按条件检索“1,232”条记录

已选条件: 数据来源: CNKI × 机构: 晶体材料研究所 ×
导出
  • 排序
  • 显示
H-2(11/2) + S-4(3/2) and (4)G(11/2) + I-4(9/2) --> H-2(11/2) + H-2(11/2) (or S-4(3/2)) were put forward. [publication_type] => J [keyword_plu] => UP-CONVERSION; LUMINESCENCE [author_in] => [Song, F; Tan, H; Shang, MR; Zhang, GY; Cheng, ZX; Chen, HC]Nankai Univ, Photon Ctr, Tianjin 300071, Peoples R China.@@@[Song, F; Tan, H; Shang, MR; Zhang, GY; Cheng, ZX; Chen, HC] Shandong Univ, Inst Crystal, Jinan 250100, Peoples R China. [publisher_city] => BEIJING [cauthor_back] => Song, F [get_data] => 2018-08-29 [format_title_en_publication_en_pub_year] => baffc9286bf9c672ead5baf322967213-743405015 [begin_page] => 2375 [cite_wos] => 16 [check_3Y] => 2 [cite_awos] => 17 [from_id] => 76,85,73,78 [cauthor_ad] => [Song, F]Nankai Univ, Photon Ctr, Tianjin 300071, Peoples R China. [school_id] => 117 [cauthor_order] => 1 [research_area] => Physics [sys_level_num] => 1_7 [publisher] => CHINESE PHYSICAL SOC [sys_jg_type] => 0 [format_issn_issue_page_pub_year] => 8a6574bd19d65fc6f3904c66e11e2b83227934483 [title_en] => Spectra characteristics of Er3+ doped NaY(WO4)(2) crystal [publication_29] => ACTA PHYS SIN-CH ED [author_fn] => Song, F; Tan, H; Shang, MR; Zhang, GY; Cheng, ZX; Chen, HC [pub_year] => 2002 [publisher_ad] => P O BOX 603, BEIJING 100080, PEOPLES R CHINA [check_180] => 0 [keyword_en] => Er : NaY(WO4)(2); E3+; absorption spectra; emission spectra; excitation; spectra; upconversion luminescence [end_page] => 2379 [pub_date] => OCT [pages] => 5 [format_wos_No] => fca142062beff5e7892dc89ab198e9ca-149673038 [hints] => 5 [volume] => 51 [researcherID] => Cheng, Zhenxiang/F-4638-2012 [language] => Chinese [source_type] => 351 [issue] => 10 [reference_No] => 10 [batch] => 3250,3243,3241,3254 [publication_en] => ACTA PHYSICA SINICA [hx_id] => 2378,2371 [sys_update_time] => 2018-09-05 15:29:28 [format_title_en_issn_pub_year] => 356d37ab5b928cf5edcc00e33dea1b2c-173446630 [publication_iso] => Acta Phys. Sin. [article_id] => 331858,563987,495116,764 [wos_sub] => Physics, Multidisciplinary [orcID] => Cheng, Zhenxiang/0000-0003-4847-2907 [SYS_TAG] => 3 [wos_No] => WOS:000178899300039 [page] => 2375-2379 [hb_type] => 2 [article_dt] => Article [jl_language] => chinese [jl_article_dt] => 期刊论文 [jl_publication_en] => actaphysicasinica [jl_country] => 中国 [jl_keyword_en] => excitation,upconversionluminescence,spectra,ernaywo42,absorptionspectra,emissionspectra,e3 [jl_publisher] => chinesephysicalsoc [author_jg] => [宋峰;谭浩;商美茹;张光寅]南开大学光子学中心,天津,300071,中国.@@@[程振祥;陈焕矗]山东大学晶体研究所,济南,250100,中国 [keyword_cn] => 光谱特性;NaY(WO4)2晶体;ER^3+;吸收光谱;激发光谱;发射光谱;上转换发光;铒掺杂; [format_title] => acbff3e65c8e2a5625181281250a78d7-1750756492 [clc] => O734 [title_cn] => 掺Er^3+的NaY(WO4)2晶体的光谱特性 [format_publication_cn] => 94ac9f922a2bd4c3b29ced57c489e9b7-391537303 [publication_cn] => 物理学报 [format_title_en] => 979199ed9c1b0849656290ea1f15e624-526929331 [CSSN] => 11-1958/O4 [abstract_cn] => 测量了Er:NaY(WO4)2晶体的吸收光谱、激发光谱、发射光谱以及上转换发光,并对测量的结果进行了详细分析,得出了Er:NaY(WO4)2晶体的光学特性.解释了离子间的能级跃迁过程. [sys_priority_field] => 73 [author_cn] => 宋峰[1];谭浩[1];商美茹[1];张光寅[1];程振祥[2];陈焕矗[2] [uri] => http://lib.cqvip.com/qk/94684X/200210/7050939.html [format_publication_en] => 11968562f496834807ca5004bd980c96-838396646 [jl_publication_cn] => 物理学报 [jl_keyword_cn] => er3,上转换,激发光谱,吸收光谱,ernaywo42晶体,发射光谱 [jl_clc] => o437 [company_id] => 24,0,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => [author_test] => Array ( ) [sys_author_id_arr] => [jl_publication_cn_publication_en] => actaphysicasinica,物理学报 [jl_keyword_cn_keyword_en] => excitation,er3,emissionspectra,spectra,吸收光谱,发射光谱,ernaywo42,上转换,absorptionspectra,ernaywo42晶体,激发光谱,upconversionluminescence,e3 [format_scopus_No] => 37d81689478a7c758e677897545581df447510872 [classification_pub] => WLHPA [standard_in] => Photonics Center, Nankai University, Tianjin 300071, China; Institute of Crystal, Shandong University, Jinan 250100, China [datebase] => Scopus [cite_scopus] => 1 [scopus_No] => 2-s2.0-0041419270 [format_title_cn_publication_cn_pub_year] => e009e1f5239ae417cce76641596c2011-1727523388 [format_title_cn_issn_pub_year] => 7406e74bb9e471e84675ce6c995d85cf-1006646655 [sys_author_jg_last_arr] => 济南250100 [jl_company_test] => uircu0,uorgidu24,uparentidu24,unameuu6676u4f53u6750u6599u7814u7a76u6240,ulevelu1 [sys_author_in_last_arr] => peoplesrchina [sys_author_id] => [id] => AQifvWUBFjIhTVEbgOh5 [tags] => 0 ) [4] => Array ( [issn] => 0567-7351 [reference] => Alves I, 1999, SOLID STATE COMMUN, V109, P697, DOI@@@10.1016/S0038-1098(98)00631-0@@@[樊小勇 FAN XiaoYong], 2007, [化学学报, Acta Chemical Sinica], V65, P165@@@Fu LJ, 2006, SOLID STATE SCI, V8, P113, DOI@@@10.1016/j.solidstatesciences.2005.10.019@@@GUO Q, 2004, CHEM COMMUN, V1, P26@@@Khabashesku VN, 2000, CHEM MATER, V12, P3264, DOI 10.1021/cm000328r@@@Li C, 2007, MATER CHEM PHYS, V103, P427, DOI@@@10.1016/j.matchemphys.2007.02.057@@@Lu TR, 1998, THIN SOLID FILMS, V332, P74, DOI@@@10.1016/S0040-6090(98)01024-4@@@Miller DR, 2002, J MATER CHEM, V12, P2463, DOI 10.1039/b109700h@@@ORTEGA J, 1995, PHYS REV B, V51, P2624, DOI 10.1103/PhysRevB.51.2624@@@Teter DM, 1996, SCIENCE, V271, P53, DOI 10.1126/science.271.5245.53@@@Tirado JL, 2003, MAT SCI ENG R, V40, P103, DOI@@@10.1016/S0927-796X(02)00125-0@@@Yao T, 2004, SOLID STATE IONICS, V175, P199, DOI@@@10.1016/j.ssi.2004.08.023@@@Zhang ZH, 2001, J AM CHEM SOC, V123, P7788, DOI 10.1021/ja0103849@@@Zhao HZ, 2005, MAT SCI ENG B-SOLID, V122, P90, DOI@@@10.1016/j.mseb.2005.05.007@@@Zimmerman JL, 2001, NANO LETT, V1, P731, DOI 10.1021/nl015626h [batch2] => 1,2,6 [format_cscd_No] => d05ff2b0f7f33a2b97d005042af7b22e140002868 [begin_page] => 1166 [tag] => 0 [research_area] => Chemistry [publication_info] => 0567-7351(2009)67:11<1166:SMXC34>2.0.TX;2-S [abstract_en] => Graphite-like carbon nitride (g-C3N4) was synthesized using a solid state method and characterized by XRD, FTIR and XPS. The electrochemical properties of the g-C3N4 were studied using both cyclic voltammetry and charge-discharge cycling. It was found that the g-C3N4 sample showed certain reversible intercalation capacity of Li+, but the capacity dropped sharply during the first few cycles. The poor reversibility could be ascribed mainly to the decomposition Of C3N4 upon electroreduction. Modification of the g-C3N4 was performed by intercalating a little amount of Mg2+ and Al3+ into its interlayer spacing, which made slight improvement on the crystallization and the reversible Li+ intercalation of the residual g-C3N4. [abstract_cn] => 采用固态反应方法制备了石墨型C3N4.采用XRD,FTIR,XPS对产物的组成和结构进行了表征.研究了石墨型C3N4的电化学行为,并将其用作负极材料组装成锂离子电池进行测试,发现该材料具有一定的嵌锂能力,但比容量低,循环寿命短.采用少量嵌入Mg2+,Al3+的方法对石墨型C3N4进行改性,结果发现石墨型C3N4的充放电性能得到一定改善. [keyword_cn] => 石墨型C3N4;固态合成;电化学性质;锂离子电池;可逆嵌锂 [fund_No] => 国家自然科学基金 [format_title_en_publication_en_pub_year] => a1b4817ba4b9f708fd5029ac55a47586134807161 [publication_type] => J [author_jg] => [杨晓晖] 山东大学化学与化工学院, 教育部胶体与界面化学重点实验室, 济南, 山东 250100, 中国.@@@[王红军] 山东大学化学与化工学院, 教育部胶体与界面化学重点实验室, 济南, 山东 250100, 中国.@@@[张树永] 山东大学化学与化工学院, 教育部胶体与界面化学重点实验室, 济南, 山东 250100, 中国.@@@[陆希峰] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[崔得良] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国 [cite_cscd] => 3 [cite_awos] => 11 [from_id] => 76,75,73,80,78 [issue] => 11 [email] => syzhang@sdu.edu.cn [email_c] => syzhang@sdu.edu.cn [sys_level_num] => 1_1 [format_title_cn_publication_cn_pub_year] => 1bac3ed37bc0d493df35f9990a3f4f1b1989086509 [sys_jg_type] => 11,9,5 [format_issn_issue_page_pub_year] => 7c16fd3d584065b1a0766aaa0da8a14d1823385713 [title_en] => Solid-state Synthesis of Graphite-like C3N4 and Its Reversible Li+ Intercalation [volume] => 67 [author_fn] => Yang Xiaohui; Wang Hongjun; Lu Xifeng; Cui Deliang; Zhang Shuyong [pub_year] => 2009 [check_180] => 4 [keyword_en] => graphite-like C3N4; solid-state synthesis; electrochemical property;; lithium-ion battery; reversible lithium intercalation [end_page] => 1170 [article_id] => 167987,661404,475433,320197,648090 [pages] => 5 [hints] => 11 [author_cn] => 杨晓晖;王红军;陆希峰;崔得良;张树永; [language] => Chinese [source_type] => 351 [reference_No] => 15 [cscd_No] => CSCD:3589042 [batch] => 3250,3243,3249,3252,3241 [publication_en] => ACTA CHIMICA SINICA [hx_id] => 2377,2378,2371 [author_in] => [Yang, X] Education Ministry Key Laboratory of Colloid and Interface Chemistry, School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Wang, H] Education Ministry Key Laboratory of Colloid and Interface Chemistry, School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Lu, X] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Cui, D] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Zhang, S] Education Ministry Key Laboratory of Colloid and Interface Chemistry, School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China [format_title_en_issn_pub_year] => 108d62dcf871c819e145355aba22ce811396381012 [check_3Y] => 60 [publication_cn] => 化学学报 [title_cn] => 石墨型C_3N_4的固态合成及嵌锂性能研究 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 28647fd79056ab0ff4e2407399192741-803031361 [page] => 1166-1170 [hb_type] => 2 [article_dt] => Article [hb_batch] => issn_issue_page_pub_year_1_7 [cite_wos] => 11 [delivery_No] => 465SD [format_title] => e596d4f4ec8e063c45c0563a0aa7d7cd1434470916 [cauthor_ad] => [Yang, XH]Shandong Univ, Educ Minist, Key Lab Colloid & Interface Chem, Sch Chem & Chem Engn, Jinan 250100, Peoples R China. [publication_29] => ACTA CHIM SINICA [author_en] => Yang, XH; Wang, HJ; Lu, XF; Cui, DL; Zhang, SY [get_data] => 2018-08-29 [publisher] => SCIENCE PRESS [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => LITHIUM-ION BATTERIES; CARBON NITRIDE; ELECTRODE [publication_iso] => Acta Chim. Sin. [format_title_en] => a2df21fd1cc95f5a6de1276976193e74467112910 [publisher_city] => BEIJING [pub_date] => JUN 14 [wos_No] => WOS:000267606400002 [sys_priority_field] => 76 [wos_sub] => Chemistry, Multidisciplinary [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => chinese [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => actachimicasinica [jl_country] => 中国 [jl_keyword_en] => ,lithiumionbattery,graphitelikec3n4,solidstatesynthesis,electrochemicalproperty,reversiblelithiumintercalation [jl_keyword_cn] => 锂离子电池,固态合成,石墨型c3n4,可逆嵌锂,电化学性质 [jl_publisher] => sciencepress [cite_wanfang] => 4 [clc] => O647.2 [CSSN] => 31-1320/O6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-84875252597&partnerID=40&md5=ac318f898eaa4ab6fee110bee8118ecb [jl_clc] => o6472 [company_id] => 24,0,43,169 [sys_subject_sort] => 0,0,0 [college_parent_id] => 24,43,169 [company_test] => Array,Array,Array [author_id] => 20439 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 4 [name] => 崔得良 [irtag] => 7 [t_index] => 0 [person_id] => 20439 ) ) [sys_author_id_arr] => 20439崔得良 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => 可逆嵌锂,石墨型c3n4,锂离子电池,lithiumionbattery,graphitelikec3n4,solidstatesynthesis,electrochemicalproperty,固态合成,电化学性质,reversiblelithiumintercalation [format_scopus_No] => 08b908381efa1f09dd77def75b721e40-1422688339 [format_wos_No] => 2795104c4ef19eacf2d14b2663a9fa9a808482732 [standard_in] => Education Ministry Key Laboratory of Colloid and Interface Chemistry, School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China; State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China [cauthor] => Zhang, S(syzhang@sdu.edu.cn) [datebase] => Scopus [cite_scopus] => 12 [scopus_No] => 2-s2.0-84875252597 [jl_author_test] => uirtypical3,uirtstag0,upersonid20439,unameuu5f20u6811u6c38,usureu0,uuindex4,utindex0,uirtag6,uirinspecttag0,uirauthortype0,uirtag0,uuindex5,unameuu5d14u5f97u826f,upersonid25639 [sys_author_jg_last_arr] => 中国,中国,中国,中国,中国 [jl_company_test] => unameuu6676u4f53u6750u6599u7814u7a76u6240,uparentidu43,uircu0,uorgidu24,uorgidu43,ulevelu1,unameuu5316u5b66u4e0eu5316u5de5u5b66u9662,uparentidu24 [sys_author_in_last_arr] => china [sys_author_id] => [id] => 6AZ1vWUBFjIhTVEbYoKt [tags] => 0 ) [5] => Array ( [batch2] => 1,2 [batch] => 3250,3241,3254 [tag] => 0 [abstract_cn] => 根据自旋注入半导体的相关理论,考虑到有机体内可能同时含有带自旋的单极化子和不带自旋的双极化子两种载流子,从扩散理论和欧姆定律出发,建立了自旋注入有机体的唯象模型.通过计算发现,适当选择铁磁层极化率或两层的电导率可以使得有机层内电流具有高的自旋极化.进一步研究了单极化子浓度等因素对注入电流极化的影响. [keyword_cn] => 自旋注入;双极化子;扩散理论;自旋极化;极化率;铁磁层;载流子;注入电流;半导体;单极化; [clc] => O4 O47 [author_jg] => [任俊峰;付吉永;刘德胜;解士杰]山东大学物理与微电子学院,晶体材料国家重点实验室,济南250100,中国 [format_title_cn_publication_cn_pub_year] => 867ace96e9af53f67f17282b1982d188-218670182 [from_id] => 78,73,85 [issue] => 11 [sys_level_num] => 2_1 [sys_jg_type] => 9 [source_type] => 351 [pub_year] => 2004 [article_id] => 329169,586837,41475 [pages] => 4 [hints] => 4 [author_cn] => 任俊峰[1];付吉永[1];刘德胜[1];解士杰[1] [issn] => 1000-3290 [uri] => http://lib.cqvip.com/qk/94684X/200411/10860497.html [publication_cn] => 物理学报 [title_cn] => 自旋注入有机物的扩散理论 [CSSN] => 11-1958/O4 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => ccb94d6c056de833b747634b11abe26d-1136781631 [hb_type] => 2 [jl_publication_cn] => 物理学报 [jl_country] => 中国 [jl_keyword_cn] => ,扩散理论,注入电流,铁磁层,双极化子,单极化,半导体,自旋极化,载流子,自旋注入,极化率 [jl_clc] => o4o47 [author_in] => [Ren, JF; Fu, JY; Liu, DS; Xie, SJ]Shandong Univ, Sch Phys & Microelect, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_id] => 21473,22205 [author_test] => Array ( [0] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 0 [name] => 解士杰 [irtag] => 0 [t_index] => 0 [person_id] => 21473 ) [1] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 0 [name] => 刘德胜 [sys_author_id] => Array ( [0] => 21473 [1] => 22205 ) [irtag] => 0 [t_index] => 0 [person_id] => 22205 ) ) [company_id] => 24,151,35,133,5,161 [sys_subject_sort] => 0,0,0,0,0,0 [college_parent_id] => 24,151,35,133,5,161 [company_test] => Array,Array,Array,Array,Array,Array [sys_author_id_arr] => 21473解士杰,22205刘德胜 [jl_publication_cn_publication_en] => 物理学报 [jl_keyword_cn_keyword_en] => 注入电流,自旋注入,铁磁层,自旋极化,单极化,载流子,扩散理论,半导体,极化率,双极化子 [sys_author_id] => 21473,22205 [hb_batch] => grant_no [author_first] => 任俊峰 [cite_wos] => 10 [publication_en] => ACTA PHYSICA SINICA [check_3Y] => 0 [language] => Chinese [delivery_No] => 869WI [cauthor_ad] => [Xie, SJ]Shandong Univ, Sch Phys & Microelect, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [format_title] => 1fb15fc8cde72af4d3af1e6f7b287410712157722 [author_fn] => Ren, JF; Fu, JY; Liu, DS; Xie, SJ [format_title_en_issn_pub_year] => 454ae92375e2ba831494ad91d43064e81370017655 [publication_29] => ACTA PHYS SIN-CH ED [end_page] => 3817 [abstract_en] => Based on the theory of electrical spin injection into semiconductors, by considering the carriers of spin polarons and spinless bipolarons in organic polymers, we suggested a model of spin injection into organic polymers. It was found that a high current polarization can be obtained by adjusting the spin current polarization in the ferromagnetic layer or the conductivities of the ferromagnetic and organic layers. Effect of the proportion of polarons to carriers on the spin current polarization was discussed. [article_dt] => Article [publication_type] => J [begin_page] => 3814 [author_en] => Ren, JF; Fu, JY; Liu, DS; Xie, SJ [volume] => 53 [publisher] => CHINESE PHYSICAL SOC [get_data] => 2018-08-29 [keyword_en] => spintronics; spin injection; organic polymers; polarons [page] => 3814-3817 [keyword_plu] => SEMICONDUCTOR; MAGNETORESISTANCE [format_publication_cn] => 94ac9f922a2bd4c3b29ced57c489e9b7-391537303 [publication_iso] => Acta Phys. Sin. [format_title_en_publication_en_pub_year] => 01b74dbf7cc79daeb6b35cd0772cd9781555466252 [format_title_en] => fcfbad0daae0eb5be8724e80092e9408-1083500587 [publisher_city] => BEIJING [pub_date] => NOV [cauthor_order] => 4 [hx_id] => 2371 [email] => xsj@sdu.edu.cn [reference_No] => 17 [format_issn_issue_page_pub_year] => 5f80d33e6d49c512ba7c8c630d20f2531011276692 [cite_awos] => 11 [wos_No] => WOS:000225014800035 [sys_priority_field] => 73 [format_wos_No] => 90183dae4d73e477f44afad820752d991857600053 [wos_sub] => Physics, Multidisciplinary [research_area] => Physics [cauthor_back] => Xie, SJ [check_180] => 0 [publisher_ad] => P O BOX 603, BEIJING 100080, PEOPLES R CHINA [title_en] => Diffusion theory of spin injection into organic polymers [format_publication_en] => 11968562f496834807ca5004bd980c96-838396646 [jl_article_dt] => 期刊论文 [id] => IwoyvmUBFjIhTVEbpmJF [tags] => 0 ) [6] => Array ( [batch2] => 1,2 [batch] => 3250,3241,3254 [tag] => 0 [CSSN] => 22-1131/06 [keyword_cn] => 强双光子吸收;引发剂;光聚合反应; [clc] => O631.5 [author_jg] => [于晓强]山东大学晶体材料国家重点实验室,济南250100,中国.@@@[孙渝明]山?,济南,中国 [format_title_cn_publication_cn_pub_year] => 542b776e2fdfa3e2fab9efc6aafee93d839641411 [from_id] => 78,73,85 [issue] => 12 [sys_level_num] => 2_1 [sys_jg_type] => 10 [source_type] => 351 [pub_year] => 2000 [article_id] => 333323,46194,586651 [pages] => 3 [hints] => 12 [author_cn] => 于晓强[1];孙渝明[2] [issn] => 0251-0790 [uri] => http://lib.cqvip.com/qk/90335X/200012/4770492.html [publication_cn] => 高等学校化学学报 [title_cn] => 强双光子吸收引发的聚合反应 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => b819088b2af398d3e3a6d1e00fcacad41012062302 [hb_type] => 2 [jl_publication_cn] => 高等学校化学学报 [jl_country] => 中国 [jl_keyword_cn] => ,强双光子吸收,光聚合反应,引发剂 [jl_clc] => o6315 [author_in] => [Yu, XQ; Wang, C; Zhao, X; Wang, XM; Yan, YX; Fang, Q; Shao, ZS; Jiang, MH; Sun, YM; Liu, AQ]Shandong Univ, Natl Key Lab Crystal Mat, Jinan 250100, Peoples R China.@@@[Yu, XQ; Wang, C; Zhao, X; Wang, XM; Yan, YX; Fang, Q; Shao, ZS; Jiang, MH; Sun, YM; Liu, AQ] Shandong Univ, Dept Opt, Jinan 250100, Peoples R China. [company_id] => 24,151,142,15 [author_id] => 25201 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 于晓强 [irtag] => 7 [t_index] => 0 [person_id] => 25201 ) ) [sys_author_id_arr] => [jl_publication_cn_publication_en] => 高等学校化学学报 [jl_keyword_cn_keyword_en] => 引发剂,强双光子吸收,光聚合反应 [sys_author_id] => [hb_batch] => grant_no [author_first] => 于晓强 [publication_en] => CHEMICAL JOURNAL OF CHINESE UNIVERSITIES-CHINESE [cite_wos] => 10 [check_3Y] => 1 [language] => Chinese [delivery_No] => 402TT [format_title] => 47b1985b768873dd3cf0fa2dbadcc920-2135514373 [cauthor_ad] => [Jiang, MH]Shandong Univ, Natl Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Yu, XQ; Wang, C; Zhao, X; Wang, XM; Yan, YX; Fang, Q; Shao, ZS; Jiang, MH; Sun, YM; Liu, AQ [format_title_en_issn_pub_year] => a6bc58753b06eea32403dc6c1d5ee1bf-168769979 [publication_29] => CHEM J CHINESE U [end_page] => 1955 [abstract_en] => A novel two-photon photoninitiated polymerization is reported. The results of the study show that the two-photon polymerization of TMPTMA can be initiated by means of 4,4\'-bis(di-n-butylamino)-E-stiebene(BDBAS) under 600 nm strong laser, The light source that we used for the two-photon polymerization is a YAG pumped dye laser whose oscillating wavelength repetition rate and single pulse energy are 600 nm, 10 ns and 15 mJ, respectively. The peak power density of radiation light tight-focused by means of bojective lens is 3.8 GW/cm(2), The relative mechanism of the polymerization is discussed. [publication_type] => J [begin_page] => 1953 [article_dt] => Letter [author_en] => Yu, XQ; Wang, C; Zhao, X; Wang, XM; Yan, YX; Fang, Q; Shao, ZS; Jiang, MH; Sun, YM; Liu, AQ [volume] => 21 [get_data] => 2018-08-29 [publisher] => HIGHER EDUCATION PRESS [keyword_en] => strong two-photon absorption; initiator; polymerization excited by laser [page] => 1953-1955 [keyword_plu] => 2-PHOTON ABSORPTION [format_publication_cn] => 112be9cb2f30361719ed2bc572ba4a22192440272 [publication_iso] => Chem. J. Chin. Univ.-Chin. [format_title_en_publication_en_pub_year] => 34fd3fe329fc12ed07ffacda88bffcf6-518546535 [format_title_en] => 99ac9a7ccfe586a7ba27ce51ad9303a71692072618 [publisher_city] => BEIJING [pub_date] => DEC [cauthor_order] => 8 [hx_id] => 2371 [reference_No] => 9 [format_issn_issue_page_pub_year] => c8b3f97a218e0152bcded6111ed9ca4e-764287484 [cite_awos] => 11 [wos_No] => WOS:000167004800044 [sys_priority_field] => 73 [format_wos_No] => 11e46513a24b2d792bd9d970ec26f5401508273589 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [cauthor_back] => Jiang, MH [check_180] => 0 [publisher_ad] => SHATANHOU ST 55, BEIJING 100009, PEOPLES R CHINA [title_en] => Two-photon absorption photoinitiated polymerization [format_publication_en] => 4eabdd9afe3fe566a165b6e1c3e0dbbd-130083487 [jl_article_dt] => letter [sys_subject_sort] => 0,0,0,0 [college_parent_id] => 24,151,142,15 [company_test] => Array,Array,Array,Array [id] => ugoyvmUBFjIhTVEbXUUb [tags] => 0 ) [7] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3252,3254,3243,3241 [tag] => 0 [abstract_cn] => 以N-烷基咔唑作为电子给体和共轭桥中心,二米基硼作为端基电子受体,合成了两个V形A-π-D-π-A型新化合物:3,6-二-N-丁基-咔唑-carbazole,BBTC}和3,6-二[(E)-(4-二米基硼)苯乙烯基]-N-己基-咔唑,.这两个化合物在蓝绿光波段都有较强的荧光发射.光谱数据表明,扩大共轭... [keyword_cn] => 咔唑衍生物;有机硼化合物;V形分子;荧光 [article_id] => 489275,249260,328450,663847,33879,648086 [clc] => O627.4;O641.4 [author_jg] => [王伟] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[方奇] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[刘志强] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[曹笃霞] 济南大学材料科学与工程学院, 济南, 山东 250022, 中国.@@@[邓敏智] 中国科学院上海有机化学研究所, 中科院有机氟化学重点实验室, 上海 200032, 中国 [format_title_cn_publication_cn_pub_year] => 4f38c086ccd39da8091d401ced34922c2010258390 [hints] => 8 [issue] => 14 [sys_level_num] => 2_3 [sys_jg_type] => 10,3,5,8 [format_issn_issue_page_pub_year] => 3639c17564b0c85b6e99fc1ca4000862251091718 [source_type] => 351 [pub_year] => 2005 [pub_date] => JUL 28 [pages] => 6 [from_id] => 76,75,73,80,78,85 [author_cn] => 王伟,方奇,刘志强,曹笃霞,邓敏智 [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33749133416&partnerID=40&md5=ecdb7e132a4da44f0b38086d104368bd [publication_cn] => 化学学报 [title_cn] => V形咔唑衍生物的合成及荧光性质 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 93c38d1a7b33704aa473ab5a570850e91255186535 [page] => 1323-1328+1242 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 10 [fund_No] => 中国科学院上海有机化学研究所有机氟化学重点实验室基金资助项目; 国家自然科学基金; 高等学校博士点基金 [check_3Y] => 4 [language] => Chinese [delivery_No] => 950KX [format_title] => 4bb46c316842af4c0937fbe52b1f2cc01263560621 [cauthor_ad] => [Wang, W]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Wang, W; Fang, Q; Lui, ZQ; Cao, DX; Deng, MZ [reference] => BUUHOI NP, 1951, J AM CHEM SOC, V73, P98, DOI 10.1021/ja01145a036@@@[曹笃霞 Cao Duxia], 2004, [化学学报, Acta Chemical Sinica], V62, P225@@@CAO DX, 2003, J ORG CHEM, P3628@@@Entwistle CD, 2002, ANGEW CHEM INT EDIT, V41, P2927, DOI@@@10.1002/1521-3773(20020816)41:16<2927::AID-ANIE2927>3.0.CO;2-L@@@FANG Q, 1996, ACTA CRYSTALLOGR, V52, P2274@@@GLOGOWSKI ME, 1981, J ORGANOMET CHEM, V218, P137, DOI@@@10.1016/S0022-328X(00)86094-5@@@@@@Lakowicz J. R., 1983, PRINCIPLES FLUORESCE, P190@@@Liu ZQ, 2004, ORG LETT, V6, P2933, DOI 10.1021/ol048984a@@@Liu ZQ, 2003, CHEM-EUR J, V9, P5074, DOI 10.1002/chem.200304833@@@REYNOLDS GA, 1975, OPT COMMUN, V13, P222, DOI@@@10.1016/0030-4018(75)90085-1@@@Yuan Z, 2000, J SOLID STATE CHEM, V154, P5, DOI 10.1006/jssc.2000.8803 [publication_29] => ACTA CHIM SINICA [end_page] => 1328 [abstract_en] => Two new V-shaped A-pi-D-pi-A type compounds, N-butyl-3,6-bis{(E)-2-[5-(dimesitylboryl)thiophen-2-yl]vinyl}carbazole (BBTC) and N-hexyl-3,6-bis[(E)-4-(dimesitylboryl)styryl]-carbazole (BBSC), with trivalent boron and carbazole as electron acceptor and the core of pi-conjugated bridge respectively, were synthesized. All these carbazole derivatives can emit strong blue-green fluorescence either in solution or in solid state. Both the absorption and emission band have been greatly red-shifted when trivalent boron was introduced at the terminal as electron acceptor or the phenyls in pi-conjugated bridge were replaced by thienyls. [orcID] => Liu, Zhiqiang/0000-0001-7863-1759 [author_in] => [Wang, W] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Fang, Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China, Key Laboratory of Organofluorine Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai 200032, China@@@[ Liu, Z.-Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Cao, D.-X] College of Materials and Engineering, Jinan University, Jinan 250022, China@@@[ Deng, M.-Z] Key Laboratory of Organofluorine Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai 200032, China [publication_type] => J [begin_page] => 1323 [author_en] => Wang, W; Fang, Q; Lui, ZQ; Cao, DX; Deng, MZ [volume] => 63 [get_data] => 2018-08-29 [publisher] => SCIENCE PRESS [keyword_en] => pi; carbazole derivative; organoboron compound; V-shaped molecule; fluorescence [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => 2-PHOTON-EXCITED FLUORESCENCE; OPTICAL-PROPERTIES; SINGLE-PHOTON; BORON [publication_iso] => Acta Chim. Sin. [format_title_en] => f8c0f5e2196e9edc99bdd0b3f61b3087614513863 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 11 [email] => fangqi@icm.sdu.edu.cn [cite_awos] => 11 [wos_No] => WOS:000230857100014 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Synthesis and fluorescence of two V-shaped carbazole derivatives [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => chinese [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => actachimicasinica [jl_country] => 中国,中国 [jl_keyword_en] => vshapedmolecule,pi,organoboroncompound,carbazolederivative,fluorescence [jl_keyword_cn] => 荧光,v形分子,有机硼化合物,咔唑衍生物 [jl_clc] => o6274,o6414 [jl_publisher] => sciencepress [company_id] => 24,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => 20672,22582,24212,24213,24211,24214 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 方奇 [irtag] => 7 [t_index] => 0 [person_id] => 20672 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 刘志强 [irtag] => 7 [t_index] => 0 [person_id] => 22582 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24211 ) [3] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24212 ) [4] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24213 ) [5] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 王伟 [irtag] => 7 [t_index] => 0 [person_id] => 24214 ) ) [sys_author_id_arr] => 20672方奇,22582刘志强 [cscd_No] => CSCD:2111716 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => fluorescence,v形分子,vshapedmolecule,咔唑衍生物,有机硼化合物,organoboroncompound,pi,carbazolederivative,荧光 [sys_author_id] => 20672,22582 [format_cscd_No] => 0672df6924e6f1cae0a0e2f659c74a0d-2108726319 [format_title_en_publication_en_pub_year] => 1373cc183f94f5bf034558497829146d1788834477 [format_wos_No] => 8ccbba2b0234c7292c9657a73338880e626727698 [format_title_en_issn_pub_year] => 331cd7402d293ab9ace086285d61b1a1928876829 [format_scopus_No] => b5089290948fec7eb90d20268571d102-215191276 [standard_in] => State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China; Key Laboratory of Organofluorine Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai 200032, China; College of Materials and Engineering, Jinan University, Jinan 250022, China [datebase] => Scopus [cite_scopus] => 12 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-33749133416 [id] => 3Q1EvmUBFjIhTVEbKGBy [tags] => 0 ) [8] => Array ( [batch2] => 1,2,6 [batch] => 3250,3243,3241,3252 [tag] => 0 [abstract_cn] => 合成了配合物晶体FeHg(SCN)_4和MnHg(SCN)_4用单晶X射线衍射方法测定了这两个晶体的结构.以尿素为标准样品用粉末晶体倍频1064nm的Nd:YAG激光,测得其倍频光强度分别为:FeHg(SCN)_4,0.6倍于尿素;MnHg(SCN)_4,50倍于尿素.后者显示了作为新的非线性光学材料的发展前景. [keyword_cn] => FeHg(SCN)_4;MnHg(SCN)_4;合成;结构;非线性光学性质 [article_id] => 334193,598069,497487,239674 [clc] => O657.62 [author_jg] => [延云兴,方奇,于文涛,袁多荣,田玉鹏,蒋民华,I.D.Williams,蔡志岗]山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,香港科技大学化学系,中山大学超快光谱国家重点实验室 济南250100,济南250100,济南250100,济南250100,济南250100,济南250100,广州510275 [format_title_cn_publication_cn_pub_year] => 7f5526acac20ac0ab19ea339f1fea66b2010541780 [hints] => 5 [issue] => 11 [sys_level_num] => 2_3 [sys_jg_type] => 8,3,5,8,8 [format_issn_issue_page_pub_year] => ffc90dae027a2ed5d456a676c34ce58341070224 [source_type] => 351 [pub_year] => 1999 [pub_date] => 1999-11-20 [pages] => 5 [from_id] => 76,80,73,78 [author_cn] => 延云兴,方奇,于文涛,袁多荣,田玉鹏,蒋民华,I.D.Williams,蔡志岗 [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-0042760475&partnerID=40&md5=389c6718d63b164cba411cca6d848bc7 [publication_cn] => 化学学报 [title_cn] => 金属硫氰酸根配合物FeHg(SCN)_4,MnHg(SCN)_4的合成、晶体结构与非线性光学性质的研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => c38bd49848c694709001f8325875cbf6-205425360 [page] => 1257-1261 [hb_type] => 2 [article_dt] => Article [hb_batch] => issn_issue_page_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 10 [check_3Y] => 2 [language] => Chinese [delivery_No] => 257LT [format_title] => 23cbbceaa13fcf3c53eb990c1bd966ea1529278062 [cauthor_ad] => [Yan, YX]Shandong Univ, Inst Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Yan, YX; Fang, Q; Yu, WT; Yuan, DR; Tian, YP; Williams, ID; Cai, ZG [publication_29] => ACTA CHIM SINICA [end_page] => 1261 [researcherID] => williams, ian/B-2907-2009 [abstract_en] => The title compounds FeHg(SCN)(4) and MnHg(SCN)(4) were synthesized and their structures were determined by single crystal X-ray diffraction analysis. Irradiated with a 1064 nm Nd: YAG laser beam, the powdered crystals of FeHg(SCN)(4) show a 532 nm second harmonic intensity of 0.6 times that of urea which was taken as standard sample, whereas the powdered crystals of MnHg(SCN)(4) show a second harmonic intensity of 18 times that of urea. The latter shows a quite promising application value as a useful nonlinear optical materials. [orcID] => williams, ian/0000-0001-8743-401X [author_in] => [Yan, Y.-X] Institute of Crystal Materials, State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China@@@[ Fang, Q] Institute of Crystal Materials, State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China@@@[ Yu, W.-T] Institute of Crystal Materials, State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China@@@[ Yuan, D.-R] Institute of Crystal Materials, State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China@@@[ Tian, Y.-P] Institute of Crystal Materials, State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China@@@[ Williams, I.D] Department of Chemistry, Hong Kong University of Science and Technology, Hong Kong, Hong Kong@@@[ Cai, Z.-G] Institute of Laser Spectroscopy, Stake Key Laboratory of Ultrafast Laser Spectroscopy, Zhongshan University, Guangzhou, 510275, China [publication_type] => J [begin_page] => 1257 [author_en] => Yan, YX; Fang, Q; Yu, WT; Yuan, DR; Tian, YP; Williams, ID; Cai, ZG [volume] => 57 [get_data] => 2018-08-29 [publisher] => SCIENCE PRESS [keyword_en] => FeHg(SCN)(4); MnHg(SCN)(4); synthesis; structure; non-linear optical; properties [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [publication_iso] => Acta Chim. Sin. [format_title_en] => a4552d36299face55689379cb981779c1585052025 [publisher_city] => BEIJING [hx_id] => 2378,2371 [reference_No] => 7 [cite_awos] => 11 [wos_No] => WOS:000083783900013 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Synthesis, structure and non-linear optical properties of FeHg(SCN)(4) and MnHg(SCN)(4) [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => chinese [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => actachimicasinica [jl_country] => 中国,中国 [jl_keyword_en] => nonlinearoptical,mnhgscn4,fehgscn4,properties,structure,synthesis [jl_keyword_cn] => 结构,非线性光学性质,fehgscn4,mnhgscn4,合成 [jl_clc] => o65762 [jl_publisher] => sciencepress [company_id] => 24,0,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => 24888,20672 [author_test] => Array ( [0] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 1 [name] => 延云兴 [irtag] => 0 [t_index] => 1 [person_id] => 24888 ) [1] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 2 [name] => 方奇 [sys_author_id] => Array ( [0] => 24888 [1] => 20672 ) [irtag] => 0 [t_index] => 0 [person_id] => 20672 ) ) [sys_author_id_arr] => 20672方奇,24888延云兴 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => nonlinearoptical,非线性光学性质,合成,mnhgscn4,synthesis,fehgscn4,properties,structure,结构 [sys_author_id] => 20672,24888 [format_title_en_publication_en_pub_year] => 9835378386dab0cf092e6f6d5041f8b11297614056 [format_wos_No] => eaf42e16978abfb932facabcd43f37a5-1011724265 [format_title_en_issn_pub_year] => 8915900ea909370a1ec332561f29d4b9235157633 [datebase] => Scopus [format_scopus_No] => 0cbd29fea4dade47160ebfe37bf8cc95371133132 [cite_scopus] => 5 [sys_priority_field] => 76 [standard_in] => Institute of Crystal Materials, State Key Laboratory of Crystal Materials, Shandong University, Jinan, 250100, China; Department of Chemistry, Hong Kong University of Science and Technology, Hong Kong, Hong Kong; Institute of Laser Spectroscopy, Stake Key Laboratory of Ultrafast Laser Spectroscopy, Zhongshan University, Guangzhou, 510275, China [scopus_No] => 2-s2.0-0042760475 [id] => 4Q5HvmUBFjIhTVEbZySy [tags] => 0 ) [9] => Array ( [batch2] => 1,2 [batch] => 3250,3241,3254 [tag] => 0 [abstract_cn] => 研究了极化子和双极化子在基态非简并聚合物中的动力学.弱电场下,发现载流子为带电极化子或双极化子,它们的晶格态与电荷态始终耦合在一起同步运动.极化子比双极化子的运动速度快,存在饱和速度,且它们的饱和速度随聚合物非简并度的增加而降低;强电场下,元激发的电荷态将脱离晶格态的束缚而快速运动,参与导电的不再是极化子或双极化子,而是电子直接导电. [keyword_cn] => 极化子;双极化子;动力学模拟;基态非简并聚合物;光电性质;非简并参数;载流子运动;晶格畸变;有机光致发光器件;有机电致发光器件; [clc] => O631.24 TN383 [author_jg] => [王鹿霞;张大成;刘德胜;韩圣浩;解士杰]山东大学物理与微电子学院,晶体材料国家重点实验室,济南,250100,中国 [format_title_cn_publication_cn_pub_year] => 5e68a8c2fd117cbd54856eef3cc0d126-525602229 [from_id] => 78,73,85 [issue] => 10 [sys_level_num] => 2_1 [sys_jg_type] => 9 [source_type] => 351 [pub_year] => 2003 [article_id] => 563991,105101,330919 [pages] => 6 [hints] => 3 [author_cn] => 王鹿霞;张大成;刘德胜;韩圣浩;解士杰 [issn] => 1000-3290 [uri] => http://lib.cqvip.com/qk/94684X/200310/8511024.html [publication_cn] => 物理学报 [title_cn] => 基态非简并聚合物中的极化子和双极化子动力学 [CSSN] => 11-1958/O4 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 5f2fe9bcc5951bca9f85cf1212be258e-1498329190 [hb_type] => 2 [jl_publication_cn] => 物理学报 [jl_country] => 中国 [jl_keyword_cn] => 光电性质,,载流子运动,基态非简并聚合物,动力学模拟,非简并参数,有机电致发光器件,双极化子,有机光致发光器件,晶格畸变,极化子 [jl_clc] => o63124tn383 [author_in] => [Wang, LX; Zhang, DC; Lu, DS; Han, SH; Xie, SJ]Shandong Univ, Sch Phys & Microelect, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_id] => 21473,22205 [author_test] => Array ( [0] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 3 [name] => 刘德胜 [irtag] => 0 [t_index] => 0 [person_id] => 22205 ) [1] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 5 [name] => 解士杰 [sys_author_id] => Array ( [0] => 22205 [1] => 21473 ) [irtag] => 0 [t_index] => 0 [person_id] => 21473 ) ) [company_id] => 24,151,35,133,0,5,161 [sys_subject_sort] => 0,0,0,0,0,0 [college_parent_id] => 24,151,35,133,5,161 [company_test] => Array,Array,Array,Array,Array,Array [sys_author_id_arr] => 21473解士杰,22205刘德胜 [jl_publication_cn_publication_en] => 物理学报 [jl_keyword_cn_keyword_en] => 光电性质,极化子,非简并参数,基态非简并聚合物,有机光致发光器件,有机电致发光器件,晶格畸变,双极化子,动力学模拟,载流子运动 [sys_author_id] => 21473,22205 [hb_batch] => grant_no [author_first] => 王鹿霞 [cite_wos] => 9 [publication_en] => ACTA PHYSICA SINICA [check_3Y] => 1 [language] => Chinese [delivery_No] => 727WD [cauthor_ad] => [Wang, LX]Shandong Univ, Sch Phys & Microelect, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [format_title] => b2fc2692f07e7d445e6421f1b83e9dd8377656023 [author_fn] => Wang, LX; Zhang, DC; Lu, DS; Han, SH; Xie, SJ [format_title_en_issn_pub_year] => 89c9fb1eba53b0286cc51bc2ac13a8e7-1668290878 [publication_29] => ACTA PHYS SIN-CH ED [end_page] => 2552 [abstract_en] => We investigate theoretically the dynamic process of polarons and bipolarons in nondegenerate polymers. In a low field, it is bigger that the carriers are charged polarons or bipolarons, their lattice configurations and charge densities move together all along. The velocity of polarons is bigger than that of bipolarons in the same system. Both polarons and bipolarons have their saturated velocities. The saturated velocities decrease with the increase of the nondegenerate parameters. In a high electric field, the electronic states of polarons and bipolarons; are dissociated from their lattice states, and move with high velocities. In this case, the carriers are electrons rather than polarons or bipolarons. [article_dt] => Article [publication_type] => J [begin_page] => 2547 [author_en] => Wang, LX; Zhang, DC; Lu, DS; Han, SH; Xie, SJ [volume] => 52 [publisher] => CHINESE PHYSICAL SOC [get_data] => 2018-08-29 [keyword_en] => polaron; bipolaron; dynamic simulation [page] => 2547-2552 [keyword_plu] => PHOTOINDUCED POLARIZATION INVERSION; CONJUGATED POLYMERS; CONDUCTING POLYMERS; ATOMIC DISORDER; CHARGED SOLITON; ELECTRIC-FIELD; POLYACETYLENE; STABILITY; MOTION [format_publication_cn] => 94ac9f922a2bd4c3b29ced57c489e9b7-391537303 [publication_iso] => Acta Phys. Sin. [format_title_en_publication_en_pub_year] => 1dc7735844435a346e6a149ccdf860b71672015873 [format_title_en] => 03f2c7cfed1ee3346012f15f60bfd7f4834838510 [publisher_city] => BEIJING [pub_date] => OCT [cauthor_order] => 1 [hx_id] => 2371 [reference_No] => 17 [format_issn_issue_page_pub_year] => d025c2b1a1b5e4fbfbe17fdd96759c44237882723 [cite_awos] => 15 [wos_No] => WOS:000185683100035 [sys_priority_field] => 73 [format_wos_No] => 88b6a71332e18b63c3c235c9e68010a41970552230 [wos_sub] => Physics, Multidisciplinary [research_area] => Physics [cauthor_back] => Wang, LX [check_180] => 0 [publisher_ad] => P O BOX 603, BEIJING 100080, PEOPLES R CHINA [title_en] => Dynamics of polarons and bipolarons in nondegenerate polymers [format_publication_en] => 11968562f496834807ca5004bd980c96-838396646 [jl_article_dt] => 期刊论文 [id] => dAkvvmUBFjIhTVEbeWbB [tags] => 0 ) [10] => Array ( [batch2] => 1,2 [batch] => 3250,3241,3254,3252 [tag] => 0 [abstract_cn] => 采用沉积-沉淀法将AgI分散到TiO2酸蚀纳米带上,然后通过光照进而分解出Ag颗粒,最终获得了Ag@AgI等离子体负载的TiO2酸蚀纳米带(AIST)。利用UV-Vis吸收光谱、XRD、SEM对产物进行表征,并研究了可见光下对甲基橙(MO)的光催化降解性能。结果表明,纳米带酸蚀后利于AgI的沉积,Ag的表面等离子体共振效应可以增强催化剂对于可见光的吸收,使可见光下AIST的光催化降解性能显著提高。 [keyword_cn] => TiO2;酸蚀纳米带;Ag;等离子体共振;可见光响应 [article_id] => 230999,639889,377515,118407 [clc] => O482.31 [author_jg] => [王恩华;刘素文;李堂刚;宋灵君]山东轻工业学院山东省玻璃与功能陶瓷加工与测试技术重点实验室@@@[王恩华;刘素文;李堂刚;宋灵君]山东大学晶体材料国家重点实验室 [format_title_cn_publication_cn_pub_year] => 5a4c255a0f4cf898775ebda616adf4e81744784309 [hints] => 10 [issue] => 3 [sys_level_num] => 2_3 [sys_jg_type] => 0,5 [format_issn_issue_page_pub_year] => 42a3cb079caaa2fb107d6eff334079991825703685 [source_type] => 351 [pub_year] => 2011 [pub_date] => MAR [pages] => 5 [from_id] => 80,78,73,85 [author_cn] => 王恩华;刘素文;李堂刚;宋灵君; [issn] => 1001-4861 [uri] => http://kns.cnki.net/kns/detail/detail.aspx?FileName=WJHX201103024&DbName=CJFQ2011 [publication_cn] => 无机化学学报 [title_cn] => Ag@AgI等离子体负载TiO_2酸蚀纳米带的制备及可见光光催化性能的研究 [CSSN] => 32-1185/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 022a8010820b907b4579f2c74ed9ef7a1249306391 [page] => 537-541 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [format_title_en] => 2d26b324a4491c76af355d21544e1c2e-1926454249 [format_title] => 6b76f7e173e9a47d34489484fe813f20-2016937301 [hx_id] => 2371 [format_publication_cn] => 6f60fdb90c8ed276c1ac1b77ab33e988-233140351 [format_publication_en] => 8b6f8b3d82617e6d3dbc6c68ccb4e7001845903523 [jl_publication_cn] => 无机化学学报 [jl_article_dt] => 期刊论文 [jl_keyword_cn] => 等离子体共振,可见光响应,ag,tio2,酸蚀纳米带 [jl_clc] => o48231 [author_in] => [Wang En-Hua; Liu Su-Wen; Li Tang-Gang; Song Ling-Jun] Shandong Inst Light Ind, Key Lab Proc & Testing Technol Glass & Funct Cera, Jinan 250353, Peoples R China.@@@ [Wang En-Hua; Liu Su-Wen] Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [company_id] => 24,0,151 [author_id] => [author_test] => Array ( ) [sys_author_id_arr] => [jl_publication_cn_publication_en] => 无机化学学报 [jl_keyword_cn_keyword_en] => 等离子体共振,tio2,酸蚀纳米带,ag,可见光响应 [sys_author_id] => [publication_en] => CHINESE JOURNAL OF INORGANIC CHEMISTRY [cite_wos] => 9 [check_3Y] => 12 [language] => Chinese [delivery_No] => 742WV [cauthor_ad] => [Liu, SW]Shandong Inst Light Ind, Key Lab Proc & Testing Technol Glass & Funct Cera, Jinan 250353, Peoples R China. [author_fn] => Wang En-Hua; Liu Su-Wen; Li Tang-Gang; Song Ling-Jun [cite_wanfang] => 17 [format_title_en_issn_pub_year] => 63ff8424dbae15a09cb9b688e00275ac1266055496 [publication_29] => CHINESE J INORG CHEM [end_page] => 541 [abstract_en] => A Ag@AgI supported TiO2 acid corrosion nanobelts plasma photocatalyst was prepared by deposition-precipitation method and photo reduction method. The products were characterized by XRD, SEM and UV-Vis spectroscopy. The photocatalytic activity was evaluated using methyl orange (MO) degradation under visible light irradiation as a probe reaction. The results indicate that the corrosion nanobelts are beneficial for AgI deposition. The surface plasmon resonance of Ag can enhance the visible light absorption of photocatalyst. The TiO2 acid corrosion nanobelts supported with Ag@AgI photocatalyst show the highest photodegradation of MO under visible light. [publication_type] => J [begin_page] => 537 [author_en] => Wang, EH; Liu, SW; Li, TG; Song, LJ [volume] => 27 [get_data] => 2018-08-29 [publisher] => CHINESE CHEMICAL SOC [keyword_en] => TiO2; acid corrosion nanobelts; Ag; surface plasmon resonance; visible; light response [keyword_plu] => TITANIUM-DIOXIDE; NANOPARTICLES; DEGRADATION [publication_iso] => Chin. J. Inorg. Chem. [format_title_en_publication_en_pub_year] => 3dabc044cf4216350177651ce7980a592069377926 [publisher_city] => BEIJING [cauthor_order] => 2 [reference_No] => 22 [email] => liusw@sdili.edu.cn [cite_awos] => 16 [wos_No] => WOS:000288976900023 [format_wos_No] => 522743d9014241b5ff0aa66a2ee2cb1b-1080131547 [wos_sub] => Chemistry, Inorganic & Nuclear [research_area] => Chemistry [cauthor_back] => Liu, SW [check_180] => 0 [publisher_ad] => C/O DEPT INT AFFAIRS, SECRETARY OF CHEM SOC, PO BOX 2709, BEIJING; 100080, PEOPLES R CHINA [title_en] => Ag@AgI Supported TiO2 Acid Corrosion Nanobelts Plasma Photocatalyst: Synthesis and Visible Light Photocatalytic Performance [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [id] => eQ1EvmUBFjIhTVEbuH_K [tags] => 0 ) [11] => Array ( [issn] => 1001-4861 [reference] => Akihiko K., 2006, INT J HYDROGEN ENERG, V31, P197@@@Bhattacharya AK, 1997, MATER LETT, V30, P7, DOI@@@10.1016/S0167-577X(96)00162-0@@@Galembeck A, 2000, THIN SOLID FILMS, V365, P90, DOI@@@10.1016/S0040-6090(99)01079-2@@@Galembeck A, 2002, J MATER SCI, V37, P1923, DOI 10.1023/A:1015206426473@@@Gotic M, 2005, J MOL STRUCT, V744, P535, DOI@@@10.1016/j.molstruc.2004.10.075@@@HIROTA K, 1992, MATER RES BULL, V27, P823, DOI@@@10.1016/0025-5408(92)90177-2@@@Kudo A, 1999, J AM CHEM SOC, V121, P11459, DOI 10.1021/ja992541y@@@LI WZ, 2003, GUIZHOU HUAGONG, V28, P21@@@Li YD, 2001, ANGEW CHEM INT EDIT, V41, P333, DOI@@@10.1002/1521-3773(20020118)41:2<333::AID-ANIE333>3.0.CO;2-5@@@LIM AR, 1995, J PHYS-CONDENS MAT, V7, P7309, DOI@@@10.1088/0953-8984/7/37/005@@@Liu JB, 2003, MAT SCI ENG B-SOLID, V104, P36, DOI@@@10.1016/S0921-5107(03)00264-2@@@Liu S., 2001, ADV MATER, V13, P656@@@[唐安平 Tang Anping], 2004, [涂料工业, Paint & coatings industry], V34, P8@@@TANG AP, 2005, YOUSE JINSHU, V57, P43@@@Tokunaga S, 2001, CHEM MATER, V13, P4624, DOI 10.1021/cm0103390@@@TUHCKS A, 2005, J SOLID STATE CHEM, V178, P1145@@@WANG F, 2001, BEIJING SHIFAN DAXUE, V37, P221@@@Xiong YJ, 2004, CHEM-EUR J, V10, P654, DOI 10.1002/chem.200305569@@@Yu JQ, 2005, CHEM LETT, V34, P850, DOI 10.1246/cl.2005.850@@@Zhang L, 2006, J PHYS CHEM B, V110, P2668, DOI 10.1021/jp056367d@@@Zhou L, 2006, J MOL CATAL A-CHEM, V252, P120, DOI@@@10.1016/j.molcata.2006.01.052@@@唐安平, 2002, Paint & Coatings Industry, V32, P27 [batch2] => 1,2,6 [format_cscd_No] => d43fc7c0c41b33ef08d589e2ee943f05-975121831 [begin_page] => 1153 [tag] => 0 [research_area] => Chemistry [publication_info] => 1001-4861(2007)23:7<1153:CDFZBB>2.0.TX;2-E [abstract_en] => The nano-sized BiVO4 with different morphologies and structures was synthesized by precipitation method through choosing different raw materials and controlling the reaction temperature and pH v alue. X-ray Diffraction (XRD), Transmission Electron Microscope (TEM) and UV-Vis absorbance spectroscopy were used to characterize the products. The results showed that highly crystalline tetragonal zircon-type structure of nano-sized BiVO, with spherical particles was obtained at room temperature using NH4VO3 as the reactant. Monoclinic scheelite structure of BiVO, was obtained through increasing the reaction temperature or the pH value. By choosing NaVO3 as the raw materials, monoclinic scheelite structure BiVO4 with a plate or rod-like shape was obtained directly at room temperature. BiVO4 with different morphologies was obtained when using different surfactants. [abstract_cn] => 采用液相沉淀法,通过选择不同起始原料并控制反应温度和pH值,制备得到不同形貌和结构的纳米BiVO。。采用X-射线衍射(XRD)、透射电子显微镜(TEM)和紫外.可见吸收光谱(UV-Vis)技术对产物进行分析表征。结果表明,采用NH4VO3,作V源,室温下可直接制备得到结晶好的四方晶系硅酸锆型BiVO4。球形纳米颗粒,提高反应液pH值或升高温度,可得到单斜晶系白钨矿型BiVO4,采用NaVO3,作为V源,室温下可直接得到单斜晶系白钨矿型片状BiVO4。加入不同类型表面活性剂则得到不同形貌的BiVO4。 [keyword_cn] => 钒酸铋;沉淀法;纳米;形貌; [fund_No] => 国家自然科学基金资助项目; 鲁东大学中青年自然科学基金资助项目 [format_title_en_publication_en_pub_year] => 4b16192b87d571761e1b1e7db4185641-1177228234 [publication_type] => J [author_jg] => [高善民] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.@@@[乔青安] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.@@@[赵培培] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.@@@[陶芙蓉] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.@@@[张江] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.@@@[戴瑛] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[黄柏标] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国 [cite_cscd] => 6 [cite_awos] => 10 [from_id] => 76,75,78,73,85 [issue] => 7 [email] => gaosm@ustc.edu [email_c] => gaosm@ustc.edu [sys_level_num] => 1_1 [format_title_cn_publication_cn_pub_year] => b1d7edc6b59531b68e03d39722e363111695928363 [sys_jg_type] => 11,3 [format_issn_issue_page_pub_year] => 46bd4c31ce5df89721c713742df5fe6d1609530732 [title_en] => Synthesis of different morphologies and structures of nano-sized BiVO4 by precipitation method [volume] => 23 [author_fn] => Gao Shan-Min; Qiao Qing-An; Zhao Pei-Pei; Tao Fu-Rong; Zhang Jiang; Dai Ying; Huang Bai-Biao [pub_year] => 2007 [check_180] => 0 [keyword_en] => BiVO4; precipitation method; nano-sized; morphologies [end_page] => 1158 [article_id] => 670723,73427,484312,639895,324596 [pages] => 6 [hints] => 5 [author_cn] => 高善民[1,2];乔青安[1];赵培培[1];陶芙蓉[1];张江[1];戴瑛[2];黄柏标[2] [researcherID] => Huang, baibiao/C-1857-2008 [language] => Chinese [source_type] => 351 [reference_No] => 22 [cscd_No] => CSCD:2842493 [batch] => 3250,3243,3249,3254,3241 [publication_en] => CHINESE JOURNAL OF INORGANIC CHEMISTRY [hx_id] => 2377,2378,2371 [author_in] => [Gao, SM; Qiao, QA; Zhao, PP; Tao, FR; Zhang, J; Dai, Y; Huang, BB]Ludong Univ, Sch Chem & Mat Sci, Shandong 264025, Peoples R China.@@@[Gao, SM; Qiao, QA; Zhao, PP; Tao, FR; Zhang, J; Dai, Y; Huang, BB] Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [format_title_en_issn_pub_year] => 4cb6452048989af84270888f82b9f989-1119113176 [check_3Y] => 23 [publication_cn] => 无机化学学报 [title_cn] => 沉淀法制备不同形貌和结构的纳米BiVO4 [orcID] => Huang, baibiao/0000-0002-0416-944X [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => b7bd2e13cbf1169d93a742a2cb178c37-2098524895 [page] => 1153-1158 [hb_type] => 2 [article_dt] => Article [hb_batch] => issn_issue_page_pub_year_1_7 [cite_wos] => 9 [delivery_No] => 197QA [format_title] => e67feefde6ae0de403bce9055b34620e1822069101 [cauthor_ad] => [Gao, SM]Ludong Univ, Sch Chem & Mat Sci, Shandong 264025, Peoples R China. [publication_29] => CHINESE J INORG CHEM [author_en] => Gao, SM; Qiao, QA; Zhao, PP; Tao, FR; Zhang, J; Dai, Y; Huang, BB [get_data] => 2018-08-29 [publisher] => CHINESE CHEMICAL SOC [format_publication_cn] => 6f60fdb90c8ed276c1ac1b77ab33e988-233140351 [keyword_plu] => BISMUTH VANADATE; PHOTOCATALYTIC PROPERTIES; HYDROTHERMAL PREPARATION; DECOMPOSITION; NANOWIRES; CRYSTAL; ROUTE [publication_iso] => Chin. J. Inorg. Chem. [format_title_en] => 97000b447e94aec1d8a08f24889ae2f71024686749 [publisher_city] => BEIJING [pub_date] => JUL 10 [wos_No] => WOS:000248569400005 [sys_priority_field] => 73 [wos_sub] => Chemistry, Inorganic & Nuclear [publisher_ad] => C/O DEPT INT AFFAIRS, SECRETARY OF CHEM SOC, PO BOX 2709, BEIJING; 100080, PEOPLES R CHINA [format_publication_en] => 8b6f8b3d82617e6d3dbc6c68ccb4e7001845903523 [jl_language] => chinese [jl_publication_cn] => 无机化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => chinesejournalofinorganicchemistry [jl_country] => 中国 [jl_keyword_en] => nanosized,bivo4,precipitationmethod,morphologies [jl_keyword_cn] => 形貌,,纳米,钒酸铋,沉淀法 [jl_publisher] => chinesechemicalsoc [clc] => O614.511 O614.532 [CSSN] => 32-1185/06 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-34547403023&partnerID=40&md5=f9d4bf4d3212fe1a295340bedf314d61 [jl_clc] => o614511o614532 [company_id] => 24,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => 20494,21239 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 戴瑛 [irtag] => 7 [t_index] => 0 [person_id] => 20494 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 黄柏标 [irtag] => 7 [t_index] => 0 [person_id] => 21239 ) ) [sys_author_id_arr] => 21239黄柏标 [jl_publication_cn_publication_en] => chinesejournalofinorganicchemistry,无机化学学报 [jl_keyword_cn_keyword_en] => 钒酸铋,沉淀法,纳米,nanosized,bivo4,形貌,precipitationmethod,morphologies [format_scopus_No] => 14faa08af7ea581462e6141b0221a2bc605740357 [format_wos_No] => 03953a739d4d4bf236f79386cad420ef244925928 [standard_in] => School of Chemistry and Materials Science, Ludong University, Yantai, Shandong 264025, China; State Key Lab. of Crystal Materials, Shandong University, Jinan 250100, China [cauthor] => Gao, SM(gaosm@ustc.edu) [datebase] => Scopus [cite_scopus] => 9 [scopus_No] => 2-s2.0-34547403023 [jl_author_test] => uirtypical3,uirtstag0,uuindex0,usureu0,upersonid21239,utindex0,unameuu6234u745b,uirtag6,uirinspecttag0,upersonid20494,uirauthortype0,uirtag0,unameuu9ec4u67cfu6807 [sys_author_jg_last_arr] => 中国,中国,中国,中国,中国,中国,中国 [jl_company_test] => uircu0,uorgidu24,uparentidu24,unameuu6676u4f53u6750u6599u7814u7a76u6240,ulevelu1 [sys_author_in_last_arr] => peoplesrchina [sys_author_id] => 21239 [id] => zwZ0vWUBFjIhTVEbw2hP [tags] => 0 ) [12] => Array ( [issn] => 0567-7351 [reference] => CHARLES RG, 1965, J INORG NUCL CHEM, V27, P119, DOI@@@10.1016/0022-1902(65)80200-7@@@Christiana A. M., 2008, J INORG BIOCHEM, V102, P77@@@Cleare M.J., 1973, PLATIN MET REV, V17, P2@@@ERNEST W, 1999, CHEM REV, V99, P2451@@@FREDERIK CK, 2002, J ORG CHEM, V67, P7185@@@GAO ZJ, 1998, J AM CHEM SOC, V120, P8253@@@John VD, 2002, J EXP CLIN CANC RES, V21, P219@@@Junko I., 2002, BIOORGAN MED CHEM, V10, P3481@@@Kelland LR, 1999, J INORG BIOCHEM, V77, P111, DOI@@@10.1016/S0162-0134(99)00141-5@@@Lev-Ari S, 2006, ANTICANCER RES, V26, P4423@@@Liu Q, 2001, J CHEM SOC DALTON, P911, DOI 10.1039/b008611h@@@Mishra S, 2005, BIOORGAN MED CHEM, V13, P1477, DOI@@@10.1016/j.bmc.2004.12.057@@@Song YM, 2009, J INORG BIOCHEM, V103, P396, DOI@@@10.1016/j.jinorgbio.2008.12.001@@@Su CC, 2006, ANTICANCER RES, V26, P4379@@@Sundquist W I, 1990, J.Coord.Chem.Rev, V100, P293@@@张金超, 2006, [科学通报, Chinese science bulletin], V51, P796@@@ZHANG Q, 2008, CHINESE CHEM LETT, V19, P281@@@[周双生 ZHOU Shuangsheng], 2008, [药学学报, Acta Pharmaceutica Sinica], V43,@@@P490@@@李大圣, 2009, 博士论文 [batch2] => 1,2,6 [format_cscd_No] => 1fd7446ad3b2544058c332fcf23367fd1590889565 [begin_page] => 2335 [tag] => 0 [research_area] => Chemistry [publication_info] => 0567-7351(2011)69:19<2335:JHSLBI>2.0.TX;2-J [abstract_en] => Four kinds of platinum(II) complexes of curcumin analog (A similar to D) were synthesized by self-made curcumin derivatives (L-1 similar to L-4) and potassium tetraiodoplatinate(II) as the starting material with ethanol as solvent. Their compositions were characterized by FT-IR, H-1 NMR, MS, TG-DTA and elemental analysis. MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) was used to study the complexes\' antitumor activity in vitro against human lung adenocarcinoma cancer cell line (A549), human cervix cancer cell line (Hela) and human breast cancer cell line (MCF-7), the results showed that the complexes had strong antitumor activity against these cell lines. Inhibition of human liver tumor of A549 was examined by antitumor rate, complex A showed inhibition activity on transplanting-tumor growth of A549, 800 mg.kg(-1) was as potent as cisplatin, its LD50 was 945.6 mg.kg(-1). [abstract_cn] => 以乙醇为溶剂,用自制的姜黄素衍生物(L1~L4)和碘亚铂酸钾为原料,合成得到了4种姜黄素类铂(II)配合物(A~D),通过FT-IR、1H NMR、MS、差热热重和元素分析对所有目标化合物进行了结构表征.应用MTT(3-(4,5-二甲基噻唑-2)-2,5-二苯基四氮唑溴盐)法研究了化合物体外对人肺腺癌A549、子宫颈癌HeLa和乳腺癌MCF-7细胞的抗肿瘤活性,结果表明这些化合物对上述癌细胞均有较强活性;并用抑瘤率测定了人肺腺瘤(A549)细胞的抑制作用,体内试验也显示铂(II)配合物A具有抗人肺腺癌瘤(A549)作用.其中剂量为800 mg·kg-1的抗瘤活性与顺铂相当,它的半数致死量为94... [keyword_cn] => 姜黄素;铂(Ⅱ)配合物;合成;抗肿瘤活性 [fund_No] => 国家自然科学基金; 安徽省级高校自然科学研究重点项目; 现代中药安徽省工程技术研究中心项目; 安徽中医学院自然科学研究重点项目 [format_title_en_publication_en_pub_year] => d9dd5c1e8a72c51eb24aeddc577c826d606367557 [publication_type] => J [author_jg] => [周双生] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.@@@[薛璇] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.@@@[姜波] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.@@@[鲁传华] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.@@@[田玉鹏] 安徽大学化学化工学院, 晶体材料国家重点实验室, 合肥, 安徽 230039, 中国.@@@[蒋明华] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国 [cite_cscd] => 8 [cite_awos] => 10 [from_id] => 76,75,73,80,78 [issue] => 19 [email] => zshuangsheng@126.com [email_c] => zshuangsheng@126.com [sys_level_num] => 1_1 [format_title_cn_publication_cn_pub_year] => 0dce27a1effac6cc8ea87bdf29581b96-1475139052 [sys_jg_type] => 11,5 [format_issn_issue_page_pub_year] => e5e05545ae1ef1e9f5227f748e618b9e1321155259 [title_en] => Synthesis and Antitumor Activities of Platinum(II) Complexes of Curcumin Analog [volume] => 69 [author_fn] => Zhou Shuangsheng; Xue Xuan; Jiang Bo; Lu Chuanhua; Tian Yupeng; Jiang Minghua [pub_year] => 2011 [check_180] => 0 [keyword_en] => curcumin; platinum(II) complex; synthesis; antitumor activity [end_page] => 2340 [article_id] => 183211,643650,375429,659695,465291 [pages] => 6 [hints] => 21 [author_cn] => 周双生;薛璇;姜波;鲁传华;田玉鹏;蒋明华; [language] => Chinese [source_type] => 351 [reference_No] => 19 [cscd_No] => CSCD:4341063 [batch] => 3250,3243,3249,3252,3241 [publication_en] => ACTA CHIMICA SINICA [hx_id] => 2377,2378,2371 [author_in] => [Zhou, S] School of Pharmacy, Anhui College of Traditional Chinese Medicine, Hefei 230031, China@@@[ Xue, X] School of Pharmacy, Anhui College of Traditional Chinese Medicine, Hefei 230031, China@@@[ Jiang, B] School of Pharmacy, Anhui College of Traditional Chinese Medicine, Hefei 230031, China@@@[ Lu, C] School of Pharmacy, Anhui College of Traditional Chinese Medicine, Hefei 230031, China@@@[ Tian, Y] School of Chemistry and Chemical Engineering, Anhui University, Hefei 230039, China, State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Jiang, M] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China [format_title_en_issn_pub_year] => 304883cbc981364ec3b33d05d6236a1c1741745387 [check_3Y] => 18 [publication_cn] => 化学学报 [title_cn] => 姜黄素类铂(Ⅱ)配合物的合成及其抗肿瘤活性 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => e55e7dc080490cea7848c95a56f21f8f-1447262221 [page] => 2335-2340 [hb_type] => 2 [article_dt] => Article [hb_batch] => issn_issue_page_pub_year_1_7 [cite_wos] => 8 [delivery_No] => 846WK [format_title] => a5979a377840ccddfbe3aee9adc7fb87816062815 [cauthor_ad] => [Zhou, SS]Anhui Coll Tradit Chinese Med, Sch Pharm, Hefei 230031, Peoples R China. [publication_29] => ACTA CHIM SINICA [author_en] => Zhou, SS; Xue, X; Jiang, B; Lu, CH; Tian, YP; Jiang, MH [get_data] => 2018-08-29 [publisher] => SCIENCE PRESS [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => CISPLATIN; APOPTOSIS [publication_iso] => Acta Chim. Sin. [format_title_en] => 65b853689b4ef685c0245ac20395ff2f-1512059267 [publisher_city] => BEIJING [pub_date] => OCT 14 [wos_No] => WOS:000296933700021 [sys_priority_field] => 76 [wos_sub] => Chemistry, Multidisciplinary [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => chinese [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => actachimicasinica [jl_country] => 中国 [jl_keyword_en] => curcumin,platinumiicomplex,antitumoractivity,synthesis [jl_keyword_cn] => 铂Ⅱ配合物,姜黄素,抗肿瘤活性,合成 [jl_publisher] => sciencepress [cite_wanfang] => 5 [clc] => O643.32 [CSSN] => 31-1320/O6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-84873837202&partnerID=40&md5=b08fc073f953bf50225ecea76daebbea [jl_clc] => o64332 [company_id] => 24,0,43,169 [sys_subject_sort] => 0,0,0 [college_parent_id] => 24,43,169 [company_test] => Array,Array,Array [author_id] => [author_test] => Array ( ) [sys_author_id_arr] => [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => 合成,antitumoractivity,铂Ⅱ配合物,抗肿瘤活性,姜黄素,curcumin,platinumiicomplex,synthesis [format_scopus_No] => 87d5b4cad5a0e9b92dc8f5bf6076fe441963013408 [format_wos_No] => 13e77ef343b06c0a273c4e84e4bda3991655656023 [standard_in] => School of Pharmacy, Anhui College of Traditional Chinese Medicine, Hefei 230031, China; School of Chemistry and Chemical Engineering, Anhui University, Hefei 230039, China; State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China [cauthor] => Zhou, S(zshuangsheng@126.com) [datebase] => Scopus [cite_scopus] => 8 [scopus_No] => 2-s2.0-84873837202 [sys_author_jg_last_arr] => 中国,中国,中国,中国,中国,中国 [jl_company_test] => uircu0,uorgidu24,uparentidu24,unameuu6676u4f53u6750u6599u7814u7a76u6240,ulevelu1 [sys_author_in_last_arr] => china [sys_author_id] => [id] => 2wZ1vWUBFjIhTVEblYtB [tags] => 0 ) [13] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3252,3254,3243,3241 [tag] => 0 [abstract_cn] => 分别以二苯胺和咔唑为端基 ,以芴为共轭桥 ,合成了两个对称型芴衍生物 :2 ,7 二 (N ,N 二苯胺基 ) 9,9 二乙基芴[2 ,7 bis(N ,N diphenylamino) 9,9 diethyl fluorene ,简称DPDEF]和 2 ,7 二咔唑基 9,9 二乙基芴 (2 ,7 dicarbazol 9′ yl 9,9 diethyl fluorene ,简称DCDEF) .用四圆X射线衍射方法测定了其晶体结构 .DPDEF单晶属于单斜晶系 ,C2 /c空间群 .晶胞参数 :a =2 864 9(4 )nm ,b =0 85 111(9)nm ,c =2 7... [keyword_cn] => DPDEF;DCDEF;芴衍生物;蓝色上转换荧光 [article_id] => 490183,597903,68715,237927,330442,661667 [clc] => Q789 [author_jg] => [曹笃霞,方奇,薛刚,许贵宝,于文涛,刘志强]山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室 济南250100,济南250100,济南250100,济南250100,济南250100,济南250100 [format_title_cn_publication_cn_pub_year] => 48f5b01d6f43485d8826427539a798701670844254 [hints] => 11 [issue] => 3 [sys_level_num] => 2_3 [sys_jg_type] => 0,5 [format_issn_issue_page_pub_year] => 19f6abc8013cd0667d4343d4fa6bc9a8-1247977769 [source_type] => 351 [pub_year] => 2004 [pub_date] => FEB 14 [pages] => 5 [from_id] => 76,75,73,80,85,78 [author_cn] => 曹笃霞,方奇,薛刚,许贵宝,于文涛,刘志强 [issn] => 0567-7351 [uri] => http://kns.cnki.net/kns/detail/detail.aspx?FileName=HXXB200403000&DbName=CJFQ2004 [publication_cn] => 化学学报 [title_cn] => 芴衍生物的合成、结构与蓝色(λ_(max)=418nm)双光子荧光 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 2d27ce0d50159282dc7f50cee8fb78ef-1872726298 [page] => 225-229 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [format_title_en] => 188ea0d4119bee1a7cc4fca98db166f6-69771576 [format_title] => 250a1db45481d6f404b588f30b4285c31243066833 [hx_id] => 2377,2378,2371 [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_keyword_cn] => dcdef,dpdef,蓝色上转换荧光,芴衍生物 [jl_clc] => q789 [author_in] => [Cao, D.-X] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Fang, Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Xue, G] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Xu, G.-B] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Yu, W.-T] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Liu, Z.-Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China [company_id] => 24,0,151 [author_id] => [author_test] => Array ( ) [sys_author_id_arr] => [jl_publication_cn_publication_en] => 化学学报 [jl_keyword_cn_keyword_en] => dcdef,dpdef,蓝色上转换荧光,芴衍生物 [cite_wos] => 8 [publication_en] => ACTA CHIMICA SINICA [fund_No] => 国家自然科学基金; 高等学校骨干教师资助计划项目 [check_3Y] => 3 [language] => Chinese [delivery_No] => 773BK [cauthor_ad] => [Fang, Q]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Cao, DX; Fang, Q; Xue, G; Xu, GB; Yu, WT; Liu, ZQ [reference] => Abbotto A, 2002, ORG LETT, V4, P1495, DOI 10.1021/ol025703v@@@Albota M, 1998, SCIENCE, V281, P1653, DOI 10.1126/science.281.5383.1653@@@Belfield KD, 2002, J LUMIN, V97, P141, DOI 10.1016/S0022-2313(02)00216-8@@@Bhawalkar JD, 1996, REP PROG PHYS, V59, P1041, DOI@@@10.1088/0034-4885/59/9/001@@@Cho BR, 2001, J AM CHEM SOC, V123, P10039, DOI 10.1021/ja010770q@@@HIROSUKE T, 1993, CHEM ABSTR, V118, P22035@@@Kannan R, 2001, CHEM MATER, V13, P1896, DOI 10.1021/cm000747o@@@Liu ZQ, 2002, CHEM COMMUN, P2900, DOI 10.1039/b207210f@@@REYNOLDS GA, 1975, OPT COMMUN, V13, P222, DOI@@@10.1016/0030-4018(75)90085-1@@@Ventelon L, 2001, ANGEW CHEM INT EDIT, V40, P2098, DOI@@@10.1002/1521-3773(20010601)40:11<2098::AID-ANIE2098>3.3.CO;2-S@@@Xu C, 1996, J OPT SOC AM B, V13, P481, DOI 10.1364/JOSAB.13.000481 [cite_wanfang] => 12 [format_title_en_issn_pub_year] => 64a968079f34c163d3cd79d21ce23e31-1833161579 [datebase] => Scopus [format_scopus_No] => 926a29348b92be8fdfea5f26f1f4f7c885200320 [publication_29] => ACTA CHIM SINICA [end_page] => 229 [abstract_en] => Two symmetrical fluorene derivatives with diphenylamino and carbazolyl as terminal group have been synthesized, which are named 2,7-bis(N, N-diphenylamino)-9,9-diethyl-fluorene (abbreviated to DPDEF) and 2,7-dicarbazol-9\'-yl-9,9-diethyl-fluorene (abbreviated to DCDEF). Their crystal structures were determined by four-circle X-ray diffraction. DPDEF belongs to monoclinic system, C2/c space group, a = 2. 8649 (4) nm, 3 b 0.85111(9) nm, c = 2.7012(4) nm, beta = 100.982(11)degrees, V = 6.4657(14) nm(3), Z = 8, D-c = 1.144 g(.)cm(-3), R = 0.0581. DCDEF belongs to monoclinic system, P2(1)/c space group, a = 0. 92794 (12) nm, b = 0.88561 (9) nm, c = 3.7236(4) nm, beta = 96.914(9)degrees, V = 3.0378 (6) nm(3), Z = 4, D-c = 1.208 g(.)cm(-3), R = 0.0652. The fluorene bridge shows perfect planarity with very small dihedral angle (3.0degrees for DPDEF and 5.8degrees for DCDEF respectively) between two involved phenyls. Pumped by 730 nm laser pulses, DPDEF exhibited strong blue upconverted fluorescence (lambda(max) = 418 nm) in THF with the two-photon absorption cross-section of 15 GM. [researcherID] => Xu, Guibao/F-3461-2010; Liu, Zhiqiang/D-9589-2017 [orcID] => Liu, Zhiqiang/0000-0001-7863-1759 [publication_type] => J [begin_page] => 225 [author_en] => Cao, DX; Fang, Q; Xue, G; Xu, GB; Yu, WT; Liu, ZQ [format_cscd_No] => 9168fe78a449ede2d3115624f6e6b909616083794 [volume] => 62 [publisher] => SCIENCE CHINA PRESS [get_data] => 2018-08-29 [keyword_en] => DPDEF; DCDEF; fluorene derivative; blue up-converted fluorescence [keyword_plu] => CROSS-SECTIONS; DYES; CHROMOPHORES; FLUOROPHORES; EXCITATION [publication_iso] => Acta Chim. Sin. [format_title_en_publication_en_pub_year] => 675a4cee8d971a45094802d7bbcecb25561794884 [cite_scopus] => 9 [publisher_city] => BEIJING [cite_cscd] => 6 [publication_info] => 0567-7351(2004)62:3<225:WYSWDH>2.0.TX;2-X [email_c] => fangqi@ic.sdu.edu.cn [email] => fangqi@icm.sdu.edu.cn [reference_No] => 12 [cite_awos] => 10 [cscd_No] => CSCD:1612211 [wos_No] => WOS:000188877700001 [format_wos_No] => ac83573a5d2fd25f1d42e0de92cfbde8-1623314436 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [standard_in] => State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China [scopus_No] => 2-s2.0-33749138073 [title_en] => Synthesis, structure and two-photon excited blue fluorescence of fluorene derivatives [jl_language] => chinese [jl_publication_en] => actachimicasinica [sys_author_jg_last_arr] => 济南250100 [jl_country] => 中国 [jl_keyword_en] => dcdef,fluorenederivative,dpdef,blueupconvertedfluorescence [sys_author_in_last_arr] => china [jl_publisher] => sciencechinapress [sys_author_id] => [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [id] => Ow5HvmUBFjIhTVEbZSTq [tags] => 0 ) [14] => Array ( [batch2] => 1,2,6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33749386195&partnerID=40&md5=c2d0b7787552109667281591e0466af7 [tag] => 0 [abstract_cn] => 合成了3个系列各含有单支、双支和三支结构的9个均三嗪衍生物,测定了它们的线性吸收和发射性质以及双光子吸收和发射性质.随着三嗪环上侧链数目的增加,线性吸收谱(吸收峰位于390-440 nm)、荧光谱(发射峰位于460- 580 nm)和双光子荧光谱(激发波长800 nm)都发生红移;各种光谱的强度逐渐增强;基态与激发态的偶极矩之差△μeg也逐渐增大.另外,从单支到三支结构,双光子吸收截面σ随侧链数目呈非线性增加.这表明多支结构的双光子吸收存在显著的增强效应. [keyword_cn] => 均三嗪;;多支结构;;合成;;双光子吸收;;增强效应 [fund_No] => 国家自然科学基金; 教育部高校骨干教师资助项目 [article_id] => 597893,662037,489277,328242,82466,249251 [clc] => O627.4; [author_jg] => [崔月芝] 山东轻工业学院化工系, 济南, 山东 250100, 中国.@@@[方奇] 山东轻工业学院化工系, 济南, 山东 250100, 中国.@@@[薛刚] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[许贵宝] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[于文涛] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[尹磊] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => a3d99b3100cfa8126c4b512e21fee1f3 [hints] => 10 [issue] => 15 [author_first] => 崔月芝 [sys_level_num] => 2_3 [sys_jg_type] => 10,3,5 [format_issn_issue_page_pub_year] => 9ddf3571c1f1020bf2492e1986b5d7b8 [source_type] => 351 [pub_year] => 2005 [pub_date] => AUG 14 [pages] => 8 [from_id] => 76,75,73,80,78,85 [author_cn] => 崔月芝;方奇;薛刚;许贵宝;于文涛;尹磊 [issn] => 0567-7351 [batch] => 3249,3250,3252,3254,3243,3241 [publication_cn] => 化学学报 [title_cn] => 多支结构的均三嗪衍生物的合成及双光子吸收性质 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 40d3a035774ebcd95b86e7ff8433aa5d [page] => 50-57 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 8 [check_3Y] => 7 [language] => Chinese [delivery_No] => 954OA [format_title] => 66f7e02616d7de092256195b0656c38c-351519933 [cauthor_ad] => [Cui, YZ]Shandong Coll Light Ind, Dept Chem Engn, Jinan 250100, Peoples R China. [author_fn] => Cui, YZ; Fang, Q; Xue, G; Xu, GB; Yu, WT; Yin, L [reference] => Abbotto A, 2003, CHEM COMMUN, P2144, DOI 10.1039/b305995b@@@Abbotto A, 2000, ADV MATER, V12, P1963, DOI@@@10.1002/1521-4095(200012)12:24<1963::AID-ADMA1963>3.3.CO;2-J@@@Albota M, 1998, SCIENCE, V281, P1653, DOI 10.1126/science.281.5383.1653@@@Albota MA, 1998, APPL OPTICS, V37, P7352, DOI 10.1364/AO.37.007352@@@Beljonne D, 2002, ADV FUNCT MATER, V12, P631, DOI@@@10.1002/1616-3028(20020916)12:9<631::AID-ADFM631>3.0.CO;2-W@@@Cho B R, 2001, Am. Chem. Soc, V123, P10039@@@Chung SJ, 1999, J PHYS CHEM B, V103, P10741, DOI 10.1021/jp992846z@@@Cui YZ, 2003, CHEM PHYS LETT, V377, P507, DOI@@@10.1016/S0009-2614(03)01207-7@@@[崔月芝 Cui Yuezhi], 2003, [化学学报, Acta Chemical Sinica], V61, P307@@@DEMAS JN, 1971, J PHYS CHEM-US, V75, P991@@@Drobizhev M, 2003, J PHYS CHEM B, V107, P7540, DOI 10.1021/jp0349861@@@Ehrlich JE, 1997, OPT LETT, V22, P1843, DOI 10.1364/OL.22.001843@@@He GS, 1997, J APPL PHYS, V81, P2529, DOI 10.1063/1.364303@@@Kim OK, 2000, CHEM MATER, V12, P284, DOI 10.1021/cm990662r@@@Lakowicz J. R., 1983, PRINCIPLES FLUORESCE, P190@@@Liu ZQ, 2003, CHEM-EUR J, V9, P5074, DOI 10.1002/chem.200304833@@@Macak P, 2000, Chem. Phys, V113, P7055@@@Meng FS, 2004, CHEM LETT, V33, P470, DOI 10.1246/cl.2004.470@@@Porres L, 2004, ORG LETT, V6, P47, DOI 10.1021/ol036041s@@@Reinhardt BA, 1998, CHEM MATER, V10, P1863, DOI 10.1021/cm980036e@@@Spangler C. W., 1999, MATER CHEM, V9, P2013@@@Ventelon L, 1999, CHEM COMMUN, P2055, DOI 10.1039/a906182g@@@Xu C, 1996, J OPT SOC AM B, V13, P481, DOI 10.1364/JOSAB.13.000481@@@Yoo J, 2003, ORG LETT, V5, P645, DOI 10.1021/ol027343h [publication_29] => ACTA CHIM SINICA [end_page] => 1428 [abstract_en] => Three series of multi-branched s-triazine derivatives with one, two or three branches have been synthesized. For each series, the linear absorption (peak position: 390 similar to 440 nm) and emission spectra (peak position: 460580 nm), along with the two-photon exited fluorescence spectra excited at 800 nm, showed regular red-shifts as the branch number was increased, and their spectral intensities were significantly enlarged from one- to three-branched structures. In addition, the difference of dipole moment (Delta mu(eg)) between the ground and the excited states became larger as the branch number was increased from 1 to 3. The two-photon absorption cross section sigma was non-linearly increased with the increase of the branch number and the reduced sigma, indicating a remarkable cooperative enhancement of sigma in the multi-branched s-triazine derivatives. [researcherID] => Xu, Guibao/F-3461-2010 [author_in] => [Cui, Y.-Z] Department of Chemical Engineering, Shandong College of Light Industry, Jinan 250100, China, State Key Laboratory of Crystal Material, Shandong University, Jinan 250100, China@@@[ Fang, Q] State Key Laboratory of Crystal Material, Shandong University, Jinan 250100, China, Key Laboratory of Organofluorine Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai 200032, China@@@[ Xue, G] State Key Laboratory of Crystal Material, Shandong University, Jinan 250100, China@@@[ Xu, G.-B] State Key Laboratory of Crystal Material, Shandong University, Jinan 250100, China@@@[ Yu, W.-T] State Key Laboratory of Crystal Material, Shandong University, Jinan 250100, China@@@[ Yin, L] State Key Laboratory of Crystal Material, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 1421 [author_en] => Cui, YZ; Fang, Q; Xue, G; Xu, GB; Yu, WT; Yin, L [volume] => 63 [get_data] => 2018-08-29 [publisher] => SCIENCE PRESS [keyword_en] => s-triazine; multi-branched; synthesis; two-photon absorption;; cooperative enhancement [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => ENHANCED 2-PHOTON ABSORPTION; EXCITATION CROSS-SECTIONS; COOPERATIVE ENHANCEMENT; OCTUPOLAR COMPOUNDS; OPTICAL-PROPERTIES; FLUORESCENCE; FLUOROPHORES; MOLECULES; DESIGN; CHROMOPHORES [publication_iso] => Acta Chim. Sin. [format_title_en] => 8ed460a197d2a14cfb186a0baad1567b971564951 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 24 [email] => fangqi@icm.sdu.edu.cn [cite_awos] => 10 [wos_No] => WOS:000231163200008 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Syntheses and two-photon absorption properties of multi-branched s-triazine derivatives [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => chinese [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => actachimicasinica [jl_country] => 中国,纳米比亚,瑞士,印度 [jl_keyword_en] => multibranched,cooperativeenhancement,twophotonabsorption,striazine,synthesis [jl_keyword_cn] => 多支结构,增强效应,合成,双光子吸收,均三嗪 [jl_clc] => o6274 [jl_publisher] => sciencepress [company_id] => 24,0,0,0,0,0 [sys_subject_sort] => 0 [college_parent_id] => 24 [company_test] => Array [author_id] => 20672,25103,25191 [author_test] => Array ( [0] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 2 [name] => 方奇 [irtag] => 0 [t_index] => 0 [person_id] => 20672 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 6 [name] => 尹莉 [irtag] => 8 [t_index] => 0 [person_id] => 25103 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 5 [name] => 于文涛 [sys_author_id] => Array ( [0] => 20672 ) [irtag] => 7 [t_index] => 0 [person_id] => 25191 ) ) [sys_author_id_arr] => 20672方奇 [cscd_No] => CSCD:2109798 [jl_publication_cn_publication_en] => 化学学报,actachimicasinica [jl_keyword_cn_keyword_en] => 双光子吸收,增强效应,合成,多支结构,cooperativeenhancement,striazine,multibranched,twophotonabsorption,均三嗪,synthesis [sys_author_id] => [format_cscd_No] => 6dcb95e67109def1c915f1171c36d8d2 [format_title_en_publication_en_pub_year] => 4e4a3171180d4cd9cf450db04dd7591e [format_wos_No] => 1cbdd56f073787e8357f9f26216805ab [format_title_en_issn_pub_year] => fcdf770c912a876e63f1d568bc5efa27 [format_scopus_No] => ea3efd92341d5574cd1a8bb6c79725cd [standard_in] => Department of Chemical Engineering, Shandong College of Light Industry, Jinan 250100, China; State Key Laboratory of Crystal Material, Shandong University, Jinan 250100, China; Key Laboratory of Organofluorine Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai 200032, China [datebase] => Scopus [cite_scopus] => 8 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-33749386195 [jl_pub_year] => 2005 [jl_author_test] => usureu0,usureu1,upersonid20672,unameuu65b9u5947,uuindex2,usysauthoridu20672,uirtag0,uuindex6,upersonid25103,utindex0,unameuu5c39u8389,uirmagnum0,uirtag8 [sys_author_jg_last_arr] => 中国 [jl_company_test] => uircu0,uorgidu24,uparentidu24,unameuu6676u4f53u6750u6599u7814u7a76u6240,ulevelu1 [sys_author_in_last_arr] => china [id] => MQ5HvmUBFjIhTVEbZSTq [tags] => 0 ) [15] => Array ( [batch2] => 1,2,6 [batch] => 3250,3243,3241,3254 [tag] => 0 [abstract_cn] => 测量了Tm^3+:NaY(WO4)2晶体的吸收光谱、发射光谱和激发光谱,利用J-O理论计算了钨酸钇钠晶体的强度参数:Ω2=7.21304×10^-20cm^2,Ω4=O.504766×10^-22cm^2,Ω6=O.977784×10^-20cm^2,以及Tm^3+的光学参数包括各能级的荧光寿命和荧光分支比、积分发射截面等,在计算了Tm^3+的自发辐射概率时,同时考虑了电偶极跃迁和磁偶极跃迁.研究了其发光特性和跃迁通道,发现存在^1D2+^3H6→^1G4+^3F4的交叉弛豫. [keyword_cn] => 钨酸钇钠晶体;TM^3+;磁偶极;偶极跃迁;能级;积分;分支比;自发辐射;光谱特性;发光特性; [clc] => O734 O482.31 [author_jg] => [宋峰;苏静;谭浩;商美茹;吴朝晖;田建国;张光寅]南开大学光子学中心,天津300071,中国.@@@[程振祥;陈焕矗]山东大学晶体研究所,济南250100,中国 [format_title_cn_publication_cn_pub_year] => f1869b5b2f93047cfca6ff017174558c1156627632 [from_id] => 76,78,73,85 [issue] => 10 [sys_level_num] => 2_1 [sys_jg_type] => 11 [source_type] => 351 [pub_year] => 2004 [article_id] => 611336,490583,67992,329272 [pages] => 5 [hints] => 3 [author_cn] => 宋峰[1];苏静[1];谭浩[1];商美茹[1];吴朝晖[1];田建国[1];张光寅[1];程振祥[2];陈焕矗[2] [issn] => 1000-3290 [uri] => http://lib.cqvip.com/qk/94684X/200410/10788496.html [publication_cn] => 物理学报 [title_cn] => 钨酸钇钠晶体中Tm^3+的光谱特性 [CSSN] => 11-1958/O4 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 2d87ce30651d96d32b3b0a2f54d2c8ce-1070762718 [hb_type] => 2 [jl_publication_cn] => 物理学报 [jl_country] => 中国 [jl_keyword_cn] => ,磁偶极,积分,钨酸钇钠晶体,发光特性,偶极跃迁,tm3,光谱特性,能级,分支比,自发辐射 [jl_clc] => o734o48231 [author_in] => [Song, F; Su, J; Tan, H; Shang, MR; Wu, ZH; Tian, JG; Zhang, GY; Cheng, ZX; Chen, HC]Nankai Univ, Photon Ctr, Tianjin 300071, Peoples R China.@@@[Song, F; Su, J; Tan, H; Shang, MR; Wu, ZH; Tian, JG; Zhang, GY; Cheng, ZX; Chen, HC] Shandong Univ, Inst Crystal, Jinan 250100, Peoples R China. [company_id] => 24,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => [author_test] => Array ( ) [sys_author_id_arr] => [jl_publication_cn_publication_en] => 物理学报 [jl_keyword_cn_keyword_en] => 分支比,tm3,发光特性,积分,钨酸钇钠晶体,能级,光谱特性,自发辐射,偶极跃迁,磁偶极 [hb_batch] => grant_no [author_first] => 宋峰 [cite_wos] => 7 [publication_en] => ACTA PHYSICA SINICA [check_3Y] => 2 [language] => Chinese [delivery_No] => 861MR [cauthor_ad] => [Song, F]Nankai Univ, Photon Ctr, Tianjin 300071, Peoples R China. [format_title] => 1564060efd35ad9fe6a8caf1f39a52f1-1454619937 [author_fn] => Song, F; Su, J; Tan, H; Shang, MR; Wu, ZH; Tian, JG; Zhang, GY; Cheng, ZX; Chen, HC [cauthor] => Song, F(fsong@nankai.edu.cn) [format_title_en_issn_pub_year] => c99a40176b31bee6c71a1768f3c691371836418543 [datebase] => Scopus [format_scopus_No] => f6f4949aa49311213335ff05b0e6374527611012 [publication_29] => ACTA PHYS SIN-CH ED [end_page] => 3595 [abstract_en] => Absorption spectra, emission spectra and excitation spectra of Tm3+-doped NaY(WO4)(2) crystals have been measured at room temperature. Such parameters as the intensity parameter, oscillation strength, rate of spontaneous emissions, lifetime and integrated emission cross section have been calculated according to Judd-Ofelt theory and absorption spectra. The intensity parameters are Omega(2) = 8.67319 x 10(-20) cm(2), Omega(4) = 1.70424 x 10(-20) cm(2), Omega(6) = 1.55845 x 10(-20) cm(2). When calculating the spontaneous emission lifetimes, we take into account the magnetic dipole transitions. From the measured spectra, the mechanism of transitions has been analyzed in detail and the cross relaxation D-1(2) + H-3(6) --> (1)G(4) + F-3(4) were put for-ward and verified. [researcherID] => Cheng, Zhenxiang/F-4638-2012 [orcID] => Cheng, Zhenxiang/0000-0003-4847-2907 [article_dt] => Article [publication_type] => J [begin_page] => 3591 [author_en] => Song, F; Su, J; Tan, H; Shang, MR; Wu, ZH; Tian, JG; Zhang, GY; Cheng, ZX; Chen, HC [volume] => 53 [publisher] => CHINESE PHYSICAL SOC [get_data] => 2018-08-29 [keyword_en] => Tm3+ : NaY( WO4)(2); absorption spectra; emission spectra; excitation; spectra [page] => 3591-3595 [keyword_plu] => RARE-EARTH IONS; INTENSITIES [format_publication_cn] => 94ac9f922a2bd4c3b29ced57c489e9b7-391537303 [publication_iso] => Acta Phys. Sin. [format_title_en_publication_en_pub_year] => 95f4655581cb7e3c9664cddc5e69ef1a738857820 [cite_scopus] => 6 [format_title_en] => d3424248c6a9ece80464c6dc28052bfe-548569474 [publisher_city] => BEIJING [pub_date] => OCT [cauthor_order] => 1 [hx_id] => 2378,2371 [email] => fsong@nankai.edu.cn [reference_No] => 18 [format_issn_issue_page_pub_year] => d50cf3062d22d6ff8a6f251b0a14deb5-2076116384 [cite_awos] => 8 [wos_No] => WOS:000224421300067 [sys_priority_field] => 73 [classification_pub] => WLHPA [format_wos_No] => 1e028d397ebacf93d71bc887d3e06500-106967575 [wos_sub] => Physics, Multidisciplinary [research_area] => Physics [cauthor_back] => Song, F [check_180] => 0 [publisher_ad] => P O BOX 603, BEIJING 100080, PEOPLES R CHINA [standard_in] => Photonics Ctr., Nankai Univ., Tianjin 300071, China; Inst. of Crystal, Shandong Univ., Jinan 250100, China [scopus_No] => 2-s2.0-8844236335 [title_en] => Spectroscopic properties of Tm3+-doped NaY(WO4)(2) crystals [format_publication_en] => 11968562f496834807ca5004bd980c96-838396646 [jl_language] => chinese [jl_article_dt] => 期刊论文 [jl_publication_en] => actaphysicasinica [sys_author_jg_last_arr] => 中国,中国 [jl_company_test] => uircu0,uorgidu24,uparentidu24,unameuu6676u4f53u6750u6599u7814u7a76u6240,ulevelu1 [jl_keyword_en] => absorptionspectra,spectra,emissionspectra,excitation,tm3naywo42 [sys_author_in_last_arr] => peoplesrchina [jl_publisher] => chinesephysicalsoc [sys_author_id] => [id] => CwkxvmUBFjIhTVEbTO_9 [tags] => 0 ) [16] => Array ( [batch2] => 1,2,5,6 [batch] => 3249,0,3250,3252,3254,3246,3243,3241 [tag] => 0 [abstract_cn] => 采用Sol-gel法制备出气敏材料La0.68Pb0.32FeO3纳米粉体。该粉体材料具有正交钙钛矿结构,晶胞参数a=0.555 62 nm,b=0.559 65 nm,c=0.781 85 nm,晶胞体积v=0.243 1 nm3,平均粒径约为20 nm。用该粉体制成气敏元件,并测试了该粉体材料在乙醇、丙酮和汽油中的气敏特性,测试结果表明:相比空气而言, 在乙醇气氛中的La0.68Pb0.32FeO3电导值升高,呈现出n-型半导体载流子的导电特性;在丙酮和汽油气氛中的La0.68Pb0.32FeO3的电导值降低,呈现出p-型半导体载流子的导电特性。该材料对乙醇具有极高的气敏灵敏性,在0.01... [keyword_cn] => 钙钛矿结构;纳米材料;气敏 [article_id] => 263038,397365,330461,661478,593432,328,491385 [clc] => TF124 [author_jg] => [张玲] 山东大学, 济南, 山东 250100, 中国.@@@[胡季帆] 山东大学, 济南, 山东 250100, 中国.@@@[秦宏伟] 山东大学, 济南, 山东 250100, 中国.@@@[薛天锋] 山东大学, 济南, 山东 250100, 中国.@@@[安康] 山东大学, 济南, 山东 250100, 中国.@@@[韩涛] 山东大学, 济南, 山东 250100, 中国.@@@[宋鹏] 山东大学, 济南, 山东 250100, 中国.@@@[周莹] 山东大学, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => abadaa51bd44264963c460f0a8a89573-1139600343 [hints] => 4 [issue] => 3 [sys_level_num] => 2_3 [sys_jg_type] => 0,8,8 [format_issn_issue_page_pub_year] => 8af8271aa0a2dac43a01c3c536107a79927811392 [source_type] => 351 [pub_year] => 2004 [pub_date] => MAR [pages] => 4 [from_id] => 76,75,74,73,80,85,78 [author_cn] => 张玲,胡季帆,秦宏伟,薛天锋,安康,韩涛,宋鹏,周莹 [issn] => 1002-185X [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-2942720904&partnerID=40&md5=2f45d0c15815c71e0f58ca45d7844c37 [publication_cn] => 稀有金属材料与工程 [title_cn] => 钙钛矿结构La_(0.68)Pb_(0.32)FeO_3纳米材料的制备及气敏特性研究 [CSSN] => 61-1154/TG [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => a4a63874071d35e1de4a4381980c0d951057821033 [page] => 293-296 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => RARE METAL MATERIALS AND ENGINEERING [cite_wos] => 7 [fund_No] => 国家自然科学基金资助 [check_3Y] => 2 [language] => Chinese [delivery_No] => 807UJ [format_title] => 87db3b8f172cbdac9c11975e5e16759d-347032022 [cauthor_ad] => [Ling, Z]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Ling, Z; Hu, JF; Qin, HW; Xue, TF; An, K; Tao, H; Peng, S; Ying, Z [reference] => [惠春 Hui Chun], 2002, 稀有金属材料与工程, V31, P315@@@Kong LB, 1996, SENSOR ACTUAT B-CHEM, V30, P217, DOI@@@10.1016/0925-4005(96)80052-9@@@Maria Cristina Carotta, 1998, Sensors and Actuators, VB48, P270@@@[牛新书 Niu Xinshu], 2002, 稀有金属材料与工程, V31, P367@@@[徐甲强 Xu Jiaqiang], 2002, [硅酸盐学报, Journal of the Chinese Silicate@@@Society], V30, P321@@@Yude Wang, 2001, Materials Letters, V49, P361, DOI@@@10.1016/S0167-577X(00)00400-6@@@吴凤清, 1994, 高等学校化学学报, V15, P803@@@蒲正利, 2002, 稀有金属材料与工程, V31, P710 [publication_29] => RARE METAL MAT ENG [end_page] => 296 [abstract_en] => The sample La0.68Pb0.32FeO3 was prepared by using a sol-gel method. The X-ray diffraction patterns indicated that sample La0.68Pb0.32FeO3 has an othogonal perovskite structure. The lattice parameter a, b, c, and cell-volume nu are 0.555 62 nm, 0.559 65 nm, 0.781 85 nm, and 0.243 1 nm(3), respectively. The grain size is about 20nm. The gas-sensing properties have been studied in alcohol, acetone and gasoline. The experimental results revealed that the sample La0.68Pb0.32FeO3 shows a n-type semiconductor in alcohol, but a p-type semiconductor in acetone and gasoline. Compared with the conductivity of the sample La0.68Pb0.32FeO3 in air, that of the sample La0.68Pb0.32FeO3 increases in alcohol, but decreases in acetone and gasoline. Lao.68PbO.32FeO3 possesses a high sensitivity to alcohol. The sensitivity in 0.01% and 0.1% alcohol at T=200degreesC for La0.68Pb0.32FeO3 is 51 and 522, respectively. The best operating temperature range is 180degreesCsimilar to220degreesC in alcohol. The sensitivity in 0.05% acetone at T=240degreesC for La0.68Pb0.32FeO3 is 30. The best operating temperature range is 220degreesCsimilar to260degreesC in acetone. We suggest that the La0.68Pb0.32FeO3 has electron/hole complek conductivity mechanisms . [researcherID] => Han, Tao/C-4140-2013 [author_in] => [Zhang, L] Shandong Univ., Ji'nan 250100, China@@@[ Hu, J] Shandong Univ., Ji'nan 250100, China@@@[ Qin, H] Shandong Univ., Ji'nan 250100, China@@@[ Xue, T] Shandong Univ., Ji'nan 250100, China@@@[ An, K] Shandong Univ., Ji'nan 250100, China@@@[ Han, T] Shandong Univ., Ji'nan 250100, China@@@[ Song, P] Shandong Univ., Ji'nan 250100, China@@@[ Zhou, Y] Shandong Univ., Ji'nan 250100, China [publication_type] => J [begin_page] => 293 [author_en] => Ling, Z; Hu, JF; Qin, HW; Xue, TF; An, K; Tao, H; Peng, S; Ying, Z [volume] => 33 [get_data] => 2018-08-29 [publisher] => NORTHWEST INST NONFERROUS METAL RESEARCH [keyword_en] => perovskite structure; nano-materials; gas-sensing [format_publication_cn] => bd451201223fc4b5c4770b7e4076b04e-131793275 [keyword_plu] => MECHANISM [publication_iso] => Rare Metal Mat. Eng. [format_title_en] => 6a4e82cb9204f0dcbfbb39a28293a7ba-812081661 [publisher_city] => SHAANXI [hx_id] => 2376,2377,2378,2371 [reference_No] => 8 [email] => hujf@sdu.edu.cn [cite_awos] => 7 [wos_No] => WOS:000220526100017 [wos_sub] => Materials Science, Multidisciplinary; Metallurgy & Metallurgical; Engineering [research_area] => Materials Science; Metallurgy & Metallurgical Engineering [check_180] => 0 [publisher_ad] => C/O RARE METAL MATERIAL ENGINEERING PRESS, PO BOX 51, XIAN, SHAANXI; 710016, PEOPLES R CHINA [title_en] => Studies on preparation and gas-sensing properties of La0.68Pb0.32FeO3 nano-materials with peroskite structure [format_publication_en] => c131c72c99f1bef2da2a611ae08967d41692360400 [jl_language] => chinese [jl_publication_cn] => 稀有金属材料与工程 [jl_article_dt] => 期刊论文 [jl_publication_en] => raremetalmaterialsandengineering [jl_country] => 中国,中国 [jl_keyword_en] => gassensing,perovskitestructure,nanomaterials [jl_keyword_cn] => 纳米材料,钙钛矿结构,气敏 [jl_clc] => tf124 [jl_publisher] => northwestinstnonferrousmetalresearch [company_id] => 24,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => 23099,21178,25543,25542 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 胡季帆 [irtag] => 7 [t_index] => 0 [person_id] => 21178 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 秦宏伟 [irtag] => 7 [t_index] => 0 [person_id] => 23099 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 张玲 [irtag] => 7 [t_index] => 0 [person_id] => 25543 ) [3] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 张玲 [irtag] => 7 [t_index] => 0 [person_id] => 25542 ) ) [sys_author_id_arr] => [cscd_No] => CSCD:1584300 [ei_No] => 2005389364704 [jl_publication_cn_publication_en] => 稀有金属材料与工程,raremetalmaterialsandengineering [jl_keyword_cn_keyword_en] => gassensing,气敏,nanomaterials,纳米材料,钙钛矿结构,perovskitestructure [sys_author_id] => [format_cscd_No] => 933704191e0479ab320524d84957c163-443968079 [format_title_en_publication_en_pub_year] => 687377f914840767510732dc5a288d43-80679778 [format_wos_No] => ca5ef273e74b1c4531d1d0c1b9883b6a539062418 [format_title_en_issn_pub_year] => 7a3c3956335902f3f7319e5ddc65baaa851379048 [format_ei_No] => 284e104baecfd2ad9bf6059716cb9ce6-1430841252 [imf_once] => 0.437 [author_first] => [jcr_wos] => Q3 [imf_5] => 0 [profession_stu] => [thesis_au] => [highly_article] => [student_No] => [grant_bulletin_No] => [dom_ranking] => [province] => [complete_time] => [format_scopus_No] => 6440d00744027ba7673e12d1190502e42069364584 [bulletin_date] => [fund_amount] => [attachment_text] => [name_editor] => [subject_gb1] => [phone] => [book_alias] => [application_date] => [fund_type] => [isbn_10] => [classification_No] => [cssci_No] => [responsibility] => [uncontrolled_terms] => [controlled_terms] => [top_article] => [student_type] => [agency] => [classification_pub] => XJCGE [standard_in] => Shandong Univ., Ji'nan 250100, China [country] => [open_time] => [institution_first] => Shandong Univ. [cauthor] => [datebase] => Scopus [fund_CSSCI] => [school_stu] => [main_cword] => [create_time] => [degree] => [job_no] => [volume_label] => [numerical_index] => [main_eword] => [awards_type] => [birthday] => [sponsor] => [imf] => 0.236 [bulletin_No] => [cite_scopus] => 4 [institution_name] => [grant_bulletin_date] => [department_tutor1] => [abstract_type] => [legal_status] => [email_c] => [discipline_name] => [institution_type] => [sys_priority_field] => 76 [oral_time] => [name_tutor1] => [cauthor_back] => [scopus_No] => 2-s2.0-2942720904 [positional_titles] => [id] => Dg5HvmUBFjIhTVEbnjJE [tags] => 0 ) [17] => Array ( [batch2] => 1,2 [batch] => 3250,3249,3252,3254,3241 [tag] => 0 [abstract_cn] => 以AlCl3和Li3N为前驱物,利用过量Li3N与水反应大量放热现象,引发两种前驱物之间的固相反应合成了AlN纳米粉.X射线衍射分析、红外吸收光谱、透射电子显微镜以及X射线光电子能谱测试结果表明,利用这种新的合成方法制备的氮化铝主要是六方相,而且颗粒细小.另外,这种方法反应迅速、操作过程简便,有利于降低制备成本和扩大制备规模. [keyword_cn] => 氮化铝;纳米粉;固相反应合成;水引发剂; [clc] => O614.31 TB383 [author_jg] => [李凯] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[董守义] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[郝霄鹏] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[崔得良] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[刘振刚] 山东大学化学与化工学院, 济南, 山东 250100, 中国.@@@[于美燕] 山东大学化学与化工学院, 济南, 山东 250100, 中国.@@@[王琪珑] 山东大学化学与化工学院, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => 4d7589a18bdfca76b59f8fcf5b72628e-1673590898 [from_id] => 75,78,73,80,85 [issue] => 12 [sys_level_num] => 2_1 [sys_jg_type] => 10,5 [source_type] => 351 [pub_year] => 2004 [article_id] => 68524,620411,249098,663322,329730 [pages] => 4 [hints] => 8 [author_cn] => 李凯 [1];刘振刚 [2];于美燕 [2];董守义 [1];王琪珑 [2];郝霄鹏 [1];崔得良 [1] [issn] => 0567-7351 [uri] => http://lib.cqvip.com/qk/91047X/200412/9918180.html [publication_cn] => 化学学报 [title_cn] => 利用水引发固相反应方法合成氮化铝纳米粉 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 5d788508b55bf4258eb40d2768f224f1-1404738250 [hb_type] => 2 [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 7 [fund_No] => 国家自然科学基金; 教育部博士点基金; 山东省自然科学基金资助项目 [check_3Y] => 7 [language] => Chinese [delivery_No] => 831TL [format_title] => c144c5f92b101f74fd5f97de552340a61064673409 [cauthor_ad] => [Li, K]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Li, K; Liu, ZG; Yu, MY; Dong, SY; Wang, QL; Hao, XP; Cui, DL [reference] => Hao X P, 2002, Cryst. Growth, V242, P229@@@LI X, 1990, J APPL PHYS, V68, P5369, DOI 10.1063/1.347035@@@Reier T, 1998, ELECTROCHIM ACTA, V43, P149, DOI@@@10.1016/S0013-4686(97)00243-0@@@ROMAN YG, 1989, THIN SOLID FILMS, V169, P241, DOI@@@10.1016/0040-6090(89)90707-4@@@SHIN J, 2000, J AM CERAM SOC, V83, P5@@@Song ZR, 2003, MATER LETT, V57, P4643, DOI 10.1016/S0167-577X(03)00377-X@@@VAIDHYANATHAN B, 2000, J MATER RES, V15, P4@@@YU Q, 2003, J AM CERAM SOC, V86, P7@@@YU Q, 2003, J EUR CERAM SOC, V23, P2015@@@金海波, 2000, 金属学报, V36, P775@@@郑新和, 2001, 中国稀土学报, V19, P430@@@戴长虹, 1999, 金属学报, V32, P1221@@@蔡杰, 1999, 真空电了技术, V2, P28@@@JCPDS No. 08-0262@@@乐志强, 2001, 无机精细化学品手册, P1251 [publication_29] => ACTA CHIM SINICA [end_page] => 1147 [abstract_en] => AlN nanoparticles were prepared by the water induced solid state reaction method, with AlCl3 and Li3N as the starting materials. The results of X-ray diffraction (XRD) analysis, Fourier transformation infrared (FT-IR) absorption spectra measurement, the transmission electron microscope (TEM) and X-ray photoelectron spectroscopy (XPS) observation proved that, the sample we prepared with this method was hexagonal AlN. Besides, the particles were very small. The water induced solid state reaction method includes many merits, such as, the reaction complete in a very short time period, and the experimental process is very simple. It is possible to prepare AlN nanoparticles on a large scale with very low cost by this method. [author_in] => [Li, K; Liu, ZG; Yu, MY; Dong, SY; Wang, QL; Hao, XP; Cui, DL]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China.@@@[Li, K; Liu, ZG; Yu, MY; Dong, SY; Wang, QL; Hao, XP; Cui, DL] Shandong Univ, Sch Chem & Chem Engn, Jinan 250100, Peoples R China. [publication_type] => J [begin_page] => 1144 [article_dt] => Article [author_en] => Li, K; Liu, ZG; Yu, MY; Dong, SY; Wang, QL; Hao, XP; Cui, DL [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => aluminium nitride; nanoparticle; water induced solid state reaction [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => CHEMICAL VAPOR-DEPOSITION; FILMS; PRESSURE; ALUMINUM [publication_iso] => Acta Chim. Sin. [format_title_en] => 456563ee9fb33ca49247e6fb081b479d-1820681771 [publisher_city] => BEIJING [pub_date] => JUN 28 [hx_id] => 2377,2371 [reference_No] => 14 [email] => cuidl@sdu.edu.cn [cite_awos] => 9 [wos_No] => WOS:000222218900010 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 1 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Preparation of AIN nanoparticles by a water induced solid state reaction [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => chinese [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => actachimicasinica [jl_country] => 中国,中国 [jl_keyword_en] => waterinducedsolidstatereaction,nanoparticle,aluminiumnitride [jl_keyword_cn] => ,氮化铝,纳米粉,水引发剂,固相反应合成 [jl_clc] => o61431tb383 [jl_publisher] => sciencechinapress [company_id] => 24,151,43,169 [sys_subject_sort] => 0,0,0,0 [college_parent_id] => 24,151,43,169 [company_test] => Array,Array,Array,Array [author_id] => 21754,21755,21086,20439 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 崔得良 [irtag] => 7 [t_index] => 0 [person_id] => 20439 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 郝霄鹏 [irtag] => 7 [t_index] => 0 [person_id] => 21086 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 李凯 [irtag] => 7 [t_index] => 0 [person_id] => 21754 ) [3] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 李凯 [irtag] => 7 [t_index] => 0 [person_id] => 21755 ) ) [sys_author_id_arr] => 20439崔得良,21086郝霄鹏 [cscd_No] => CSCD:1657765 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => aluminiumnitride,氮化铝,waterinducedsolidstatereaction,水引发剂,纳米粉,nanoparticle,固相反应合成 [sys_author_id] => 20439,21086,24118 [format_cscd_No] => c51455ca6aa794455c4862c70acf5f61-1476298859 [format_title_en_publication_en_pub_year] => 2c8e42cf774ecc28a68c8b99bf6ed9be102813045 [format_wos_No] => 856332758794194bba140c336de084de-332225002 [format_title_en_issn_pub_year] => af2b62f2f5278a0ca66866198c7c42da864312233 [id] => HwkxvmUBFjIhTVEbTvGU [tags] => 0 ) [18] => Array ( [issn] => 0567-7351 [reference] => Albota MA, 1998, APPL OPTICS, V37, P7352, DOI 10.1364/AO.37.007352@@@[曹笃霞 Cao Duxia], 2004, [化学学报, Acta Chemical Sinica], V62, P225@@@Dean J A, 1999, Lange\\\'s Handbook of Chemistry15th ed@@@DENK W, 1990, SCIENCE, V248, P73, DOI 10.1126/science.2321027@@@Frisch M J, 2003, J. A. Gaussian 03, Revision A. 1@@@Gaussian Inc, 2003, Gaussview 3.0, Copyright Semichem@@@Kannan R, 2001, CHEM MATER, V13, P1896, DOI 10.1021/cm000747o@@@Lakowicz J. R., 1983, PRINCIPLES FLUORESCE, P190@@@LEE CT, 1988, PHYS REV B, V37, P785, DOI 10.1103/PhysRevB.37.785@@@Lei H, 2002, Phy. Lett, V352, P240@@@Liu ZQ, 2003, CHEM-EUR J, V9, P5074, DOI 10.1002/chem.200304833@@@OUDAR JL, 1977, J CHEM PHYS, V66, P2664, DOI 10.1063/1.434213@@@PARTHENOPOULOS DA, 1989, SCIENCE, V245, P843, DOI@@@10.1126/science.245.4920.843@@@Ren Y, 2000, J MATER CHEM, V10, P2025, DOI 10.1039/b001058h@@@@@@REYNOLDS GA, 1975, OPT COMMUN, V13, P222, DOI@@@10.1016/0030-4018(75)90085-1@@@Xu C, 1996, J OPT SOC AM B, V13, P481, DOI 10.1364/JOSAB.13.000481@@@Yuan Z, 2000, J SOLID STATE CHEM, V154, P5, DOI 10.1006/jssc.2000.8803 [batch2] => 1,2,6 [format_cscd_No] => 24438ffc11c38e194b8529ff1de52cb8379099875 [begin_page] => 2103 [tag] => 0 [research_area] => Chemistry [publication_info] => 0567-7351(2004)62:20<2103:DPWDZS>2.0.TX;2-5 [abstract_en] => Two novel fluorene derivatives with dimesitylboryl as electron acceptor and diphenylamino or carbazolyl as electron donor have been synthesized, which are named 2-(N, N-diphenylamino)-7-dimesitylboryl-9,9-diethyl-fluorene (1) and 2-carbazolyl-7-dimesitylboryl-9,9-diethylfluorene (2). Upon excitation by femtosecond laser with a pulse-width of 200 fs, both compounds exhibit strong blue two-photon excited fluorescence in THF with lambda(max) = 484 nm for 1 and lambda(max) = 440 nm for 2. Their two-photon absorption cross- sections obtained by two-photon fluorescence method are 425 GM (1, excited at 800 nm) and 116 GM (2, excited at 730 nm). [abstract_cn] => 以二米基硼 B(Mes) 2 为电子受体 ,以芴基为共轭桥 ,分别以二苯胺和咔唑为电子给体 ,合成了两个新的D π A型化合物 :2 (N ,N 二苯胺基 ) 7 二米基硼基 9,9 二乙基芴 [2 (N ,N diphenylamino) 7 dimesitylboryl 9,9 diethylfluorene ,1]和 2 N 咔唑基 7 二米基硼基 9,9 二乙基芴 [2 carbazolyl 7 dimesitylboryl 9,9 diethylfluorene ,2 ] .在脉宽为 2 0 0fs的飞秒激光激发下 ,它们在THF中发出强的蓝色上转换荧光 ( 1:... [keyword_cn] => 二米基硼;芴衍生物;双光子吸收;上转换荧光 [fund_No] => 国家自然科学基金; 高等学校骨干教师计划资助项目 [format_title_en_publication_en_pub_year] => 8eed930233d5adbbb4a2838a29149049-1335882061 [publication_type] => J [author_jg] => [刘志强] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[曹笃霞] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[方奇] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[刘国群] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[许贵宝] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国 [cite_cscd] => 2 [cite_awos] => 7 [from_id] => 76,75,73,80,78 [issue] => 20 [email] => fangqi@icm.sdu.edu.cn [email_c] => fangqi@icm.sdu.edu.cn [sys_level_num] => 1_1 [format_title_cn_publication_cn_pub_year] => b4e95102d66761068b79e2950d4caa4d-459058622 [sys_jg_type] => 10,3,5 [format_issn_issue_page_pub_year] => 78b20d450aefcd6ff11d68cfc0935042537244656 [title_en] => Synthesis and up-converted fluorescence of D-pi-A compounds with N and B as the centers of electron donating and accepting groups [volume] => 62 [author_fn] => Liu, ZQ; Cao, DX; Fang, Q; Liu, GQ; Xu, GB [pub_year] => 2004 [check_180] => 0 [keyword_en] => dimesitylboryl; fluorene derivative; two-photon absorption; up-converted; fluorescence [end_page] => 2108 [article_id] => 329312,554757,661459,238399,490169 [pages] => 6 [hints] => 10 [author_cn] => 刘志强,曹笃霞,方奇,刘国群,许贵宝 [researcherID] => Liu, Zhiqiang/D-9589-2017; Xu, Guibao/F-3461-2010 [language] => English [source_type] => 351 [reference_No] => 17 [cscd_No] => CSCD:1811001 [batch] => 3250,3243,3249,3252,3241 [publication_en] => ACTA CHIMICA SINICA [hx_id] => 2377,2378,2371 [author_in] => [Liu, Z.-Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China, School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Cao, D.-X] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Fang, Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China, School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Liu, G.-Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Xu, G.-B] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China [format_title_en_issn_pub_year] => 93a4a27234028e74ade2dc270bc653a9-1709492267 [check_3Y] => 3 [publication_cn] => 化学学报 [title_cn] => 氮硼为电子授受中心的D--π-A化合物的合成与上转换荧光 [orcID] => Liu, Zhiqiang/0000-0001-7863-1759; Liu, Guoqun/0000-0002-3342-5780 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 5cc88598f886c7b70d350eef16fc3f02-1693964479 [page] => 2103-2108 [hb_type] => 2 [article_dt] => Article [hb_batch] => issn_issue_page_pub_year_1_7 [cite_wos] => 7 [delivery_No] => 867JZ [format_title] => 570dbb87d7532630f1b96f5bc3c504f0551717426 [cauthor_ad] => [Liu, ZQ]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [publication_29] => ACTA CHIM SINICA [author_en] => Liu, ZQ; Cao, DX; Fang, Q; Liu, GQ; Xu, GB [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => EXCITATION CROSS-SECTIONS [publication_iso] => Acta Chim. Sin. [format_title_en] => b1b5232a4f8d23ee00da9a56b76238511538125065 [publisher_city] => BEIJING [pub_date] => OCT 28 [wos_No] => WOS:000224840200025 [sys_priority_field] => 76 [wos_sub] => Chemistry, Multidisciplinary [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => english [jl_publication_cn] => 化学学报 [jl_article_dt] => 期刊论文 [jl_publication_en] => actachimicasinica [jl_country] => 中国 [jl_keyword_en] => upconverted,dimesitylboryl,fluorenederivative,twophotonabsorption,fluorescence [jl_keyword_cn] => 上转换荧光,芴衍生物,二米基硼,双光子吸收 [jl_publisher] => sciencechinapress [cite_wanfang] => 6 [clc] => O614 [CSSN] => 31-1320/O6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-26944454655&partnerID=40&md5=d7fe0fc4881cf2b3c00abcc78eeac048 [jl_clc] => o614 [company_id] => 24,151,43,169 [sys_subject_sort] => 0,0,0,0 [college_parent_id] => 24,151,43,169 [company_test] => Array,Array,Array,Array [author_id] => 20672,22582 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 方奇 [irtag] => 7 [t_index] => 0 [person_id] => 20672 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 刘志强 [irtag] => 7 [t_index] => 0 [person_id] => 22582 ) ) [sys_author_id_arr] => 20672方奇,22582刘志强 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => upconverted,fluorenederivative,双光子吸收,二米基硼,fluorescence,芴衍生物,dimesitylboryl,twophotonabsorption,上转换荧光 [format_scopus_No] => 991d648ee654723f4afcc95a27375057-1054489672 [format_wos_No] => 1a8f8a621d44290dfb54984d34f948981049447235 [standard_in] => State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China; School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China [datebase] => Scopus [cite_scopus] => 7 [scopus_No] => 2-s2.0-26944454655 [jl_author_test] => uirtypical3,uirtstag0,unameuu5218u6218u5f3a,unameuu5218u5fd7u5f3a,unameuu65b9u5947,upersonid20672,uuindex0,uuindex1,upersonid22560,usureu0,utindex1,utindex0,uirtag7,uirtypical1,uirinspecttag0,uirauthortype0,uirauthortype3,uirtag0,upersonid22577,upersonid22582,unameuu5218u632fu524d [sys_author_jg_last_arr] => 中国,中国,中国,中国,中国 [jl_company_test] => unameuu6676u4f53u6750u6599u7814u7a76u6240,uparentidu43,uircu0,uorgidu24,uorgidu43,ulevelu1,unameuu5316u5b66u4e0eu5316u5de5u5b66u9662,uparentidu24 [sys_author_in_last_arr] => china [sys_author_id] => 20672,22582 [id] => HwZ1vWUBFjIhTVEbYoOt [tags] => 0 ) [19] => Array ( [batch2] => 1,2 [uri] => http://kns.cnki.net/kns/detail/detail.aspx?FileName=WJHX201308002&DbName=CJFQ2013 [tag] => 0 [abstract_cn] => 光动力治疗因具有低毒、副作用小、抗癌广谱、高选择性等优势,正吸引着人们越来越多的关注。提高光敏剂的选择性和光毒性已经成为研究的热点。本文简单介绍了光敏剂的发展历程,并对酞菁类第三代光动力治疗光敏剂的最新研究进展进行了论述。 [keyword_cn] => 光动力治疗;;光敏剂;;酞菁;;靶向 [fund_No] => 国家自然科学基金; 山东大学自主创新基金 [article_id] => 366672,231793,668884,546084 [clc] => TB383.1 [author_jg] => [丁兰兰] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[栾立强] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[施佳伟] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.@@@[刘伟] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => f78996c4b5bd18682b73c541c32a1bdb1641648576 [hints] => 10 [issue] => 8 [author_first] => 丁兰兰; [sys_level_num] => 2_3 [sys_jg_type] => 0,5 [format_issn_issue_page_pub_year] => e3d31020db9f18ad32a6d3d5183fb4481635189475 [source_type] => 351 [pub_year] => 2013 [pub_date] => AUG 10 [pages] => 8 [from_id] => 75,73,80,78 [author_cn] => 丁兰兰;栾立强;施佳伟;刘伟; [issn] => 1001-4861 [batch] => 3250,3249,3241,3252 [publication_cn] => 无机化学学报 [title_cn] => 酞菁在光动力治疗中的应用 [CSSN] => 32-1185/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => e348c87fc27dbe2fa48c70dc5b1d57d1-1018080705 [page] => 1591-1598 [hb_type] => 2 [article_dt] => Review [hb_batch] => title_cn_publication_cn_pub_year_2_3 [cite_wos] => 7 [publication_en] => CHINESE JOURNAL OF INORGANIC CHEMISTRY [check_3Y] => 93 [language] => Chinese [delivery_No] => 208NT [format_title] => 4bdef7a918d4012ed7afdbeafb7fb2c9755081043 [cauthor_ad] => [Liu, W]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Ding Lan-Lan; Luan Li-Qiang; Shi Jia-Wei; Liu Wei [reference] => Agostinis P, 2011, CA-CANCER J CLIN, V61, P250, DOI 10.3322/caac.20114@@@Ali H, 2011, J ORG CHEM, V76, P1887, DOI 10.1021/jo102083g@@@Araki J, 2007, SOFT MATTER, V3, P1456, DOI 10.1039/b705688e@@@Baracca A, 2003, BBA-BIOENERGETICS, V1606, P137, DOI@@@10.1016/S0005-2728(03)00110-5@@@Battaglia A, 2006, TETRAHEDRON LETT, V47, P2667, DOI@@@10.1016/j.tetlet.2006.02.108@@@Baugh SDP, 2001, J AM CHEM SOC, V123, P12488, DOI 10.1021/ja011709o@@@Bechet D, 2008, TRENDS BIOTECHNOL, V26, P612, DOI@@@10.1016/j.tibtech.2008.07.007@@@Brancaleon L, 2002, LASER MED SCI, V17, P173, DOI 10.1007/s101030200027@@@Chen Y, 2010, CHEM SOC REV, V39, P495, DOI 10.1039/b816354p@@@Cosentino C, 2011, Feedback Control in Systems Biology@@@Couleaud P, 2010, NANOSCALE, V2, P1083, DOI 10.1039/c0nr00096e@@@CULLIS PM, 1995, J CHEM SOC PERK T 2, P1503, DOI 10.1039/p29950001503@@@Dallavalle S, 2006, J MED CHEM, V49, P5177, DOI 10.1021/jm060285b@@@Delcros JG, 2002, J MED CHEM, V45, P5098, DOI 10.1021/jm020843w@@@Derycke ASL, 2004, ADV DRUG DELIVER REV, V56, P17, DOI@@@10.1016/j.addr.2003.07.014@@@Dolmans DEJGJ, 2003, NAT REV CANCER, V3, P380, DOI 10.1038/nrc1071@@@Dougherty TJ, 1998, J NATL CANCER I, V90, P889, DOI@@@10.1093/jnci/90.12.889@@@Eiseman JL, 1998, CANCER RES, V58, P4864@@@Ferlini C, 2007, NAT PROTOC, V2, P3111, DOI 10.1038/nprot.2007.397@@@FOOTE CS, 1968, SCIENCE, V162, P963, DOI 10.1126/science.162.3857.963@@@Hapiot F, 2006, CHEM REV, V106, P767, DOI 10.1021/cr050576c@@@HOLLEY JL, 1992, CANCER RES, V52, P4190@@@Jiang XJ, 2011, J MED CHEM, V54, P320, DOI 10.1021/jm101253v@@@Jiang XJ, 2010, CHEM-EUR J, V16, P4777, DOI 10.1002/chem.200903580@@@JOHNSON LV, 1980, P NATL ACAD SCI-BIOL, V77, P990, DOI@@@10.1073/pnas.77.2.990@@@Juzeniene A, 2006, J ENVIRON PATHOL TOX, V25, P7, DOI@@@10.1615/JEnvironPatholToxicolOncol.v25.i1-2.20@@@@@@Juzeniene A, 2004, LASER MED SCI, V19, P139, DOI@@@10.1007/s10103-004-0314-x@@@Ke MR, 2012, CHEM-EUR J, V18, P4225, DOI 10.1002/chem.201103516@@@Kralova J, 2006, PHOTOCHEM PHOTOBIOL, V82, P432, DOI@@@10.1562/2005-05-06-RA-516@@@Lau JTF, 2012, J MED CHEM, V55, P5446, DOI 10.1021/jm300398q@@@Lau JTF, 2011, CHEM COMMUN, V47, P9657, DOI 10.1039/c1cc13783b@@@Lau JTF, 2011, CHEM-EUR J, V17, P7569, DOI 10.1002/chem.201100621@@@Lee DR, 2009, NEUROCHEM RES, V34, P1857, DOI 10.1007/s11064-009-0001-1@@@Leng XB, 2007, ORG LETT, V9, P2497, DOI 10.1021/ol070888x@@@Liu JY, 2009, ORG BIOMOL CHEM, V7, P1583, DOI 10.1039/b822128f@@@Liu W, 2005, J MED CHEM, V48, P1033, DOI 10.1021/jm049375b@@@Luan LQ, 2013, BIOORG MED CHEM LETT, V23, P3775, DOI@@@10.1016/j.bmcl.2013.04.093@@@Luan LQ, 2012, CHEM LETT, V41, P1012, DOI 10.1246/cl.2012.1012@@@Mao JF, 2009, CHEM COMMUN, P908, DOI 10.1039/b817968a@@@Master AM, 2012, MOL PHARMACEUT, V9, P2331, DOI 10.1021/mp300256e@@@Master AM, 2012, NANOMED-NANOTECHNOL, V8, P655, DOI@@@10.1016/j.nano.2011.09.012@@@Miller GG, 1997, DRUG DEVELOP RES, V42, P182, DOI@@@10.1002/(SICI)1098-2299(199711/12)42:3/4<182::AID-DDR10>3.0.CO;2-B@@@Mitsunaga M, 2011, NAT MED, V17, P1685, DOI 10.1038/nm.2554@@@MOAN J, 1991, PHOTOCHEM PHOTOBIOL, V53, P549, DOI@@@10.1111/j.1751-1097.1991.tb03669.x@@@Nishiyama N, 2009, ADV DRUG DELIVER REV, V61, P327, DOI@@@10.1016/j.addr.2009.01.004@@@Ongarora BG, 2012, J MED CHEM, V55, P3725, DOI 10.1021/jm201544y@@@PANDEY RK, 1995, PHOTOCHEM PHOTOBIOL, V62, P764, DOI@@@10.1111/j.1751-1097.1995.tb08727.x@@@Papadopoulou MV, 2004, BIOORG MED CHEM LETT, V14, P1519, DOI@@@10.1016/j.bmcl.2003.12.100@@@PEOPLES GE, 1995, P NATL ACAD SCI USA, V92, P432, DOI@@@10.1073/pnas.92.2.432@@@Ruebner A, 1999, P NATL ACAD SCI USA, V96, P14692, DOI@@@10.1073/pnas.96.26.14692@@@Samor C, 2008, BIOCONJUGATE CHEM, V19, P2270, DOI 10.1021/bc800033r@@@SCHWABER J, 1973, NATURE, V244, P444, DOI 10.1038/244444a0@@@Sehgal I, 2008, J MED CHEM, V51, P6014, DOI 10.1021/jm800444c@@@Sharman WM, 2004, ADV DRUG DELIVER REV, V56, P53, DOI@@@10.1016/j.addr.2003.08.015@@@Sharman WM, 1999, DRUG DISCOV TODAY, V4, P507, DOI@@@10.1016/S1359-6446(99)01412-9@@@Sibrian-Vazquez M, 2006, J MED CHEM, V49, P1364, DOI 10.1021/jm050893b@@@Sibrian-Vazquez M, 2008, J MED CHEM, V51, P2915, DOI 10.1021/jm701050j@@@Sibrian-Vazquez M, 2010, ORG BIOMOL CHEM, V8, P1160, DOI@@@10.1039/b917280g@@@Siegel G, 2006, Basic Neurochemistry: Molecular, Cellular, and Medical@@@Aspects: Vol.1@@@Solban N, 2006, LASER SURG MED, V38, P522, DOI 10.1002/lsm.20345@@@Uslan C, 2012, J PHOTOCH PHOTOBIO A, V235, P56, DOI@@@10.1016/j.jphotochem.2012.03.010@@@Verma S, 2007, PHOTOCHEM PHOTOBIOL, V83, P996, DOI@@@10.1111/j.1751-1097.2007.00166.x@@@Wang CJ, 2003, J MED CHEM, V46, P5129, DOI 10.1021/jm030223a@@@YUAN ZM, 1994, CANCER RES, V54, P742@@@Zhao ZX, 2012, INORG CHEM, V51, P812, DOI 10.1021/ic201178e@@@Zorlu Y, 2010, TETRAHEDRON LETT, V51, P6615, DOI@@@10.1016/j.tetlet.2010.10.044@@@黄剑东, 2006, Wuji Huaxue Xuebao, V22, P435@@@吴丽荣, 2010, Daxue Huaxue, V25, P1@@@朱菁, 2000, Zhongguo Jiguang, V27, P95@@@刘岩岩, 2008, Huaxue Jinzhan, V20, P1345@@@汪凌云, 2012, Youji Huaxue, V32, P2248@@@高源, 2011, Fenxi Huaxue, V39, P1926@@@金晓敏, 2002, Zhongguo Yaowu Huaxue Zazhi, V12, P52@@@牛丽红, 2009, Huaxue Tongbao, V72, P251@@@黄金陵, 2005, CN Patent, CN1593424@@@刘丽珍, 2005, Fenzi Kexue Xuebao, V21, P56@@@黄焱, 2010, Yingyong Jiguang, V30, P518 [publication_29] => CHINESE J INORG CHEM [end_page] => 1598 [abstract_en] => Photodynamic therapy (PDT) is a clinically approved procedure. Due to its minimal normal tissue toxicity, negligible side effects and high selectivity, it has emerged as an efficient treatment method for many kinds of cancers. Recently, significant effort has been devoted to enhance its selectivity and phototoxicity toward malignant tissues. This review summarizes the recent research of photosensitizers, especially focuses on the progress of the third generation photosensitizers based on phthalocyanines. [author_in] => [Ding Lan-Lan; Luan Li-Qiang; Shi Jia-Wei; Liu Wei] Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [publication_type] => J [begin_page] => 1591 [author_en] => Ding, LL; Luan, LQ; Shi, JW; Liu, W [volume] => 29 [get_data] => 2018-08-29 [publisher] => CHINESE CHEMICAL SOC [keyword_en] => photodynamic therapy; photosensitizer; phthalocyanine; targeting [format_publication_cn] => 6f60fdb90c8ed276c1ac1b77ab33e988-233140351 [keyword_plu] => WATER-SOLUBLE PHTHALOCYANINES; IN-VITRO; SILICON(IV) PHTHALOCYANINES; BETA-CYCLODEXTRINS; PROSTATE-CANCER; LIGHT-SOURCES; PEPTIDE; DELIVERY; CELLS; MITOCHONDRIA [doi] => 10.3969/j.issn.1001-4861.2013.00.311 [publication_iso] => Chin. J. Inorg. Chem. [format_title_en] => 02c865b151a87e3090ab7961433e5c50144138574 [publisher_city] => BEIJING [hx_id] => 2377,2371 [reference_No] => 77 [email] => weiliu@sdu.edu.cn [cite_awos] => 9 [wos_No] => WOS:000323687100003 [wos_sub] => Chemistry, Inorganic & Nuclear [research_area] => Chemistry [check_180] => 2 [publisher_ad] => C/O DEPT INT AFFAIRS, SECRETARY OF CHEM SOC, PO BOX 2709, BEIJING; 100080, PEOPLES R CHINA [title_en] => Phthalocyanine Based Photosensitizers for Photodynamic Therapy [format_publication_en] => 8b6f8b3d82617e6d3dbc6c68ccb4e7001845903523 [jl_language] => chinese [jl_publication_cn] => 无机化学学报 [jl_article_dt] => review [jl_publication_en] => chinesejournalofinorganicchemistry [jl_country] => 中国,中国 [jl_keyword_en] => photodynamictherapy,targeting,photosensitizer,phthalocyanine [jl_keyword_cn] => ,靶向,光敏剂,酞菁,光动力治疗 [jl_clc] => tb3831 [jl_publisher] => chinesechemicalsoc [company_id] => 24,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => 22445,22444 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 4 [name] => 刘伟 [irtag] => 7 [t_index] => 0 [person_id] => 22445 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 4 [name] => 刘伟 [irtag] => 7 [t_index] => 0 [person_id] => 22444 ) ) [sys_author_id_arr] => [cscd_No] => CSCD:4913869 [jl_publication_cn_publication_en] => chinesejournalofinorganicchemistry,无机化学学报 [jl_keyword_cn_keyword_en] => phthalocyanine,targeting,光动力治疗,photosensitizer,靶向,photodynamictherapy,酞菁,光敏剂 [sys_author_id] => 22444 [format_cscd_No] => a95b43ab81d4fe3a521d33299c6727081936183398 [format_title_en_publication_en_pub_year] => 3e48edb24d19d1e43bf6eb58425747f81695461595 [format_wos_No] => 86a91f0c9a4e82acc113880e774479ef1090476319 [format_title_en_issn_pub_year] => ed047667e3254c32009a56631d398eab-1904161531 [id] => OA5KvmUBFjIhTVEbGvCn [tags] => 0 ) ) 1-->
1. 一种新的有机非线性光学晶体——L-精氨酸磷酸盐 SCIE

作者:许东;蒋民华;谭忠恪;

作者机构:[许东;蒋民华;谭忠恪]山东大学晶体材料研究所,山东大学晶体材料研究所,山东大学晶体材料研究所 济南,济南,济南

来源:化学学报,ACTA CHIMICA SINICA,1983,Vol.41,Issue.6,570-573

WOS被引数:162

资源类型:期刊论文

WOS:A1983RF76200015

2. 钛酸铋系化合物的光催化性能研究 CSCD SCOPUS SCIE

作者:许效红;姚伟峰;张寅;周爱秋;侯云;王民

作者机构:[许效红] 山东大学,化学与化工学院, 济南, 山东 250100, 中国.;[周爱秋] 山东大学,化学与化工学院, 济南, 山东 250100, 中国.;[姚伟峰] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[张寅] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[侯云] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[王民] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.1,5-10+91

WOS被引数:20

资源类型:期刊论文

WOS:000226363200002

3. Ti~(3+)自掺杂的纳米TiO_2的制备及其可见光催化性能 CSCD SCOPUS SCIE

作者:王潇彤;李延敏;刘新;高善民;黄柏标;戴瑛;

作者机构:[王潇彤] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[刘新] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[高善民] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[李延敏] 鲁东大学生命科学学院, 烟台, 山东 264025, 中国.;[黄柏标] 山东大学晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[戴瑛] 山东大学晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:催化学报,CHINESE JOURNAL OF CATALYSIS,2015,Vol.36,Issue.3,389-399

WOS被引数:18

资源类型:期刊论文

WOS:000351029200019

4. 掺Er^3+的NaY(WO4)2晶体的光谱特性 SCOPUS SCIE

作者:宋峰[1];谭浩[1];商美茹[1];张光寅[1];程振祥[2];陈焕矗[2]

作者机构:[宋峰;谭浩;商美茹;张光寅]南开大学光子学中心,天津,300071,中国.;[程振祥;陈焕矗]山东大学晶体研究所,济南,250100,中国

来源:物理学报,ACTA PHYSICA SINICA,2002,Vol.51,Issue.10,2375-2379

WOS被引数:16

资源类型:期刊论文

WOS:000178899300039

5. 石墨型C_3N_4的固态合成及嵌锂性能研究 CSCD SCOPUS SCIE

作者:杨晓晖;王红军;陆希峰;崔得良;张树永;

作者机构:[杨晓晖] 山东大学化学与化工学院, 教育部胶体与界面化学重点实验室, 济南, 山东 250100, 中国.;[王红军] 山东大学化学与化工学院, 教育部胶体与界面化学重点实验室, 济南, 山东 250100, 中国.;[张树永] 山东大学化学与化工学院, 教育部胶体与界面化学重点实验室, 济南, 山东 250100, 中国.;[陆希峰] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[崔得良] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2009,Vol.67,Issue.11,1166-1170

WOS被引数:11

资源类型:期刊论文

WOS:000267606400002

6. 自旋注入有机物的扩散理论 SCIE

作者:任俊峰[1];付吉永[1];刘德胜[1];解士杰[1]

作者机构:[任俊峰;付吉永;刘德胜;解士杰]山东大学物理与微电子学院,晶体材料国家重点实验室,济南250100,中国

来源:物理学报,ACTA PHYSICA SINICA,2004,Vol.53,Issue.11,3814-3817

WOS被引数:10

资源类型:期刊论文

WOS:000225014800035

7. 强双光子吸收引发的聚合反应 SCIE

作者:于晓强[1];孙渝明[2]

作者机构:[于晓强]山东大学晶体材料国家重点实验室,济南250100,中国.;[孙渝明]山?,济南,中国

来源:高等学校化学学报,CHEMICAL JOURNAL OF CHINESE UNIVERSITIES-CHINESE,2000,Vol.21,Issue.12,1953-1955

WOS被引数:10

资源类型:期刊论文

WOS:000167004800044

8. V形咔唑衍生物的合成及荧光性质 CSCD SCOPUS SCIE

作者:王伟,方奇,刘志强,曹笃霞,邓敏智

作者机构:[王伟] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[方奇] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[刘志强] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[曹笃霞] 济南大学材料科学与工程学院, 济南, 山东 250022, 中国.;[邓敏智] 中国科学院上海有机化学研究所, 中科院有机氟化学重点实验室, 上海 200032, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.14,1323-1328+1242

WOS被引数:10

资源类型:期刊论文

WOS:000230857100014

9. 金属硫氰酸根配合物FeHg(SCN)_4,MnHg(SCN)_4的合成、晶体结构与非线性光学性质的研究 SCOPUS SCIE

作者:延云兴,方奇,于文涛,袁多荣,田玉鹏,蒋民华,I.D.Williams,蔡志岗

作者机构:[延云兴,方奇,于文涛,袁多荣,田玉鹏,蒋民华,I.D.Williams,蔡志岗]山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,山东大学晶体材料研究所晶体材料国家重点实验室,香港科技大学化学系,中山大学超快光谱国家重点实验室 济南250100,济南250100,济南250100,济南250100,济南250100,济南250100,广州510275

来源:化学学报,ACTA CHIMICA SINICA,1999,Vol.57,Issue.11,1257-1261

WOS被引数:10

资源类型:期刊论文

WOS:000083783900013

10. 基态非简并聚合物中的极化子和双极化子动力学 SCIE

作者:王鹿霞;张大成;刘德胜;韩圣浩;解士杰

作者机构:[王鹿霞;张大成;刘德胜;韩圣浩;解士杰]山东大学物理与微电子学院,晶体材料国家重点实验室,济南,250100,中国

来源:物理学报,ACTA PHYSICA SINICA,2003,Vol.52,Issue.10,2547-2552

WOS被引数:9

资源类型:期刊论文

WOS:000185683100035

11. Ag@AgI等离子体负载TiO_2酸蚀纳米带的制备及可见光光催化性能的研究 SCIE

作者:王恩华;刘素文;李堂刚;宋灵君;

作者机构:[王恩华;刘素文;李堂刚;宋灵君]山东轻工业学院山东省玻璃与功能陶瓷加工与测试技术重点实验室;[王恩华;刘素文;李堂刚;宋灵君]山东大学晶体材料国家重点实验室

来源:无机化学学报,CHINESE JOURNAL OF INORGANIC CHEMISTRY,2011,Vol.27,Issue.3,537-541

WOS被引数:9

资源类型:期刊论文

WOS:000288976900023

12. 沉淀法制备不同形貌和结构的纳米BiVO4 CSCD SCOPUS SCIE

作者:高善民[1,2];乔青安[1];赵培培[1];陶芙蓉[1];张江[1];戴瑛[2];黄柏标[2]

作者机构:[高善民] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[乔青安] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[赵培培] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[陶芙蓉] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[张江] 鲁东大学化学与材料科学学院, 烟台, 山东 264025, 中国.;[戴瑛] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[黄柏标] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:无机化学学报,CHINESE JOURNAL OF INORGANIC CHEMISTRY,2007,Vol.23,Issue.7,1153-1158

WOS被引数:9

资源类型:期刊论文

WOS:000248569400005

13. 姜黄素类铂(Ⅱ)配合物的合成及其抗肿瘤活性 CSCD SCOPUS SCIE

作者:周双生;薛璇;姜波;鲁传华;田玉鹏;蒋明华;

作者机构:[周双生] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.;[薛璇] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.;[姜波] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.;[鲁传华] 安徽中医学院药学院, 合肥, 安徽 230031, 中国.;[田玉鹏] 安徽大学化学化工学院, 晶体材料国家重点实验室, 合肥, 安徽 230039, 中国.;[蒋明华] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2011,Vol.69,Issue.19,2335-2340

WOS被引数:8

资源类型:期刊论文

WOS:000296933700021

14. 芴衍生物的合成、结构与蓝色(λ_(max)=418nm)双光子荧光 CSCD SCOPUS SCIE

作者:曹笃霞,方奇,薛刚,许贵宝,于文涛,刘志强

作者机构:[曹笃霞,方奇,薛刚,许贵宝,于文涛,刘志强]山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室,山东大学晶体材料国家重点实验室 济南250100,济南250100,济南250100,济南250100,济南250100,济南250100

来源:化学学报,ACTA CHIMICA SINICA,2004,Vol.62,Issue.3,225-229

WOS被引数:8

资源类型:期刊论文

WOS:000188877700001

15. 多支结构的均三嗪衍生物的合成及双光子吸收性质 CSCD SCOPUS SCIE

作者:崔月芝;方奇;薛刚;许贵宝;于文涛;尹磊

作者机构:[崔月芝] 山东轻工业学院化工系, 济南, 山东 250100, 中国.;[方奇] 山东轻工业学院化工系, 济南, 山东 250100, 中国.;[薛刚] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[许贵宝] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[于文涛] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[尹磊] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.15,50-57

WOS被引数:8

资源类型:期刊论文

WOS:000231163200008

16. 钨酸钇钠晶体中Tm^3+的光谱特性 SCOPUS SCIE

作者:宋峰[1];苏静[1];谭浩[1];商美茹[1];吴朝晖[1];田建国[1];张光寅[1];程振祥[2];陈焕矗[2]

作者机构:[宋峰;苏静;谭浩;商美茹;吴朝晖;田建国;张光寅]南开大学光子学中心,天津300071,中国.;[程振祥;陈焕矗]山东大学晶体研究所,济南250100,中国

来源:物理学报,ACTA PHYSICA SINICA,2004,Vol.53,Issue.10,3591-3595

WOS被引数:7

资源类型:期刊论文

WOS:000224421300067

17. 钙钛矿结构La_(0.68)Pb_(0.32)FeO_3纳米材料的制备及气敏特性研究 EI CSCD SCOPUS SCIE

作者:张玲,胡季帆,秦宏伟,薛天锋,安康,韩涛,宋鹏,周莹

作者机构:[张玲] 山东大学, 济南, 山东 250100, 中国.;[胡季帆] 山东大学, 济南, 山东 250100, 中国.;[秦宏伟] 山东大学, 济南, 山东 250100, 中国.;[薛天锋] 山东大学, 济南, 山东 250100, 中国.;[安康] 山东大学, 济南, 山东 250100, 中国.;[韩涛] 山东大学, 济南, 山东 250100, 中国.;[宋鹏] 山东大学, 济南, 山东 250100, 中国.;[周莹] 山东大学, 济南, 山东 250100, 中国

来源:稀有金属材料与工程,RARE METAL MATERIALS AND ENGINEERING,2004,Vol.33,Issue.3,293-296

JCR分区(WOS):Q3

最新影响因子:0.236

当年影响因子:0.437

WOS被引数:7

资源类型:期刊论文

WOS:000220526100017

18. 利用水引发固相反应方法合成氮化铝纳米粉 CSCD SCIE

作者:李凯 [1];刘振刚 [2];于美燕 [2];董守义 [1];王琪珑 [2];郝霄鹏 [1];崔得良 [1]

作者机构:[李凯] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[董守义] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[郝霄鹏] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[崔得良] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[刘振刚] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[于美燕] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[王琪珑] 山东大学化学与化工学院, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2004,Vol.62,Issue.12

WOS被引数:7

资源类型:期刊论文

WOS:000222218900010

19. 氮硼为电子授受中心的D--π-A化合物的合成与上转换荧光 CSCD SCOPUS SCIE

作者:刘志强,曹笃霞,方奇,刘国群,许贵宝

作者机构:[刘志强] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[曹笃霞] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[方奇] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[刘国群] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[许贵宝] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2004,Vol.62,Issue.20,2103-2108

WOS被引数:7

资源类型:期刊论文

WOS:000224840200025

20. 酞菁在光动力治疗中的应用 CSCD SCIE

作者:丁兰兰;栾立强;施佳伟;刘伟;

作者机构:[丁兰兰] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[栾立强] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[施佳伟] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国.;[刘伟] 山东大学, 晶体材料国家重点实验室, 济南, 山东 250100, 中国

来源:无机化学学报,CHINESE JOURNAL OF INORGANIC CHEMISTRY,2013,Vol.29,Issue.8,1591-1598

WOS被引数:7

资源类型:期刊论文

WOS:000323687100003

共 62 页, 1,232 条记录

TOP