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water cyclinder --> water lamellae --> continuous water phase, for this system. In the lamellae region, the dispersion exhibited negative thixotropic and shear thicken properties. The bizarre rheological properties exhibited by the dispersion with water/oil ratios of 1 were explained in terms of ion-dipole association between oleate and hexanol molecules on adjacent dropletes, which was investigated as a function of pH, ratios of water and added salts. [publication_type] => J [begin_page] => 729 [author_en] => WU, SY; CHEN, ZQ; WANG, SQ; LI, Y; YUAN, YL; ZHANG, CS [volume] => 51 [get_data] => 2018-08-29 [publisher] => ACTA CHIMICA SINICA [keyword_plu] => LIQUID-CRYSTALS; RATIO [publication_iso] => Acta Chim. Sin. [format_title_en_publication_en_pub_year] => c69b0a84942cb0221948f672b11a7a001570388038 [publisher_city] => SHANGHAI [cauthor_order] => 1 [reference_No] => 14 [cite_awos] => 5 [wos_No] => WOS:A1993LX88200001 [format_wos_No] => 33929a6ec1b2a969b71d49ec06ec876a-2044470079 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [cauthor_back] => WU, SY [check_180] => 0 [publisher_ad] => SHANGHAI INST ORGANIC CHEM ACADEMIA SINICA 345 LINGLING LU, SHANGHAI,; PEOPLES R CHINA [title_en] => THE BIZARRE RHEOLOGICAL PROPERTIES OF MICROEMULSION WITH ANIONIC SURFACTANT [sys_subject_sort] => 0,0 [college_parent_id] => 43,169 [company_test] => Array,Array [id] => 5A9KvmUBFjIhTVEbYAQa [tags] => 0 ) [13] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3241,3254,3243,3252 [tag] => 0 [abstract_cn] => 利用纳米材料为载体对酶等生物大分子进行固定化近年来引起人们的浓厚兴趣.以Au/Ag合金为原料,通过控制浓硝酸的腐蚀时间再辅以退火处理得到了不同孔径的纳米多孔金(NPG),利用扫描电镜(SEM)和N2气体吸附仪对孔性质进行了表征.以NPG为载体,用α-硫辛酸和N-乙基-N'-(3-二甲基氨基丙基)碳酰二亚胺/N-羟基琥珀酰亚胺(EDC/NHS)对金表面进行活化,通过化学共价偶联的方法对产自Trametes versicolor的漆酶进行了固定化.比较了孔径大小对酶固定化量及比活力的影响.发现小孔径更有利于对该漆酶的固定化.与游离酶相比,固定化酶的最适pH没有改变,但最适温度却从原来的40℃升到了60℃.固定化后,漆酶的pH和热稳定性都明显提高了.重复使用8次仍能保持初始活力的65%,且在4℃下保存1个月几乎观察不到酶活力的下降.此外,失活的固定化酶经浓硝酸处理后,NPG载体可重复利用.本结果初步显示出了NPG在生物技术领域中的应用潜力。 [keyword_cn] => 漆酶;固定化;纳米多孔金;酶学性质; [clc] => Q814 Q936 [author_jg] => [邱华军] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[徐彩霞] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[姬广磊] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[黄锡荣] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[韩书华] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[丁轶] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[曲音波] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => 8da0a008cd1264028930c48babe7fdf5826883569 [from_id] => 76,75,73,80,78,85 [issue] => 18 [sys_level_num] => 2_1 [sys_jg_type] => 11,3,5 [source_type] => 351 [pub_year] => 2008 [article_id] => 597895,322106,480541,238506,21244,660681 [pages] => 6 [hints] => 17 [author_cn] => 邱华军[1];徐彩霞[1];姬广磊[1];黄锡荣[1,2];韩书华[1];丁轶[1];曲音波[2] [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-77957935274&partnerID=40&md5=dfaf35c51143239c7699e7934df49eeb [publication_cn] => 化学学报 [title_cn] => 漆酶在纳米多孔金上的固定化及其酶学性质研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => c1ed9fe9340fb942d11d5b72073ef311995227883 [hb_type] => 2 [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 5 [fund_No] => 国家重点基础研究发展计划(No.2007CB93); 国家自然科学基金(No.30570014)资助项目 [check_3Y] => 24 [language] => Chinese [delivery_No] => 358GE [format_title] => 67a3edd61781b0f8e243dbb220b5d0261460404939 [cauthor_ad] => [Qiu, HJ]Shandong Univ, Minist Educ China, Key Lab Colloid & Interface Chem, Jinan 250100, Peoples R China. [author_fn] => Qiu Hua-Jun; Xu Cai-Xia; Ji Guang-Lei; Huang Xi-Rong; Han Shu-Hua; Ding Yi; Qu Yin-Bu [reference] => Collins PJ, 1996, APPL ENVIRON MICROB, V62, P4563@@@D\\\'ANNIBALE A, 1999, Process Biochem, V34, P697@@@Ding Y, 2004, J AM CHEM SOC, V126, P6876, DOI 10.1021/ja0320119@@@Ding Y, 2003, J AM CHEM SOC, V125, P7772, DOI 10.1021/ja035318g@@@Erlebacher J, 2001, NATURE, V410, P450, DOI 10.1038/35068529@@@Han SH, 2006, CHEMPHYSCHEM, V7, P394, DOI 10.1002/cphc.200500271@@@[黄俊 Huang Jun], 2005, [化学学报, Acta Chemical Sinica], V63, P1343@@@Kim J, 2006, CHEM ENG SCI, V61, P1017, DOI 10.1016/j.ces.2005.05.067@@@LI R, 1992, PHYS REV LETT, V68, P1168, DOI 10.1103/PhysRevLett.68.1168@@@Mandal S, 2005, CURR APPL PHYS, V5, P118, DOI 10.1016/j.cap.2004.06.006@@@MARTINEK K, 1977, BIOCHIM BIOPHYS ACTA, V485, P1, DOI@@@10.1016/0005-2744(77)90188-7@@@Moelans D, 2005, CATAL COMMUN, V6, P307, DOI@@@10.1016/j.catcom.2005.02.005@@@MOZHAEV VV, 1990, BIOTECHNOL BIOENG, V35, P653, DOI@@@10.1002/bit.260350702@@@Pickard MA, 1999, APPL ENVIRON MICROB, V65, P3805@@@Shulga OV, 2007, CHEM MATER, V19, P3902, DOI 10.1021/cm070238n@@@Sotiropoulou S, 2005, BIOSENS BIOELECTRON, V20, P1674, DOI@@@10.1016/j.bios.2004.07.019@@@Wang P, 1997, NAT BIOTECHNOL, V15, P789, DOI 10.1038/nbt0897-789@@@Wang P, 2006, CURR OPIN BIOTECH, V17, P574, DOI@@@10.1016/j.copbio.2006.10.009@@@Wei Y, 2000, MATER LETT, V44, P6, DOI 10.1016/S0167-577X(99)00287-6@@@Xing GW, 2000, TETRAHEDRON, V56, P3517, DOI@@@10.1016/S0040-4020(00)00261-1@@@XU CX, 2007, AM CHEM SOC, V129, P42 [publication_29] => ACTA CHIM SINICA [end_page] => 2080 [abstract_en] => Immobilization of biomolecules such as enzyme on nanomaterials has aroused wide interest in recent years. Nanoporous gold (NPG) with different pore sizes was prepared by controlling the etching time of Au/Ag alloy with concentrated nitric acid and annealing. Scanning electron microscopy and a nitrogen adsorption technique were used to characterize the NPG. The surface of NPG was activated with a-lipoic acid and N-ethyl-N\'-(3-dimethylaminopropyl) carbodiimide/N-hydroxysuccinimide (EDC/NHS), and laccase from Trametes versicolor was then immobilized on it through chemical coupling. The effects of pore size on the specific activity and on the amount of immobilized laccase were studied. The results showed that the NPG with a smaller pore size was a better carrier for the laccase immobilization. Compared with free enzyme, the optimum pH of immobilized laccase did not change, however, the optimum temperature rose from 40 degrees C to 60 degrees C. Both pH and thermal stabilities were improved markedly via the immobilization. After 8 after 1 month storage at 4 degrees C. For the inactivated immobilized laccase, its carrier NPG could be recycled by times usage, 65% of its initial activity could still remain. In addition, no obvious activity loss was observed simply immersing it into concentrated nitric acid. All these results demonstrate that NPG as a carrier for enzyme has great potential applications to biotechnology area. [researcherID] => qiu, huajun/B-3717-2011; DING, YI/F-6990-2013 [orcID] => DING, YI/0000-0002-1347-2811 [author_in] => [Qiu, H.-J] Key Laboratory of Colloid and Interface Chemistry of the Ministry of Education of China, Shandong University, Jinan 250100, China@@@[ Xu, C.-X] Key Laboratory of Colloid and Interface Chemistry of the Ministry of Education of China, Shandong University, Jinan 250100, China@@@[ Ji, G.-L] Key Laboratory of Colloid and Interface Chemistry of the Ministry of Education of China, Shandong University, Jinan 250100, China@@@[ Huang, X.-R] Key Laboratory of Colloid and Interface Chemistry of the Ministry of Education of China, Shandong University, Jinan 250100, China, State Key Laboratory of Microbial Technology of China, Shandong University, Jinan 250100, China@@@[ Han, S.-H] Key Laboratory of Colloid and Interface Chemistry of the Ministry of Education of China, Shandong University, Jinan 250100, China@@@[ Ding, Y] Key Laboratory of Colloid and Interface Chemistry of the Ministry of Education of China, Shandong University, Jinan 250100, China@@@[ Yin-Bo] State Key Laboratory of Microbial Technology of China, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 2075 [article_dt] => Article [author_en] => Qiu, HJ; Xu, CX; Ji, GL; Huang, XR; Han, SH; Ding, Y; Qu, YB [volume] => 66 [get_data] => 2018-08-29 [publisher] => SCIENCE PRESS [keyword_en] => laccase; immobilization; nanoporous gold; enzymatic property [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => MESOPOROUS SILICA; ENZYMES; STABILIZATION; OXIDATION; NANOPARTICLES; SUPPORT [publication_iso] => Acta Chim. Sin. [format_title_en] => 5ef97cf45a70f8b524252154e50c42f4-1319113823 [publisher_city] => BEIJING [pub_date] => SEP 28 [hx_id] => 2377,2378,2371 [reference_No] => 21 [email] => xrhuang@sdu.edu.cn [cite_awos] => 9 [wos_No] => WOS:000259904300010 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 2 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Immobilization of Laccase on Nanoporous Gold and Its Enzymatic Properties [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] => nanoporousgold,immobilization,enzymaticproperty,laccase [jl_keyword_cn] => 纳米多孔金,,酶学性质,漆酶,固定化 [jl_clc] => q814q936 [jl_publisher] => sciencepress [company_id] => [author_id] => 23152,21289,21055 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 韩书华 [irtag] => 7 [t_index] => 0 [person_id] => 21055 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 黄锡荣 [irtag] => 7 [t_index] => 0 [person_id] => 21289 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 曲音波 [irtag] => 7 [t_index] => 0 [person_id] => 23152 ) ) [sys_author_id_arr] => 21055韩书华,21289黄锡荣 [cscd_No] => CSCD:3391983 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => nanoporousgold,enzymaticproperty,漆酶,固定化,酶学性质,laccase,immobilization,纳米多孔金 [sys_author_id] => 21055,21289 [format_cscd_No] => 99984c1e0abcf6d69a06414637823faf-222896029 [format_title_en_publication_en_pub_year] => e0ecaf76dd36ef7a8be31152835876951882389129 [format_wos_No] => 1bfea3cf2446c57cd774976ed2cc7c28355311411 [format_title_en_issn_pub_year] => 09d3d36927a468c6f0c65ca2216c9936-1102895990 [format_scopus_No] => 63a0e719c3199eb970ff8042960fcb611806198036 [standard_in] => Key Laboratory of Colloid and Interface Chemistry of the Ministry of Education of China, Shandong University, Jinan 250100, China; State Key Laboratory of Microbial Technology of China, Shandong University, Jinan 250100, China [cauthor] => Huang, XR(xrhuang@sdu.edu.cn) [datebase] => Scopus [page] => 2075-2080 [cite_scopus] => 6 [format_issn_issue_page_pub_year] => d205af0c835d5aa1b79a34afd4426a80634222150 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-77957935274 [id] => MAozvmUBFjIhTVEbh682 [tags] => 0 ) [14] => Array ( [batch2] => 1,2,6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-84864364621&partnerID=40&md5=bc37289b83dd919cfb8e8525b5fd3fc1 [tag] => 0 [abstract_cn] => 应用密度泛函理论研究了纯(8,0)单壁碳纳米管(SWCNT)和B原子、N原子以及BN原子对掺杂的(8,0)SWCNTs对硫化氢气体分子的传感性质.计算结果表明,与纯碳纳米管相比,B原子掺杂的SWCNT显示了对H2S分子的敏感性,其几何结构和电子性质在吸附H2S分子后发生了显著变化;而N原子和BN原子对的掺杂没有改善SWCNT对H2S分子的吸附性能,因此我们建议B原子掺杂的SWCNT作为检测H2S分子的新型气相传感器. [keyword_cn] => 单壁碳纳米管;;硫化氢;;掺杂;;气相传感器;;密度泛函理论 [fund_No] => 国家重点基础研究发展计划(973计划); 国家自然科学基金资助项目 [article_id] => 73352,484602,629395,661376,238505,326134 [clc] => O647.31 [author_jg] => [王若曦] 山东大学理论化学研究所, 济南, 山东 250100, 中国.@@@[张冬菊] 山东大学理论化学研究所, 济南, 山东 250100, 中国.@@@[武剑] 山东大学理论化学研究所, 济南, 山东 250100, 中国.@@@[刘成卜] 山东大学理论化学研究所, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => 68fbc1a52f343a904d2a39e50445580d-1677890954 [hints] => 12 [issue] => 2 [author_first] => 王若曦; [sys_level_num] => 2_3 [sys_jg_type] => 11,3,5 [format_issn_issue_page_pub_year] => bdbf929ec3c7865efafb358f117ba875-795718121 [source_type] => 351 [pub_year] => 2007 [pub_date] => JAN 28 [pages] => 4 [from_id] => 76,75,73,80,78,85 [author_cn] => 王若曦;张冬菊;武剑;刘成卜; [issn] => 0567-7351 [batch] => 3249,3250,3252,3254,3243,3241 [publication_cn] => 化学学报 [title_cn] => 硼氮掺杂的碳纳米管对硫化氢气敏性能的理论研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => b26765b1b201b79953e228e2b241cb67388968227 [page] => 107-110 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 5 [check_3Y] => 6 [language] => Chinese [delivery_No] => 135SC [format_title] => f64896638146e25f42b1cc5f148d23681483427623 [cauthor_ad] => [Wang, RX]Shandong Univ, Inst Theoret Chem, Jinan 250100, Peoples R China. [author_fn] => Wang Ruo-Xi; Zhang Dong-Ju; Wu Jian; Liu Cheng-Bu [reference] => ADAMS DF, 1968, APCA J, V18, P145@@@BALASUBRAMANIAN N, 1990, ANALYST, V115, P859, DOI 10.1039/an9901500859@@@Collins PG, 2000, SCIENCE, V287, P1801, DOI@@@10.1126/science.287.5459.1801@@@Duclaux L, 2002, CARBON, V40, P1751, DOI 10.1016/S0008-6223(02)00043-X@@@Feng X, 2005, J AM CHEM SOC, V127, P10533, DOI 10.1021/ja042998u@@@Goldoni A, 2003, J AM CHEM SOC, V125, P11329, DOI 10.1021/ja034898e@@@Han WQ, 2001, CHEM PHYS LETT, V346, P368, DOI@@@10.1016/S0009-2614(01)00993-9@@@Jacobsson S, 1989, Chromatogr, V479, P194@@@Jimenez I, 2003, SENSOR ACTUAT B-CHEM, V93, P475, DOI@@@10.1016/S0925-4005(03)00198-9@@@Kong J, 2000, SCIENCE, V287, P622, DOI 10.1126/science.287.5453.622@@@Kong J, 2001, ADV MATER, V13, P1384, DOI@@@10.1002/1521-4095(200109)13:18<1384::AID-ADMA1384>3.0.CO;2-8@@@Law M, 2002, ANGEW CHEM INT EDIT, V41, P2405, DOI@@@10.1002/1521-3773(20020703)41:13<2405::AID-ANIE2405>3.0.CO;2-3@@@Lawrence NS, 2004, ANAL CHIM ACTA, V517, P131, DOI@@@10.1016/j.aca.2004.03.101@@@Li J, 2003, NANO LETT, V3, P929, DOI 10.1021/nl034220x@@@Li J P, 2000, Actuators B, V65, P111@@@Liu YL, 2004, SENSOR ACTUAT B-CHEM, V102, P148, DOI@@@10.1016/j.snb.2004.04.014@@@Peng S, 2003, NANO LETT, V3, P513, DOI 10.1021/nl034064u@@@PERDEW JP, 1992, PHYS REV B, V45, P13244, DOI 10.1103/PhysRevB.45.13244@@@Srivastava D, 1999, PHYS REV LETT, V83, P2973, DOI@@@10.1103/PhysRevLett.83.2973@@@Tao WH, 2002, SENSOR ACTUAT B-CHEM, V81, P237, DOI@@@10.1016/S0925-4005(01)00958-3@@@Wang YR, 2002, SENSOR ACTUAT B-CHEM, V87, P115, DOI@@@10.1016/S0925-4005(02)00227-7@@@Wei BY, 2003, SENSOR MATER, V15, P177@@@Wei B. Y., 2004, ACTUATORS B, V101, P81, DOI DOI@@@10.1016/J.SNB.2004.02.028@@@Yan Y, 1994, Chem Lett, V9, P1753@@@Zhang YM, 2006, J PHYS CHEM B, V110, P4671, DOI 10.1021/jp0602272@@@Zhao Q, 2005, NANO LETT, V5, P847, DOI 10.1021/nl050167w@@@2001, Cerius2,Version 4.6,Dmol3 [publication_29] => ACTA CHIM SINICA [end_page] => 110 [abstract_en] => The intrinsic and B atom, N atom and BN atoms doped (8, 0) single-walled carbon nanotubes (SWCNTs), as sensors to detect hydrogen sulfide, have been investigated using density functional theory (I)FT). The calculated results show that the B-doped SWCNTs present high sensitivity to the gaseous hydrogen sulfide molecule, and their geometric structures and electronic properties present dramatic changes after the adsorption of H2S molecule, compared with the intrinsic SWCNTs. While N-doped SWCNTs and BN-doped SWCNTs can not improve the sensing performance of the SWCNTs to H2S molecule. So it is suggested that B-doped SWCNTs would be promising candidates for serving as effective sensors to detect the presence of H2S molecules. [author_in] => [Wang, R.-X] Institute of Theoretical Chemistry, Shandong University, Jinan 250100, China, Criminal Technological Department, Shandong Police College, Jinan 250014, China@@@[ Zhang, D.-J] Institute of Theoretical Chemistry, Shandong University, Jinan 250100, China@@@[ Wu, J] Institute of Theoretical Chemistry, Shandong University, Jinan 250100, China@@@[ Liu, C.-B] Institute of Theoretical Chemistry, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 107 [author_en] => Wang, RX; Zhang, DJ; Wu, J; Liu, CB [volume] => 65 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => single-walled carbon nanotubes; hydrogen sulfide; doping; gas sensor;; density functional theory [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => ROOM-TEMPERATURE; CHEMICAL SENSORS; GAS; H2S; SENSITIVITY; NO2 [publication_iso] => Acta Chim. Sin. [format_title_en] => ae9e3798933f872df950a5e4f6f58f421859788938 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 27 [email] => cbliu@sdu.edu.cn [cite_awos] => 6 [wos_No] => WOS:000244172300004 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 1 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Theoretical study on the sensing properties of the boron and nitrogen doped carbon nanotubes for hydrogen sulfide [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] => ,gassensor,hydrogensulfide,singlewalledcarbonnanotubes,doping,densityfunctionaltheory [jl_keyword_cn] => ,单壁碳纳米管,硫化氢,掺杂,密度泛函理论,气相传感器 [jl_clc] => o64731 [jl_publisher] => sciencechinapress [company_id] => 0,0,0,0,0 [author_id] => 25363 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 2 [name] => 张冬菊 [irtag] => 7 [t_index] => 0 [person_id] => 25363 ) ) [sys_author_id_arr] => [cscd_No] => CSCD:2731237 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => 硫化氢,密度泛函理论,单壁碳纳米管,gassensor,hydrogensulfide,singlewalledcarbonnanotubes,掺杂,doping,气相传感器,densityfunctionaltheory [sys_author_id] => [format_cscd_No] => fc2439c1a61ac09337aa01dd111c549a1831617363 [format_title_en_publication_en_pub_year] => f6d7de6d0bc92e4c8fd91f044b4e5a8b762513772 [format_wos_No] => 861311d9fdd8d7e3d6260b98db4c7dcb-303652832 [format_title_en_issn_pub_year] => 86bdc6f6ee33870506b069afca9ff44f239444340 [format_scopus_No] => f4b8092fd49f7466c4b4127f11b0251d1621639305 [standard_in] => Institute of Theoretical Chemistry, Shandong University, Jinan 250100, China; Criminal Technological Department, Shandong Police College, Jinan 250014, China [cauthor] => Liu, CB(cbliu@sdu.edu.cn) [datebase] => Scopus [cite_scopus] => 8 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-84864364621 [id] => 0w1FvmUBFjIhTVEbZaRs [tags] => 0 ) [15] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3241,3254,3243,3252 [tag] => 0 [abstract_cn] => 合成了一种新的导电分子晶体(PyH)[Ni(dmit)2]2(Py=pyridine,dmit=(C3S5)2-=4,5-dimercapto-1,3-dithiole-2-thione),用元素分析、红外光谱对其进行了表征,并用四圆X射线衍射方法确定了结构,该晶体属于三斜晶系,P-1空间群;晶胞参数为:a=0.59227(4)nm,b=0.82279(6)nm,c=1.67535(9)nm,α=90.233(5)°,β=92.107(5)°,y=104.654(6)°;V=0.78925(9)nm3,Z=1.(PyH)[Ni(dnit)2]2晶体中,导电组元[Ni(dmit)2]-0.5沿b轴方向形成具有二聚体结构的柱状堆积,在(001)面形成以肩并肩分子间的S…S强相互作用为特征的二维导电层,这种二维导电层上的室温电导率为0.13 Ω-1@cm-1,在c轴方向,(PyH)+与[Ni(dmit)2]-0.5之间除库仑作用外,还存在N-H…S,C-H…S氢键相互作用.单晶(001)面上变温电阻的测定结果表明,在∞K到室温的温度范围内,(PyH)[Ni-(dmit)2]2具有半导体导电行为,导电激活能为0.15eV. [keyword_cn] => 分子导体;合成;结构;导电性;(PyH)[Ni(dmit)2]2;镍配合物;吡啶阳离子; [clc] => O614.813 O62 [author_jg] => [许文] 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.@@@[薛刚] 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.@@@[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.@@@[张德清] 中国科学院化学研究所, 北京 100080, 中国.@@@[徐伟] 中国科学院化学研究所, 北京 100080, 中国.@@@[徐翠英] 中国科学院化学研究所, 北京 100080, 中国.@@@[张金彪] 中国科学院化学研究所, 北京 100080, 中国 [format_title_cn_publication_cn_pub_year] => 6499107f99c3d181905973520d25e76d1492037491 [from_id] => 76,75,73,80,78,85 [issue] => 12 [sys_level_num] => 2_1 [sys_jg_type] => 10,2,5 [source_type] => 351 [pub_year] => 2002 [article_id] => 664457,597876,239542,495072,331653,82202 [pages] => 6 [hints] => 7 [author_cn] => 许文[1];方奇[1];薛刚[1];于文涛[1];刘国群[1];张德清[2];徐伟[2];徐翠英[2];张金彪[2] [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-0442267256&partnerID=40&md5=4bc35a1e51fb54cd313530f3ddd13316 [publication_cn] => 化学学报 [title_cn] => 分子导体(PyH)[Ni(dmit)2]2的合成、结构与导电性 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 061d7847c3e6b582f7e1b5738c863adf-186056764 [hb_type] => 2 [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 5 [fund_No] => 国家自然科学基金(Nos.20172034 and 29672023); 中国科学院有机固体开放实验室资助项目 [check_3Y] => 3 [language] => Chinese [delivery_No] => 628AK [format_title] => ec1357904dbe01adea3bf1c6673912ef-1302797810 [cauthor_ad] => [Xu, W]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Xu, W; Fang, Q; Xue, G; Yu, WT; Liu, GQ; Zhang, DQ; Xu, W; Xu, CY; Zhang, JB [reference] => BOUSSEAU M, 1986, J AM CHEM SOC, V108, P1908, DOI 10.1021/ja00268a032@@@BROSSARD L, 1989, J PHYS-PARIS, V50, P1521, DOI@@@10.1051/jphys:0198900500120152100@@@Fang Q, 2002, J CHEM SOC DALTON, P1377, DOI 10.1039/b105854c@@@KOBAYASHI A, 1987, CHEM LETT, P1819, DOI 10.1246/cl.1987.1819@@@KOBAYASHI A, 1991, CHEM LETT, P2163, DOI 10.1246/cl.1991.2163@@@KOBAYASHI H, 1992, CHEM LETT, P1909, DOI 10.1246/cl.1992.1909@@@MIYAZAKI A, 1992, B CHEM SOC JPN, V65, P2528, DOI 10.1246/bcsj.65.2528@@@@@@STEIMECKE G, 1979, PHOSPHORUS SULFUR, V7, P49, DOI@@@10.1080/03086647808069922@@@@@@TAJIMA H, 1993, CHEM LETT, P1235, DOI 10.1246/cl.1993.1235@@@Veldhuizen YSJ, 1997, INORG CHEM, V36, P4930, DOI 10.1021/ic970347b@@@@@@Xu W, 2001, SYNTHETIC MET, V122, P409, DOI 10.1016/S0379-6779(00)00405-7 [publication_29] => ACTA CHIM SINICA [end_page] => 2158 [abstract_en] => A new molecular conductor ( PyH) [ Ni ( dmit)(2)](2) ( Py = pyridine, dmit = ( C3S5)(2-) = 4,5-dimercapto-1,3-dithiole-2-thione) has been prepared by oxidation with I-2/NaI and characterized by elemental analysis and IR spectrum. The single crystal structure was determined by four-circle X-ray diffraction method. Crystallographic parameters for (PyH) [Ni(dmit)(2)](2): triclinic system; P-1 space group; a = 0.59227 (4) nm, b =0.82279(6) mn, c = 1.67535(9) nm, alpha = 90.233(5)degrees, beta = 92.107(6)degrees, gamma = 104.654(6)degrees; V = 0. 78925 (9) nm; Z = 1. Both [Ni (dmit)(2)](-0.5) anion and PyH+ cation are almost planar. [Ni(dmit)(2)](-0.5) is stacked to form columns of dimerised pairs along the b-axis. Short and intense (SS)-S-... contacts in side-by-side style build a kind of two-dimensional network in the (001) plane. The conductivity at one direction on (001) plane at room temperature was measured to be 0.13 Omega(-1) (.) cm(-1). Along the c direction the sheets of conductive [Ni(dTnit)(2)](-0.5) are structurally modulated by hydrogen bonds between anions and cations. The resistivity-temperature curve in the temperature range of 90 - 290 K shows that the title compound behaves as a semiconductor with quite narrow energy gap. [orcID] => Liu, Guoqun/0000-0002-3342-5780 [author_in] => [Xu, 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@@@[ Xue, G] 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, G.-Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Zhang, D.-Q] Institute of Chemistry, Chinese Academy of Sciences, Beijing 100080, China@@@[ Xu, W] Institute of Chemistry, Chinese Academy of Sciences, Beijing 100080, China@@@[ Xu, C.-Y] Institute of Chemistry, Chinese Academy of Sciences, Beijing 100080, China@@@[ Zhang, J.-B] Institute of Chemistry, Chinese Academy of Sciences, Beijing 100080, China [publication_type] => J [begin_page] => 2153 [article_dt] => Article [author_en] => Xu, W; Fang, Q; Xue, G; Yu, WT; Liu, GQ; Zhang, DQ; Xu, W; Xu, CY; Zhang, JB [volume] => 60 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => molecular conductor; synthesis; structure; electrical conductivity [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => CRYSTAL-STRUCTURE; SUPERCONDUCTOR; TRANSITION; METAL [publication_iso] => Acta Chim. Sin. [format_title_en] => a11f3e9d635d7fcdcbb9497005493383274661362 [publisher_city] => BEIJING [pub_date] => DEC [hx_id] => 2377,2378,2371 [reference_No] => 11 [email] => Fangqi@icm.sdu.edu.cn [cite_awos] => 6 [wos_No] => WOS:000179969400013 [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 conductivity of molecular conductor (PyH)[Ni(dmit)(2)](2) [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] => electricalconductivity,synthesis,structure,molecularconductor [jl_keyword_cn] => 镍配合物,pyhnidmit22,,结构,分子导体,吡啶阳离子,导电性,合成 [jl_clc] => o614813o62 [jl_publisher] => sciencechinapress [company_id] => 24,151 [sys_subject_sort] => 0,0 [college_parent_id] => 24,151 [company_test] => Array,Array [author_id] => 24843,20672,25191 [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] => 许文 [irtag] => 7 [t_index] => 0 [person_id] => 24843 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 于文涛 [irtag] => 7 [t_index] => 0 [person_id] => 25191 ) ) [sys_author_id_arr] => 20672方奇 [cscd_No] => CSCD:1139004 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => pyhnidmit22,导电性,吡啶阳离子,合成,镍配合物,electricalconductivity,分子导体,synthesis,molecularconductor,structure,结构 [sys_author_id] => 20672 [format_cscd_No] => 54a27f1ce147c97201828ed1e6dd6032-24558549 [format_title_en_publication_en_pub_year] => e6f6e780a542e84ac9438cfa8cd2321a826992157 [format_wos_No] => a740437d3e5efa467c8392f29643bddf426507591 [format_title_en_issn_pub_year] => 7042a0234f6175b35dd542ca120ac50b390139824 [format_scopus_No] => 325b1794eda6a234c7f3a3d205d2d0e1693878080 [standard_in] => State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China; Institute of Chemistry, Chinese Academy of Sciences, Beijing 100080, China [datebase] => Scopus [page] => 2153-2158 [cite_scopus] => 5 [format_issn_issue_page_pub_year] => 0d02885845544868f2344810f6807e0e1673518242 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-0442267256 [id] => KAkwvmUBFjIhTVEbmrnE [tags] => 0 ) [16] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3252,3254,3243,3241 [tag] => 0 [abstract_cn] => 用非均相共沉淀法合成了系列Zn Al类水滑石 (HTlc)样品 ,研究发现Al/(Zn +Al)摩尔比 (x)在 0 3 1~ 0 5 2范围内可得到纯类水滑石相 .用电势滴定法和显微电泳法分别测定了 5个纯Zn AlHTlc样品的零净电荷点 (PZNC)和等电点 (IEP) ,以考察结构电荷对PZNC和IEP的影响 .研究发现随结构正电荷密度的增加 ,PZNC和IEP均降低 ;IEP高于PZNC ,且随结构正电荷密度的降低 ,IEP与PZNC的差值也降低 ,表明IEP与PZNC的差异来自结构电荷的影响 .结构正电荷对HTlc的IEP与PZNC相对大小的影响与高价阳离子特性吸附的影响一致 ... [keyword_cn] => 类水滑石;层状双金属氢氧化物;等电点;零净电荷点;电势滴定 [article_id] => 249101,490086,663383,620419,82205,330456 [clc] => O657.2 [author_jg] => [李丽芳] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[侯万国] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[戴肖南] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.@@@[刘春霞] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => b2ffc3c18e94fe69a82bfe5389dd26c4-32016726 [hints] => 5 [issue] => 4 [sys_level_num] => 2_3 [sys_jg_type] => 3,5 [format_issn_issue_page_pub_year] => d611381403e6047e02ec0aeafff5b8fe-796347967 [source_type] => 351 [pub_year] => 2004 [pub_date] => FEB 28 [pages] => 4 [from_id] => 76,75,73,80,78,85 [author_cn] => 李丽芳,侯万国,戴肖南,刘春霞 [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33747599517&partnerID=40&md5=71f8e241194b6b677ffb314c6de8364a [publication_cn] => 化学学报 [title_cn] => Zn-Al类水滑石零净电荷点及等电点研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 5b5309256b748591acc6ba7a95e679df-931611947 [page] => 429-432+343 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 5 [fund_No] => 国家自然科学基金; 教育部跨世纪人才基金资助项目 [check_3Y] => 2 [language] => Chinese [delivery_No] => 776GU [format_title] => 872cfc025fa63efb6b99cc04b5b8768f-957699110 [cauthor_ad] => [Li, LF]Shandong Univ, Key Lab Colloid & Interface Chem, Jinan 250100, Peoples R China. [author_fn] => Li, LF; Hou, WG; Dai, XN; Liu, CX [reference] => Cavani F, 1991, CATAL TODAY, V11, P173, DOI 10.1016/0920-5861(91)80068-K@@@Han SH, 1997, CHINESE J CHEM, V15, P304@@@Hou W.G., 2001, LANGMUIR, V17, P1885@@@James R. O., 1982, SURF COLLOID SCI, V12, P119@@@[姜鹏 Jiang Peng], 2002, [高等学校化学学报, Chemical Journal of Chinese@@@Universities], V23, P78@@@Kraepiel AML, 1998, ENVIRON SCI TECHNOL, V32, P2829, DOI@@@10.1021/es9802899@@@Li SP, 2003, J COLLOID INTERF SCI, V257, P244, DOI@@@10.1016/S0021-9797(02)00062-0@@@Li SP, 2002, CHINESE CHEM LETT, V13, P781@@@PARKS GA, 1965, CHEM REV, V65, P177, DOI 10.1021/cr60234a002@@@Shojai F, 2000, CERAM INT, V26, P133, DOI 10.1016/S0272-8842(99)00030-9@@@@@@Sposito G, 1998, ENVIRON SCI TECHNOL, V32, P2815, DOI 10.1021/es9802347@@@SPRYCHA R, 1984, J COLLOID INTERF SCI, V102, P173, DOI@@@10.1016/0021-9797(84)90211-X@@@@@@YOON RH, 1979, J COLLOID INTERF SCI, V70, P483, DOI@@@10.1016/0021-9797(79)90056-0@@@侯万国, 1998, 化学学报, V56, P514 [publication_29] => ACTA CHIM SINICA [end_page] => 432 [abstract_en] => A series of Zn-Al hydrotalcite-like compounds (HTlc) was synthesized by co-precipitation method. The structure and chemical composition of the samples were determined by X-ray powder diffraction and automatic X-ray fluorescent spectrometric analysis, respectively. The results showed that pure HTlc could be obtained in the range of 0.31 less than or equal to x less than or equal to 0.52 [x = n(Al)/n(Zn+ Al)]. The point of zero net charge (PZNC] and isoelectric point (IEP) of pure Zn-Al HTlc were measured using potentiometric titration method and electrophoretic method, respectively. The results indicated that permanent charge led to shifts in the PZNC and IEP of HTlc samples, and this influence was just the same as that of the cations adsorption on HTlc samples. PZNC and EEP all decreased with x or permanent charge density increasing, and EEP values were higher than PZNC values for all samples. The difference value (IEP-PZNQ increased as x value increased, indicating that the difference came from the structure charge of HTlc samples. [author_in] => [Li, L.-F] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Jinan 250100, China, College of Applied Chemistry and Material Science, Shandong Agriculture University, Tai\'an 271018, China@@@[ Hou, W.-G] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Jinan 250100, China@@@[ Dai, X.-N] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Jinan 250100, China@@@[ Liu, C.-X] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 429 [author_en] => Li, LF; Hou, WG; Dai, XN; Liu, CX [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => hydrotalcite-like compound; layered double hydroxide; isoelectric point;; the point of zero net charge; potentiometric titration [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => HYDROXIDES; INTERFACE; SURFACE; OXIDES [publication_iso] => Acta Chim. Sin. [format_title_en] => fbbbb62741f89877d96836f3db4c0bde1148656553 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 14 [email] => wghou@sdu.edu.cn [cite_awos] => 8 [wos_No] => WOS:000189108900017 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Studies of the point of zero net charge and isoelectric point of Zn-Al hydrotalcite-like compounds [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] => ,potentiometrictitration,hydrotalcitelikecompound,layereddoublehydroxide,isoelectricpoint,thepointofzeronetcharge [jl_keyword_cn] => 层状双金属氢氧化物,类水滑石,电势滴定,等电点,零净电荷点 [jl_clc] => o6572 [jl_publisher] => sciencechinapress [company_id] => [author_id] => 21153 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 侯万国 [irtag] => 7 [t_index] => 0 [person_id] => 21153 ) ) [sys_author_id_arr] => 21153侯万国 [cscd_No] => CSCD:1614035 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => isoelectricpoint,电势滴定,hydrotalcitelikecompound,potentiometrictitration,类水滑石,layereddoublehydroxide,等电点,thepointofzeronetcharge,零净电荷点,层状双金属氢氧化物 [sys_author_id] => 21153 [format_cscd_No] => 4ee3b71d7b0132626dd94a3cfed493f7923573371 [format_title_en_publication_en_pub_year] => 20c42174f5acaf504a19f02daa4a8f531419369599 [format_wos_No] => 4a13bdd2989c35a9967fe96e12fa6f45-358580627 [format_title_en_issn_pub_year] => 892247e677c92bcc53d0a32d18bdbfec-1194214206 [datebase] => Scopus [format_scopus_No] => 856e88ca8c6225ce6f1ee91b18c555331800071739 [cite_scopus] => 6 [sys_priority_field] => 76 [standard_in] => Key Laboratory of Colloid and Interface Chemistry, Shandong University, Jinan 250100, China; College of Applied Chemistry and Material Science, Shandong Agriculture University, Tai\'an 271018, China [scopus_No] => 2-s2.0-33747599517 [id] => Dg1GvmUBFjIhTVEbF9Bp [tags] => 0 ) [17] => Array ( [batch2] => 1,2,6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33749152079&partnerID=40&md5=361c24cee13df31b6a960448bc3e794d [tag] => 0 [abstract_cn] => 合成了新的周边含12个4-硝基偶氮苯端基一代碳硅烷树枝状大分子的钯(II)配合物(G1Pd),并用元素分析、核磁共振氢谱、碳谱、红外、紫外-可见光谱、能量色散X射线分析(EDXRA)、偏光显微镜、差示扫描量热法和广角X射线衍射法对其结构和液晶性质进行了表征.配合物G1Pd的相行为是K122ch189I166ch90K.给出一种具有新的结构特点的液晶性树枝状大分子,它兼有配位金属和介晶基元.在液晶和液晶高分子界观察到首例胆甾相的高强向错和首例树枝状大分子配合物的高强向错现象. [keyword_cn] => 高强向错;;钯-偶氮配合物;;胆甾相液晶;;树枝状大分子配合物 [fund_No] => 国家自然科学基金; 山东省自然科学基金 [article_id] => 489160,73349,661850,620412,249256,328630 [clc] => TB383 [author_jg] => [张其震] 山东大学化学化工学院,中国.@@@[殷晓颖] 山东大学化学化工学院,中国.@@@[杨爱香] 山东大学化学化工学院,中国.@@@[王艳] 山东大学环境与工程学院, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => 95c2e5aed99878d0bb63d446d5a24236 [hints] => 11 [issue] => 10 [author_first] => 张其震 [sys_level_num] => 2_3 [sys_jg_type] => 11,8,5,10 [format_issn_issue_page_pub_year] => aa09ea4053c764bb9435158d0b59d396 [source_type] => 351 [pub_year] => 2005 [pub_date] => MAY 28 [pages] => 7 [from_id] => 76,75,73,80,78,85 [author_cn] => 张其震;殷晓颖;李爱香;王艳 [issn] => 0567-7351 [batch] => 3249,3250,3252,3254,3243,3241 [publication_cn] => 化学学报 [title_cn] => 一代碳硅烷树枝状大分子钯配合物的液晶性 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 379f81f8d0d022ab1c2922c038c02bb4 [page] => 934-940+871 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 5 [check_3Y] => 2 [language] => Chinese [delivery_No] => 929FH [format_title] => ef3d5ac237159af17adaf32408c49c4a514479940 [cauthor_ad] => [Zhang, QZ]Shandong Univ, Sch Chem & Chem Engn, Jinan 250100, Peoples R China. [author_fn] => Zhang, QZ; Yin, XY; Li, AX; Wang, Y [reference] => Donnio B, 2002, MACROMOLECULES, V35, P370, DOI 10.1021/ma010881+@@@GHEDINI M, 1982, MOL CRYST LIQ CRYST, V84, P207, DOI@@@10.1080/00268948208072141@@@@@@Stebani U, 1996, ANGEW CHEM INT EDIT, V35, P1858, DOI@@@10.1002/anie.199618581@@@@@@Terunuma D, 1999, CHEM LETT, P565@@@TWING B, 1996, LIQ CRYST, V20, P287@@@Zhang QZ, 2004, CHINESE J CHEM, V22, P1039@@@[张其震 Zhang Qizhen], 2003, [高等学校化学学报, Chemical Journal of Chinese@@@Universities], V24, P1887@@@[张其震 Zhang Qizhen], 2003, [化学学报, Acta Chemical Sinica], V61, P416@@@[张其震 Zhang Qizhen], 2002, [化学学报, Acta Chemical Sinica], V60, P2232@@@张其震, 2003, 化学学报, V61, P147@@@张其震, 1998, 高等学校化学学报, V19, P117 [publication_29] => ACTA CHIM SINICA [end_page] => 940 [abstract_en] => The synthesis of a new palladium-azo complex of carbosilane dendrimer of the first generation (G1Pd) was described. Twelve 4-nitroazobenzene groups were used as fragments and attached on its periphery. Azobenzene groups of carbosilane dendrimer underwent ortho-metallation by reaction with PdCl42+ 4 giving palladium(II)-azo complex. The structure and liquid crystallinity (LC) of G1Pd were characterized by elemental analysis, H-1 NMR, C-13 NMR, IR, LTV-vis, energy-dispersion X-ray analysis (EDXRA), polarizing optical micrography, DSC and WAXD. The phase behavior of G1Pd in LC state is K122ch1891166ch90K. An LC dendrimer having novel structure characteristic was given, which has metal coordination bond and mesomorphic moiety. The high-strength disclination was first observed from cholesteryl LC state and dendritic complexes of liquid crystal and LC polymers. [researcherID] => SDU, Environ Res/P-4462-2015 [author_in] => [Zhang, Q.-Z] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Yin, X.-Y] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Li, A.-X] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Wang, Y] School of Environmental Science and Engineering, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 934 [author_en] => Zhang, QZ; Yin, XY; Li, AX; Wang, Y [volume] => 63 [get_data] => 2018-08-29 [publisher] => SCIENCE PRESS [keyword_en] => high-strength disclination; palladium-azo complex; cholesteryl liquid; crystal; dendritic polymeric complex [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => MESOGENIC GROUPS; PERIPHERY; PHASE [publication_iso] => Acta Chim. Sin. 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[keyword_cn] => β-环糊精;;单-2,3-二醛基-β-环糊精;;楔筒状大环分子 [fund_No] => 国家自然科学基金(No. 29902004) [article_id] => 332083,554758,239539,664158,45669 [clc] => O636 [author_jg] => [郝爱友] 山东大学化学与化工学院, 济南, 山东 250100, 中国.@@@[王金山] 山东师范大学化学系, 济南, 山东 250014, 中国 [format_title_cn_publication_cn_pub_year] => d38d24495e6e88049be1f33fef48ed25132746493 [hints] => 9 [issue] => 8 [author_first] => 郝爱友 [sys_level_num] => 2_3 [sys_jg_type] => 10,5 [format_issn_issue_page_pub_year] => 3fcf7898a18c17e0c20454e2ed8b9165-1178556098 [source_type] => 351 [pub_year] => 2002 [pub_date] => AUG [pages] => 3 [from_id] => 75,78,73,80,85 [author_cn] => 郝爱友;王金山 [issn] => 0567-7351 [batch] => 3250,3249,3241,3254,3252 [publication_cn] => 化学学报 [title_cn] => 用环糊精合成楔筒状主体分子新模型 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => faf2c36a896a2ca5ef2c5754ef9f6ffd1924117586 [page] => 1536-1538+1356 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 5 [check_3Y] => 1 [language] => Chinese [delivery_No] => 587LH [format_title] => b18bfede19623310dd019ce10bac2b73-1545227800 [cauthor_ad] => [Hao, AY]Shandong Univ, Sch Chem & Chem Engn, Jinan 250100, Peoples R China. [author_fn] => Hao, AY; Wang, JS [reference] => Gu LQ, 1999, NATURE, V398, P686@@@Hao A Y, 2000, Commun, V30, P3703@@@Hao A Y, 1999, Inclusion Phenomena and Macrocyclic Chemistry, V34, P445@@@HAO AY, 1995, ANAL LETT, V28, P2041, DOI 10.1080/00032719508000023@@@@@@Kuwabara T, 1999, ANAL CHEM, V71, P2844, DOI 10.1021/ac9814041@@@Kuwabara T, 1998, Org. Chem., V63, P8729@@@Schneider H J, 1990, Frontiers in Supramolecular Organic CHemistry and@@@Photochemistry, VCH, Weinheim@@@郝爱友, 1996, 化学通报, P16@@@张希(译), 1995, 超分子化学@@@刘育, 1999, 中国科学(B辑), V29, P532 [publication_29] => ACTA CHIM SINICA [end_page] => 1538 [abstract_en] => beta-Cyclodextrin with the 6-hydroxyls protected by dimethyl-tert-butylsilyl was selectively oxidized by lead tetraacetate. After the silyl groups were removed off by boron fluoride-etherate, mono-2, 3-dialdehydo-beta-cyclodextrin as a cuniform molecule could be constructed. Mono-2,3-dialdehydo-beta-cyclodextrin is more soluble in water than beta-cyclodextrin. Mono-2,3-dialdehydo-beta-cyclodextrin could be used as the mobile phase additives for effective resolution of DL-adrendine on silica gel plates. [author_in] => [Hao, AY]Shandong Univ, Sch Chem & Chem Engn, Jinan 250100, Peoples R China.@@@[ Wang, JS] Shandong Normal Univ, Dept Chem, Jinan 250014, Peoples R China. [publication_type] => J [begin_page] => 1536 [author_en] => Hao, AY; Wang, JS [volume] => 60 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => beta-cyclodextrin; mono-2,3-dialdehydo-beta-cyclodextrin; cuniform; molecule [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [publication_iso] => Acta Chim. Sin. [format_title_en] => 93777d13ac1b4eac6316fd0701616d9d-975946120 [publisher_city] => BEIJING [hx_id] => 2377,2371 [reference_No] => 10 [email] => haoay@sdu.edu.cn [cite_awos] => 6 [wos_No] => WOS:000177641800033 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Synthesis of new cuniform molecular host model based on beta-cyclodextrin [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] => mono2,molecule,cuniform,betacyclodextrin,3dialdehydobetacyclodextrin [jl_keyword_cn] => ,β环糊精,3二醛基β环糊精,楔筒状大环分子,单2 [jl_clc] => o636 [jl_publisher] => sciencechinapress [author_id] => 21076 [author_test] => Array ( [0] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 1 [name] => 郝爱友 [sys_author_id] => Array ( [0] => 21076 ) [irtag] => 0 [t_index] => 0 [person_id] => 21076 ) ) [company_id] => 43,169 [sys_subject_sort] => 0,0 [college_parent_id] => 43,169 [company_test] => Array,Array [sys_author_id_arr] => 21076郝爱友 [cscd_No] => CSCD:1009220 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => molecule,betacyclodextrin,单2,mono2,3二醛基β环糊精,cuniform,3dialdehydobetacyclodextrin,β环糊精,楔筒状大环分子 [sys_author_id] => 21076 [format_cscd_No] => 8c1573dd78118e81f602604b33dc0dfa1152032683 [format_title_en_publication_en_pub_year] => f47a698b58734b427185502ad49170e2-1071988493 [format_wos_No] => cd3c4b62723e55bd2ee8f94ae3b432ad-333059642 [format_title_en_issn_pub_year] => b321dda114884c6225790751b7b2c3321377953343 [id] => lg5JvmUBFjIhTVEbudND [tags] => 0 ) [19] => Array ( [issn] => 0567-7351 [reference] => Althorpe SC, 2003, ANNU REV PHYS CHEM, V54, P493, DOI@@@10.1146/annrev.physchem.54.011002.103750@@@Cai ZT, 2001, CHINESE J CHEM, V19, P1033@@@Eyring H, 1980, Basic Chemical Kinetics. Chapt. 3, P3@@@KUPPERMANN A, 1981, POTENTIAL ENERGY SUR, P375@@@LATHAM SL, 1978, J CHEM PHYS, V69, P3746, DOI 10.1063/1.437039@@@Murrell J N, 1984, Molecular Potential Energy Functions, P2@@@Schatz GC, 2000, SCIENCE, V288, P1599, DOI 10.1126/science.288.5471.1599@@@@@@SKODJE RT, 1993, ANNU REV PHYS CHEM, V44, P145, DOI@@@10.1146/annurev.pc.44.100193.001045@@@Sun X M, 2004, Can. J. Chem@@@WALLER IM, 1990, J PHYS CHEM-US, V94, P2240, DOI 10.1021/j100369a009@@@WU SF, 1971, CHEM PHYS LETT, V116, P557 [batch2] => 1,2,6 [format_cscd_No] => aa744b7ef9c01d698a59ea43f6615580-385633710 [begin_page] => 372 [tag] => 0 [research_area] => Chemistry [publication_info] => 0567-7351(2005)63:5<372:PFSNMJ>2.0.TX;2-G [abstract_en] => The conception of partial potential energy surface (PPES) was presented in this paper. PPES can be extracted from complete potential energy surface (CPES), otherwise, it can be constructed with ab initio method. For the systems of F + H-2-> FH + H, H + H-2-> H-2 + H, I + HI -> IH + I and Na + I-2-> Na+ + I-2(-), the construction and applications of PPES were proposed as typical examples. It can be seen that the applications of PPES show remarkable virtue in analyzing the reaction mechanism and the formation of scattering resonance state. [abstract_cn] => 提出了偏分势能面的概念,偏分势能面可由完全势能面抽取出来,也可采用ab initio方法进行构造.作为范例,给出了F+H2→FH+H,H+H2→H2+H,I+HI→IH+I及Na+I2→Na++I2等体系中几种偏分势能面的构造和应用.可以看到,应用偏分势能面对于分析反应机理及散射共振态的生成方面显示突出优点. [keyword_cn] => 势能面;偏分势能面;反应路径;动力学Eyring湖;散射共振态 [fund_No] => 国家自然科学基金; 高等学校博士点基金资助项目 [format_title_en_publication_en_pub_year] => 10f88033c33383f4317e9da12194f2c21965128502 [publication_type] => J [author_jg] => [孙孝敏] 山东大学理论化学研究所, 济南, 山东 250100, 中国.@@@[王华阳] 山东大学理论化学研究所, 济南, 山东 250100, 中国.@@@[蔡政亭] 山东大学理论化学研究所, 济南, 山东 250100, 中国.@@@[冯大诚] 山东大学理论化学研究所, 济南, 山东 250100, 中国.@@@[边文生] 中国科学院化学研究所, 分子反应动力学国家重点实验室, 北京 100080, 中国 [cite_cscd] => 2 [cite_awos] => 5 [from_id] => 76,75,73,80,78 [issue] => 5 [email] => zhtcai@sdu.edu.cn [email_c] => zhtcai@sdu.edu.cn [sys_level_num] => 1_1 [format_title_cn_publication_cn_pub_year] => 60ac567ea5cb51ee66b6d66ba44d30db2020804372 [sys_jg_type] => [format_issn_issue_page_pub_year] => b53b72f1e8bfddcd4a0740ac118d022c-246051140 [title_en] => Partial potential energy surface and its applications (I): Conception, method of construction and several examples [volume] => 63 [author_fn] => Sun, XM; Wang, HY; Cai, ZT [pub_year] => 2005 [check_180] => 0 [keyword_en] => potential energy suface; partial potential energy surface; reaction; pathway; dynamic eyring lake; scattering resonance state [end_page] => 376 [article_id] => 249265,157766,662016,489279,620417,328657 [pages] => 5 [hints] => 5 [author_cn] => 孙孝敏;王华阳;蔡政亭;冯大诚;边文生 [language] => Chinese [source_type] => 351 [reference_No] => 11 [cscd_No] => CSCD:2083316 [batch] => 3250,3243,3249,3241,3252 [publication_en] => ACTA CHIMICA SINICA [hx_id] => 2377,2378,2371 [author_in] => [Sun, X.-M] Institute of Theoretical Chemistry, Shangdong University, Jinan 250100, China@@@[ Wang, H.-Y] Institute of Theoretical Chemistry, Shangdong University, Jinan 250100, China@@@[ Cai, Z.-T] Institute of Theoretical Chemistry, Shangdong University, Jinan 250100, China@@@[ Feng, D.-C] Institute of Theoretical Chemistry, Shangdong University, Jinan 250100, China@@@[ Bian, W.-S] State Key Laboratory of Molecular Reaction Dynamics, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100080, China [format_title_en_issn_pub_year] => a9da56770cf4817368dd27c5d962b643240094598 [check_3Y] => 2 [publication_cn] => 化学学报 [title_cn] => 偏分势能面及其应用(Ⅰ):概念、构造方法及几个简例 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 817fe1f4bc04066e86c3c280a07c4e7d2136139944 [page] => 372-376 [hb_type] => 2 [article_dt] => Article [hb_batch] => issn_issue_page_pub_year_1_7 [cite_wos] => 5 [delivery_No] => 906PE [format_title] => d2d53a3c95e4febd257d9358740123b81343787403 [cauthor_ad] => [Cai, ZT]Shandong Univ, Inst Theoret Chem, Jinan 250100, Peoples R China. [publication_29] => ACTA CHIM SINICA [author_en] => Sun, XM; Wang, HY; Cai, ZT [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => QUANTUM SCATTERING; CHEMICAL-REACTIONS; TRANSITION-STATE; RESONANCE; DYNAMICS [publication_iso] => Acta Chim. Sin. 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61. 稀土(Ⅲ)-冠醚配位反应的热力学性质 Ⅱ. 镧系(Ⅲ)高氯酸盐与二苯并18-冠-6在无水乙腈中配位反应的量热滴定研究 SCIE

作者:黄锡荣;蒋本杲;尹敬执;阎海科;

作者机构:[黄锡荣;蒋本杲;尹敬执;阎海科]山东大学化学系,山东大学化学系,山东大学化学系,中国科学院化学研究所 济南 250100,济南 250100,济南 250100,北京 100080

来源:化学学报,ACTA CHIMICA SINICA,1991,Vol.49,Issue.4,359-364

WOS被引数:6

资源类型:期刊论文

WOS:A1991FV35600009

62. 蔗糖对MO/水立方液晶体系流变性质的影响 CSCD SCOPUS SCIE

作者:王志宁,郑利强,李干佐

作者机构:[王志宁] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[郑利强] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[李干佐] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.4,274-278+255

WOS被引数:6

资源类型:期刊论文

WOS:000227223500004

63. 全氟辛酸钠与十二烷基三甲基溴化铵混合胶束微环境性质的NMR,ESR研究 SCOPUS SCIE

作者:郝京诚,汪汉卿,刘维民,李干佐

作者机构:[郝京诚,汪汉卿,刘维民,李干佐]山东师范大学化学系,中国科学院兰州化学物理研究所固体润滑开放实验室,中国科学院兰州化学物理研究所固体润滑开放实验室,山东大学化学系 济南250014,兰州730000,兰州730000,济南250100

来源:化学学报,ACTA CHIMICA SINICA,1997,Vol.55,Issue.4,322-327

WOS被引数:6

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WOS:A1997WX14500002

64. Brij类表面活性剂与Laponite纳米颗粒的相互作用及其稳定乳液的研究 CSCD SCOPUS SCIE

作者:李财富[1];张水燕[1];王君[1];冯绪胜[1];孙德军[1];徐健[1]

作者机构:[李财富] 山东大学化学与化工学院, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[张水燕] 山东大学化学与化工学院, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[王君] 山东大学化学与化工学院, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[冯绪胜] 山东大学化学与化工学院, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[孙德军] 山东大学化学与化工学院, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[徐健] 山东大学化学与化工学院, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2008,Vol.66,Issue.21,2313-2320

WOS被引数:6

资源类型:期刊论文

WOS:000261527700001

65. Mg-Fe-HTlc/高岭土悬浮体流变性研究 CSCD SCOPUS SCIE

作者:戴肖南,侯万国,李丽芳,焦燕妮

作者机构:[戴肖南,侯万国,李丽芳,焦燕妮]山东大学胶体与界面化学教育部重点实验室,山东大学胶体与界面化学教育部重点实验室,山东农业大学化学与材料科学学院,山东大学胶体与界面化学教育部重点实验室 济南250100,德州学院化学系德州253023,济南250100,泰安271018,济南250100

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.8,693-696+666

WOS被引数:6

资源类型:期刊论文

WOS:000228513700005

66. 喜树碱/氧化石墨烯/类水滑石纳米杂化物的制备及表征 CSCD SCOPUS SCIE

作者:兀晓文;杜娜;李海平;张人杰;侯万国;

作者机构:[兀晓文] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[杜娜] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[李海平] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[张人杰] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[侯万国] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2014,Vol.72,Issue.8,963-969

WOS被引数:6

资源类型:期刊论文

WOS:000340842200010

67. 端基含4个丁氧基偶氮苯介晶基元光致变色液晶树状物的光化学研究 CSCD SCOPUS SCIE

作者:张其震;刘建强;唐新德;张静智

作者机构:[张其震] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[刘建强] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[唐新德] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[张静智] 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.18,1822-1828

WOS被引数:6

资源类型:期刊论文

WOS:000224063500028

68. Mg-Al-NO_3层状双金属氢氧化物电性质研究 CSCD SCOPUS SCIE

作者:金志琳,侯万国,张春光,孙祉伟,杨亲正,孙德军,戴国亮

作者机构:[金志林] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[侯万国] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[张春光] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[孙祉伟] 中国科学院力学研究所, 国家微重力实验室, 北京 100080, 中国

来源:化学学报,ACTA CHIMICA SINICA,2003,Vol.61,Issue.8,1208-1212

WOS被引数:5

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WOS:000185643800009

69. 稀土(Ⅲ)-冠醚配位反应的热力学性质 Ⅰ.稀土(Ⅲ)高氯酸盐与苯并-15-冠-5在乙腈溶液中配位反应的量热滴定研究 SCIE

作者:刘德谦;蒋本杲;尹敬执;阎海科;

作者机构:[刘德谦;蒋本杲;尹敬执;阎海科]山东大学化学系,山东大学化学系,山东大学,中国科学院化学研究所 济南,济南,兼职教授,北京

来源:化学学报,ACTA CHIMICA SINICA,1990,Vol.48,Issue.5,452-458

WOS被引数:5

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WOS:A1990DL35900007

70. 二硝酸二(N-月桂酰吡咯烷)合铀酰配合物的合成和结构 SCOPUS SCIE

作者:韩景田,包伯荣,孙国新,杨勇,杨永会,陈民勤,孙思修

作者机构:[韩景田,包伯荣,孙国新,杨勇,杨永会,陈民勤,孙思修]中国科学院上海原子核研究所,上海大学理学院,中国科学院上海原子核研究所,复旦大学分析测试中心,山东大学化学学院,复旦大学分析测试中心,山东大学化学学院 上海201800,上海201800,上海201800,上海200433,济南250100,上海200433,济南250100

来源:化学学报,ACTA CHIMICA SINICA,2000,Vol.58,Issue.10,1286-1290

WOS被引数:5

资源类型:期刊论文

WOS:000165207800021

71. 2,4,6-三苯乙烯基均三嗪(TSTA)的结构及其光学性质 CSCD SCOPUS SCIE

作者:崔月芝,方奇,薛刚,于文涛,雷虹,刘志强

作者机构:[崔月芝] 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.;[薛刚] 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.;[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.;[雷虹] 山东大学信息科学与工程学院, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2003,Vol.61,Issue.3,307-311

WOS被引数:5

资源类型:期刊论文

WOS:000182279800001

72. 丙烯酸聚乙二醇酯-甲基丙烯酸共聚物对CaCO_3微粒形貌的调控 CSCD SCOPUS SCIE

作者:王芳,徐桂英,张志庆,肖莉

作者机构:[王芳] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[徐桂英] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[张志庆] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[肖莉] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2003,Vol.61,Issue.9,1488-1491

WOS被引数:5

资源类型:期刊论文

WOS:000188245700028

73. 阴离子型表面活性剂所组成微乳液的异常流变性 SCIE

作者:伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜;

作者机构:[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]青岛化工学院应用化学系;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]青岛化工学院应用化学系;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]青岛化工学院应用化学系;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]青岛化工学院应用化学系;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]山东大学化学系;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]山东大学化学系 青岛 266042;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]青岛 266042;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]青岛 266042;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]青岛 266042;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]济南 250100;[伍世英;陈宗淇;王世权;李莹;袁云龙;张传胜]济南 250100

来源:化学学报,ACTA CHIMICA SINICA,1993,Vol.51,Issue.8,729-735

WOS被引数:5

资源类型:期刊论文

WOS:A1993LX88200001

74. 漆酶在纳米多孔金上的固定化及其酶学性质研究 CSCD SCOPUS SCIE

作者:邱华军[1];徐彩霞[1];姬广磊[1];黄锡荣[1,2];韩书华[1];丁轶[1];曲音波[2]

作者机构:[邱华军] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[徐彩霞] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[姬广磊] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[黄锡荣] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[韩书华] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[丁轶] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[曲音波] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2008,Vol.66,Issue.18,2075-2080

WOS被引数:5

资源类型:期刊论文

WOS:000259904300010

75. 硼氮掺杂的碳纳米管对硫化氢气敏性能的理论研究 CSCD SCOPUS SCIE

作者:王若曦;张冬菊;武剑;刘成卜;

作者机构:[王若曦] 山东大学理论化学研究所, 济南, 山东 250100, 中国.;[张冬菊] 山东大学理论化学研究所, 济南, 山东 250100, 中国.;[武剑] 山东大学理论化学研究所, 济南, 山东 250100, 中国.;[刘成卜] 山东大学理论化学研究所, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2007,Vol.65,Issue.2,107-110

WOS被引数:5

资源类型:期刊论文

WOS:000244172300004

76. 分子导体(PyH)[Ni(dmit)2]2的合成、结构与导电性 CSCD SCOPUS SCIE

作者:许文[1];方奇[1];薛刚[1];于文涛[1];刘国群[1];张德清[2];徐伟[2];徐翠英[2];张金彪[2]

作者机构:[许文] 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.;[薛刚] 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.;[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.;[张德清] 中国科学院化学研究所, 北京 100080, 中国.;[徐伟] 中国科学院化学研究所, 北京 100080, 中国.;[徐翠英] 中国科学院化学研究所, 北京 100080, 中国.;[张金彪] 中国科学院化学研究所, 北京 100080, 中国

来源:化学学报,ACTA CHIMICA SINICA,2002,Vol.60,Issue.12,2153-2158

WOS被引数:5

资源类型:期刊论文

WOS:000179969400013

77. Zn-Al类水滑石零净电荷点及等电点研究 CSCD SCOPUS SCIE

作者:李丽芳,侯万国,戴肖南,刘春霞

作者机构:[李丽芳] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[侯万国] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[戴肖南] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国.;[刘春霞] 山东大学, 胶体与界面化学教育部重点实验室, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2004,Vol.62,Issue.4,429-432+343

WOS被引数:5

资源类型:期刊论文

WOS:000189108900017

78. 一代碳硅烷树枝状大分子钯配合物的液晶性 CSCD SCOPUS SCIE

作者:张其震;殷晓颖;李爱香;王艳

作者机构:[张其震] 山东大学化学化工学院,中国.;[殷晓颖] 山东大学化学化工学院,中国.;[杨爱香] 山东大学化学化工学院,中国.;[王艳] 山东大学环境与工程学院, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.10,934-940+871

WOS被引数:5

资源类型:期刊论文

WOS:000229327000012

79. 用环糊精合成楔筒状主体分子新模型 CSCD SCIE

作者:郝爱友;王金山

作者机构:[郝爱友] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[王金山] 山东师范大学化学系, 济南, 山东 250014, 中国

来源:化学学报,ACTA CHIMICA SINICA,2002,Vol.60,Issue.8,1536-1538+1356

WOS被引数:5

资源类型:期刊论文

WOS:000177641800033

80. 偏分势能面及其应用(Ⅰ):概念、构造方法及几个简例 CSCD SCOPUS SCIE

作者:孙孝敏;王华阳;蔡政亭;冯大诚;边文生

作者机构:[孙孝敏] 山东大学理论化学研究所, 济南, 山东 250100, 中国.;[王华阳] 山东大学理论化学研究所, 济南, 山东 250100, 中国.;[蔡政亭] 山东大学理论化学研究所, 济南, 山东 250100, 中国.;[冯大诚] 山东大学理论化学研究所, 济南, 山东 250100, 中国.;[边文生] 中国科学院化学研究所, 分子反应动力学国家重点实验室, 北京 100080, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.5,372-376

WOS被引数:5

资源类型:期刊论文

WOS:000227653400005

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