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Li++I-2(-), the ab initio potential energy surfaces ( PES) of two electronic states (ionic B-2(2) state and covalent (2)A(1) state) were constructed by use of QCISD (T) method. Minimum energy reaction path on each PES and the crossing curve of the two-state PES were abstracted. According to the results, the most probable crossing radius (R-c(max)) between the ionic and covalent states was determined, and the fine electronic structure on the crossing point was calculated. The electron affinity of I-2 molecule and the dissociation energy of I-2(-) anion and the ionization potential of Li atom obtained from present PES are quite in agreement with the experimental and spectrum data. The ion-pair formation probability was calculated using Landau-Zener formula, and from it the scattering resonance state was found, which is similar to the Na+I-2-->Na++I-2(-) system. [article_dt] => Article [publication_type] => J [begin_page] => 1477 [author_en] => Sun, XM; Zhang, J; Feng, DC; Cai, ZT; Bian, WS [format_cscd_No] => 5c8c1df32c5c6ef5cb61eec17c149eeb-371538329 [volume] => 62 [publisher] => SCIENCE CHINA PRESS [get_data] => 2018-08-29 [keyword_en] => ab initio potential energy surface of two electronic states; ion-pair; formation probability; nonadiabatic coupling; scattering resonance state [page] => 1477-1483 [keyword_plu] => DIFFERENTIAL CROSS-SECTIONS; POTENTIAL-ENERGY SURFACES; SIMPLE CHEMICAL REACTIONS; MONTE CARLO TRAJECTORIES; TRANSITION-STATE REGION; ELECTRON-JUMP MODEL; REACTION-PRODUCTS; CONFIGURATION-INTERACTION; HALOGEN MOLECULES; NUCLEAR REACTIONS [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [publication_iso] => Acta Chim. Sin. [format_title_en_publication_en_pub_year] => 716061a46dbad6900467778d39ee56fc-926233727 [format_title_en] => 431f98da6d1e6c6bc5eeb4ea60eec44d138530212 [publisher_city] => BEIJING [cite_cscd] => 0 [pub_date] => AUG 28 [publication_info] => 0567-7351(2004)62:16<1477:LZDSCF>2.0.TX;2-Z [hx_id] => 2377,2378,2371 [email_c] => zhtcai@sdu.edu.cn [email] => zhtcai@sdu.edu.cn [reference_No] => 61 [format_issn_issue_page_pub_year] => 59aeb44408fbcb73e9c73dfc1d822dc638594057 [cite_awos] => 0 [cscd_No] => CSCD:1670942 [wos_No] => WOS:000223627900005 [format_wos_No] => a704138896afc2a53426b56c5d6b72b51336553184 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [standard_in] => Institute of Theoretical Chemistry, Shandong University, Jinan 250100, China; State Key Laboratory of Molecular Reaction Dynamics, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100080, China [scopus_No] => 2-s2.0-33750435952 [title_en] => Theoretical study of the ion-pair formation process Li+I-2 -> Li++I-2(-): Ab initio PES and reaction probability [format_publication_en] => 169b60c7845c9e5f36906950b18f11111348184734 [jl_language] => chinese [jl_article_dt] => 期刊论文 [jl_author_test] => uirtypical3,upersonid23586,uirtstag0,unameuu5b59u5b5du654f,uuindex0,usureu0,utindex0,uirtag6,uirinspecttag0,uirauthortype0,unameuu5f20u541b,upersonid25489 [jl_publication_en] => actachimicasinica [sys_author_jg_last_arr] => 中国,中国 [jl_keyword_en] => abinitiopotentialenergysurfaceoftwoelectronicstates,nonadiabaticcoupling,formationprobability,ionpair,scatteringresonancestate [sys_author_in_last_arr] => china [jl_publisher] => sciencechinapress [sys_author_id] => [id] => LQkwvmUBFjIhTVEbmrnE [tags] => 0 ) [10] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3252,3254,3243,3241 [tag] => 0 [abstract_cn] => 合成了周边含 4个丁氧基偶氮苯介晶基元 (M 5 )端基新的零代光致变色液晶树状物 (D0 ) ,并用元素分析、核磁共振、基质辅助激光解吸飞行时间质谱、红外、紫外、偏光显微镜、差示扫描量热 (DSC)和广角X射线衍射法 (WAXD)表征 .D0显示向列相 ,与M 5相同 ,树状物相态由介晶基元相态所决定 ,D0的相行为 :K13 8N14 7I14 5N118K .对零代 (D0 )、一代 (D1)、二代 (D2 )和三代 (D3 )液晶树状物的清亮焓、清亮熵、熔化焓和熔化熵进行了比较 [keyword_cn] => 光致变色液晶树状物;向列相;相变焓;相变熵 [article_id] => 490067,26632,661692,249263,330440,629388 [clc] => TQ460 [author_jg] => [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.@@@[李爱香] 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 [format_title_cn_publication_cn_pub_year] => 53ffe2f2c85d41671c63a29ab558062c [hints] => 4 [issue] => 3 [sys_level_num] => 2_3 [sys_jg_type] => 11,10,3,5 [format_issn_issue_page_pub_year] => d62b05b386c7c730a0d73310a709eec1 [source_type] => 351 [pub_year] => 2004 [pub_date] => FEB 14 [pages] => 5 [from_id] => 76,75,73,80,78,85 [author_cn] => 张其震,刘建强,李爱香,张静智 [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-18444364687&partnerID=40&md5=1103e3c904dedaf232724cbef9cc186d [publication_cn] => 化学学报 [title_cn] => 端基含4个丁氧基苯介晶基元光致变色液晶树状物的合成、结构及液晶性研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => a73c67608374f98b52f85cc98150b00f [page] => 312-316 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 4 [fund_No] => 国家自然科学基金; 山东省自然科学基金资助项目 [check_3Y] => 2 [language] => Chinese [delivery_No] => 773BK [format_title] => f06f2e6fe391788d970552a8fcd25578-643096841 [cauthor_ad] => [Zhang, QZ]Shandong Univ, Sch Chem & Chem Engn, Jinan 250100, Peoples R China. [author_fn] => Zhang, QZ; Liu, JQ; Li, AX; Zhang, JZ [reference] => Archut A, 1998, J AM CHEM SOC, V120, P12187, DOI 10.1021/ja9822409@@@@@@BURON DJ, 1980, MOL CRYST LIQ CRYST, V58, P79@@@Busson P, 2001, MACROMOLECULES, V34, P1221, DOI 10.1021/ma992133e@@@CLARK CG, 1999, POLYM PREPR, V40, P484@@@Dardel B, 1999, MACROMOLECULES, V32, P5193, DOI 10.1021/ma990034v@@@@@@Donnil B, 2002, L.Macromolecules, V35, P370@@@GRAY GW, 1984, SMECTIC LIQUID CRYST, P21@@@Hudson SD, 1997, SCIENCE, V278, P449, DOI 10.1126/science.278.5337.449@@@Junge DM, 1999, J AM CHEM SOC, V121, P4912, DOI 10.1021/ja990387+@@@KANG SK, 1985, SYNTHESIS-STUTTGART, P1161@@@LECOIN D, 1975, MOL CRYST LIQ CRYST, V31, P233, DOI@@@10.1080/15421407508082875@@@Lorenz K, 1996, ADV MATER, V8, P414, DOI 10.1002/adma.19960080509@@@MARZOTKO D, 1973, LIQ CRYST P INT C BA, P189@@@Meier H, 1998, ANGEW CHEM INT EDIT, V37, P643, DOI@@@10.1002/(SICI)1521-3773(19980316)37:5<643::AID-ANIE643>3.3.CO;2-W@@@Nagasaki T, 1997, CHEM LETT, P717, DOI 10.1246/cl.1997.717@@@Okaniwa M, 2002, MACROMOLECULES, V35, P6232, DOI 10.1021/ma020388d@@@PERCEC V, 1995, J AM CHEM SOC, V117, P11441, DOI 10.1021/ja00151a008@@@Percec V, 2001, J AM CHEM SOC, V123, P1302, DOI 10.1021/ja0037771@@@SALZ IM, 1999, LIQ CRYST, V26, P1101@@@Stebani U, 1996, ANGEW CHEM INT EDIT, V35, P1858, DOI@@@10.1002/anie.199618581@@@@@@TAJIPER L, 2002, MACROMOLECULES, V35, P8601@@@Wooleg K L, 1993, J. Macromolecules, V26, P1514@@@Wunderlich B, 1988, J.Adv.Polym.Sci., V87, P1@@@[张其震 Zhang Qizhen], 2003, [化学学报, Acta Chemical Sinica], V61, P1478@@@[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 Qizheng], 2003, [高等学校化学学报, Chemical Journal of Chinese@@@Universities], V24, P1704@@@[张其震 Zhang Qizhen], 2003, [化学学报, Acta Chemical Sinica], V61, P619@@@[张其震 Zhang Qizhen], 2003, [化学学报, Acta Chemical Sinica], V61, P1108@@@[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, 1998, 高等学校化学学报, V19, P1175@@@张其震, 1998, 高等学校化学学报, V19, P827@@@张其震, 1997, 高等学校化学学报, V18, P158@@@张其震, 2000, 功能高分子材料 [publication_29] => ACTA CHIM SINICA [end_page] => 316 [abstract_en] => The synthesis of a new photochromic liquid crystalline (LC) dendrimer of the zero generation (DO) is described. Four 4-butoxyazobenzene groups were used as mesogenic fragments and attached in its periphery. Structure and properties of DO were characterized by elemental analysis, H-1 NMR, MALDI-TOF-MS, IR, UV, polarizing optical micrograph, DSC and WAXD. Similar to NE, DO is nematic liquid crystal. The mesomorphic state of dendrimer D0 depends on that of mesogenic units. Phase behavior of D0 in LC state is K138N147I145N118K. The isotropic enthalpy, isotropic entropy, melting enthalpy and melting entropy of the dendrimers of the zero, first, second and third generations were compared. [author_in] => [Zhang, Q.-Z] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Liu, J.-Q] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China, School of Physics and Microelectronics, Shandong University, Jinan 250100, China@@@[ Li, A.-X] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Zhang, J.-Z] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 312 [author_en] => Zhang, QZ; Liu, JQ; Li, AX; Zhang, JZ [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => photochromic liquid crystalline dendrimer; nematic; phase transition; enthalpy and entropy [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => 1ST GENERATION; SUPRAMOLECULAR DENDRIMERS; 2ND-GENERATION [publication_iso] => Acta Chim. Sin. [format_title_en] => 565e8797f1a4019d8c240b56dc2f658a-387125025 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 35 [email] => qzzhang@sdu.edu.cn [cite_awos] => 4 [wos_No] => WOS:000188877700015 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Study on the synthesis, structure and liquid crystalline of a new photochromic liquid crystalline dendrimer containing four 4-butoxyazobenzene mesogenic groups in its periphery [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] => nematic,photochromicliquidcrystallinedendrimer,enthalpyandentropy,phasetransition [jl_keyword_cn] => 光致变色液晶树状物,相变焓,相变熵,向列相 [jl_clc] => tq460 [jl_publisher] => sciencechinapress [company_id] => 133,5,43,169 [sys_subject_sort] => 0,0,0,0 [college_parent_id] => 133,5,43,169 [company_test] => Array,Array,Array,Array [author_id] => [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 刘建强 [irtag] => 7 [t_index] => 0 [person_id] => 22294 ) ) [sys_author_id_arr] => 22294刘建强 [cscd_No] => CSCD:1612569 [jl_publication_cn_publication_en] => 化学学报,actachimicasinica [jl_keyword_cn_keyword_en] => 相变焓,nematic,相变熵,phasetransition,photochromicliquidcrystallinedendrimer,enthalpyandentropy,向列相,光致变色液晶树状物 [sys_author_id] => [format_cscd_No] => a16530c4d3af2a150e1b5c56e54c034e [format_title_en_publication_en_pub_year] => b591e7bba63521cf5e34365c3aa62cce [format_wos_No] => cf218866158ef12e44c05f93cf0d7859 [format_title_en_issn_pub_year] => ebf50696b0b49716524983cde95e37ca [format_scopus_No] => c35b3552077a2d645ed33b66fda3db8a [standard_in] => School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China; School of Physics and Microelectronics, Shandong University, Jinan 250100, China [cauthor] => Zhang, QZ(qzzhang@sdu.edu.cn) [datebase] => Scopus [cite_scopus] => 4 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-18444364687 [jl_pub_year] => 2004 [jl_author_test] => upersonid22294,usureu0,uuindex0,utindex0,uirtag7,uirmagnum0,unameuu5218u5efau5f3a [sys_author_jg_last_arr] => 中国 [jl_company_test] => unameuu5316u5b66u4e0eu5316u5de5u5b66u9662,uorgidu5,uparentidu43,unameuu7269u7406u5b66u9662,uircu0,uorgidu43,ulevelu1,uparentidu5 [sys_author_in_last_arr] => china [id] => zA1FvmUBFjIhTVEbZaRs [tags] => 0 ) [11] => 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] => 4 [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 ) [12] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3241,3254,3243,3252 [tag] => 0 [abstract_cn] => 通过在正十二硫醇自组装单层膜表面制备环氧树脂涂层的方法,在涂层/铜基体界面引入自组装界面层.采用X射线光电子能谱、电化学阻抗谱、阻抗-时间谱和相位角-时间谱等方法对硫醇自组装界面层及其对涂层腐蚀防护性能的影响进行了研究.结果表明,引入的自组装单层可极大地改善涂层的腐蚀防护性能.论文还对自组装单层改善涂层腐蚀防护性能的机理进行了探讨. [keyword_cn] => 正十二硫醇;自组装单层膜;环氧树脂涂层;腐蚀防护性能; [clc] => TG174.46 [author_jg] => [孔燕] 山东大学化学与化工学院, 济南, 山东 250100, 中国.@@@[张树永] 山东大学化学与化工学院, 济南, 山东 250100, 中国.@@@[李红娟] 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] => a997f651c4285905487b1d165c24ad24-1319116939 [from_id] => 76,75,73,80,78,85 [issue] => 17 [sys_level_num] => 2_1 [sys_jg_type] => 5 [source_type] => 351 [pub_year] => 2004 [article_id] => 663308,45673,237896,490036,581871,329267 [pages] => 5 [hints] => 6 [author_cn] => 孔燕[1];张树永[1];李红娟[1] [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33750392134&partnerID=40&md5=8339f0b014f9996c1215671490743a03 [publication_cn] => 化学学报 [title_cn] => 正十二硫醇自组装单层膜改善环氧涂层腐蚀防护性能的研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => dd6daf4b374fc23068887d1eb7967b81-1070534332 [hb_type] => 2 [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 2 [fund_No] => 国家自然科学基金 [check_3Y] => 6 [language] => Chinese [delivery_No] => 853OD [format_title] => b983e3dcacb336829a53c45de37af8ce25625036 [cauthor_ad] => [Kong, Y]Shandong Univ, Sch Chem & Chem Engn, Jinan 250100, Peoples R China. [author_fn] => Kong, Y; Zhang, SY; Li, HJ [reference] => ARIMA M, 1993, REPT PROG POLYM PHYS, V36, P267@@@Chung C, 1999, J ELECTROANAL CHEM, V468, P91, DOI@@@10.1016/S0022-0728(99)00072-8@@@@@@LEE MC, 1993, PROG POLYM SCI, V18, P947@@@Luo XW, 1997, J MACROMOL SCI PURE, VA34, P2279, DOI@@@10.1080/10601329708010047@@@@@@LUO XW, 1995, MACROMOL RAPID COMM, V16, P941, DOI@@@10.1002/marc.1995.030161210@@@@@@MANSFELD F, 1995, J APPL ELECTROCHEM, V25, P187@@@NAKAMURA S, 1993, J THERM ANAL, V40, P613, DOI 10.1007/BF02546631@@@@@@Quan ZL, 2001, CORROS SCI, V43, P1071, DOI 10.1016/S0010-938X(00)00131-1@@@Schmidt R G, 1986, Advance in Polymer Science, Epoxy Resins and@@@COmposites II, P33@@@Ulman A, 1996, CHEM REV, V96, P1533, DOI 10.1021/cr9502357@@@Van Westing E P M, 1994, Corros. Sci., V36, P979@@@Van Westing E P M, 1993, Prog. Org. Coat, V23, P89@@@Zhang SY, 2003, J APPL ELECTROCHEM, V33, P1063, DOI@@@10.1023/A:1026277017947@@@张树永, 1999, 化学学报, V57, P329@@@Zhang SY, 2002, CORROS SCI, V44, P861, DOI 10.1016/S0010-938X(01)00091-9@@@Zhang SY, 1998, J APPL ELECTROCHEM, V28, P1277, DOI@@@10.1023/A:1003430821885@@@@@@Zhang SY, 2000, CORROS SCI, V42, P2037, DOI@@@10.1016/S0010-938X(00)00042-1@@@罗小雯, 1997, 高等学校化学学报, V18, P1719@@@陈月辉, 1995, 化学学报, V53, P328@@@张树永, 1997, 化学通, P31@@@2002, 电化学阻抗谱导论, P154 [publication_29] => ACTA CHIM SINICA [end_page] => 1616 [abstract_en] => By formation of epoxy coating on n-dodecanethiol self-assembled monolayer on copper substrate, self-assembled monolayer was introduced between epoxy coating and copper electrode. The formation of self-assembled interfacial n-dodecanethiol monolayer and its effect on the corrosion protection of epoxy coating were evaluated using the X-ray photoelectronic spectroscopy, electrochemical impedance spectroscopy, impedance-time transition, and phase angle-time transition method. It was found that, the self-assembled interfacial monolayer can improve the corrosion protection of the epoxy coating greatly. The mechanism for the great improvement was discussed. [author_in] => [Kong, Y] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Zhang, S.-Y] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China@@@[ Li, H.-J] School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 1612 [article_dt] => Article [author_en] => Kong, Y; Zhang, SY; Li, HJ [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => polymeric coating; corrosion protection; mechanism; coating/metal; interface; self-assembled monolayer [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => ELECTROCHEMICAL IMPEDANCE SPECTROSCOPY; IN-SITU DETERMINATION; CRESOL NOVOLAC RESIN; WATER SORPTION; MECHANISM; ADHESION; KINETICS [publication_iso] => Acta Chim. Sin. [format_title_en] => 2fbdd6922a5ae39b5e2bb28f8f39e0d0-1393409520 [publisher_city] => BEIJING [pub_date] => SEP 14 [hx_id] => 2377,2378,2371 [reference_No] => 21 [email] => syzhang@sdu.edu.cn [cite_awos] => 4 [wos_No] => WOS:000223836000007 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Study of the effect of n-dodecanethiol self-assembled monolayer on the improvement of corrosion protection of epoxy coating [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] => selfassembledmonolayer,corrosionprotection,coatingmetal,mechanism,interface,polymericcoating [jl_keyword_cn] => 自组装单层膜,环氧树脂涂层,正十二硫醇,,腐蚀防护性能 [jl_clc] => tg17446 [jl_publisher] => sciencechinapress [company_id] => 43,169 [sys_subject_sort] => 0,0 [college_parent_id] => 43,169 [company_test] => Array,Array [author_id] => [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 张树永 [irtag] => 7 [t_index] => 0 [person_id] => 25639 ) ) [sys_author_id_arr] => [cscd_No] => CSCD:1699852 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => 自组装单层膜,selfassembledmonolayer,正十二硫醇,环氧树脂涂层,corrosionprotection,mechanism,interface,腐蚀防护性能,polymericcoating,coatingmetal [sys_author_id] => [format_cscd_No] => b4f60b985a6b1b3e67f39162a2344cdf859532538 [format_title_en_publication_en_pub_year] => 8fdf967c5d8931db576a9a9f918da544-674836496 [format_wos_No] => 3af081030c242b407afc493248b31c16615829180 [format_title_en_issn_pub_year] => c20a6209a8956fba50ad7d79a8a52fcf-743973472 [format_scopus_No] => b98a42963c3caaed4b821f28e910c9f0-819385389 [standard_in] => School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China [datebase] => Scopus [page] => 1612-1616 [cite_scopus] => 3 [format_issn_issue_page_pub_year] => 63d0da60f84eb2dc6eb5fb957d46caee-1202750252 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-33750392134 [id] => UwoyvmUBFjIhTVEbeVMR [tags] => 0 ) [13] => Array ( [batch2] => 1,2,6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-30744475113&partnerID=40&md5=41192113c8e78ad3b92b09c10600c948 [tag] => 0 [abstract_cn] => 用Winsor型相图、δ—γ“鱼状”相图和改进的ε—β“鱼状”相图研究了混合碳链烷基聚葡糖苷 (APG :C8/10 G1.3 1和C12 /14 G1.43 )中相微乳液的相行为 .结果表明 ,随醇浓度的增加 ,微乳液类型发生WinsorI→III→II的转变 .从Winsor型相图直接观察到醇浓度增加时 ,微乳液三种类型的变化、各相体积以及中相微乳液形成和消失时醇的浓度 .从“鱼状”相图除得到中相微乳液形成和消失时的组成 ,以及单相微乳液形成时的组成外 ,还可得到平衡界面膜的组成、表面活性剂单体分子和醇在油相中的溶解度及表面活性剂形成单相微乳液的效能等 .在比较上述两种相图优缺点的基础上 ... [keyword_cn] => 中相微乳液;;“鱼状”相图;;烷基聚葡糖苷;;增溶 [fund_No] => 国家自然科学基金; 贵州省省长基金 [article_id] => 238392,26631,490230,661668,330529,629391 [clc] => O643.3 [author_jg] => [柴金岭] 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.@@@[李东祥] 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.@@@[张高勇] 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.@@@[梁芳珍] 山东师范大学化学系, 济南, 山东 250014, 中国.@@@[夏瑞] 北京药品检验所, 北京 100035, 中国 [format_title_cn_publication_cn_pub_year] => 0a04d40aeb60cc07b4a87d558d55b2081246915773 [hints] => 7 [issue] => 1 [author_first] => 柴金岭 [sys_level_num] => 2_3 [sys_jg_type] => 3,5 [format_issn_issue_page_pub_year] => 7716e832ffa729d82118f2e43a1e9af5-967892851 [source_type] => 351 [pub_year] => 2004 [pub_date] => JAN 14 [pages] => 6 [from_id] => 76,75,73,80,78,85 [author_cn] => 柴金岭;李东祥;李干佐;梁芳珍;张高勇山东大学胶体与界面化学教育部重点实验室;夏瑞 [issn] => 0567-7351 [batch] => 3249,3250,3252,3254,3243,3241 [publication_cn] => 化学学报 [title_cn] => 混合碳链烷基聚葡糖苷中相微乳液的研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => b503bf0de6d435bf4b25e70b03e5283d1045170489 [page] => 47-52 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 11 [check_3Y] => 2 [language] => Chinese [delivery_No] => 762TK [format_title] => 657f146540fe70cb177d80761772af8b-1905565446 [cauthor_ad] => [Chai, JL]Shandong Univ, Minist Educ, Key Lab Colloid & Interface Chem, Jinan 250100, Peoples R China. [author_fn] => Chai, JL; Li, DX; Li, GZ; Liang, FZ; Zhang, GY; Xia, R [reference] => [柴金岭 Chai Jinling], 2002, [化学通报, Chemistry], V65, P506@@@Chai JL, 2003, CHINESE J CHEM, V21, P25@@@Fukuda K, 2001, COLLOID SURFACE B, V20, P129, DOI@@@10.1016/S0927-7765(00)00183-1@@@@@@FUKUDA K, 1993, LANGMUIR, V9, P2921, DOI 10.1021/la00035a032@@@KAHLWEIT M, 1995, LANGMUIR, V11, P3382, DOI 10.1021/la00009a019@@@@@@KAHLWEIT M, 1987, J PHYS CHEM-US, V91, P1553, DOI 10.1021/j100290a052@@@KUNIEDA H, 1995, LANGMUIR, V11, P3302, DOI 10.1021/la00009a006@@@KUNIEDA H, 1985, J COLLOID INTERF SCI, V107, P107, DOI@@@10.1016/0021-9797(85)90154-7@@@Kurt D P, 2000, Nonionic Surfactants: Alkyl Polyglucosides. Surfactant@@@Science Series, Vol. 91@@@Li GZ, 1995, ACTA PHYS-CHIM SIN, V11, P553, DOI 10.3866/PKU.WHXB19950615@@@PENDERS MHGM, 1995, J PHYS CHEM-US, V99, P10313, DOI 10.1021/j100025a037@@@@@@Ryan LD, 2001, COLLOID SURFACE A, V176, P69, DOI@@@10.1016/S0927-7757(00)00614-2@@@李干佐, 1993, 科学通报, V38, P2042@@@李干佐, 1991, 化学物理学报, V4, P296@@@李方, 1996, 化学学报, V54, P1@@@王军, 2001, 烷基多苷及衍生物@@@郝京诚, 1997, 中国科学(B辑), V27, P131 [publication_29] => ACTA CHIM SINICA [end_page] => 52 [abstract_en] => The phase behavior of the middle-phase microemulsion for the quaternary system of the mixed-chain alkyl polyglucoside (C-8/10 APG or C-12/14 APG)/1-butanol/n-octane/water has been studied with Winsor phase diagram, delta-gamma fishlike and modified epsilon-beta fishlike phase diagrams. A series of phase changes Winsor I-->III-->II were observed from above three kinds of phase diagrams with increasing the concentration of alcohol, It was observed from the Winsor phase diagram that the phase types, the phase volumes and the concentrations of alcohol at the start point and end point of the Winsor microemulsion formation change with the increase of the concentration of alcohol. From the delta-gamma fishlike phase diagram, some important parameters were calculated, such as the mass fraction of 1-butanol in the hydrophile-lipophile balanced interfacial layer, A(s), the coordinates of the start point and the end point of the Winsor microemulsion formation, and the solubilities of APG and 1-butanol in n-octane phase. The modified epsilon-beta fishlike phase diagram was presented for the first time by us. With the epsilon-beta fishlike phase diagram, the above experimental phenomena were observed and the physico-chemical parameters were calculated precisely. The epsilon-beta fishlike phase diagram has some advantages over the Winsor and delta-gamma fishlike phase diagrams in visual observations of the phase changes, and calculation of the related physico-chemical parameters. [author_in] => [Chai, J.-L] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan 250100, China, Department of Chemistry, Shandong Normal University, Jinan 250014, China@@@[ Li, D.-X] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan 250100, China@@@[ Li, G.-Z] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan 250100, China@@@[ Liang, F.-Z] Department of Chemistry, Shandong Normal University, Jinan 250014, China@@@[ Zhang, G.-Y] Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan 250100, China@@@[ Xia, R] Beijing Municipal Institute of Drug Controls, Beijing 100035, China [publication_type] => J [begin_page] => 47 [author_en] => Chai, JL; Li, DX; Li, GZ; Liang, FZ; Zhang, GY; Xia, R [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => middle-phase microemulsion; fishlike phase diagram; alkyl polyglucoside;; solubilization [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => GLYCEROL ETHER; BEHAVIOR; SYSTEMS; SURFACTANTS [publication_iso] => Acta Chim. Sin. [format_title_en] => 1db85632938bc923976cb234e5915152-1543514454 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 17 [email] => coliw@sdu.edu.cn [cite_awos] => 16 [wos_No] => WOS:000187998100010 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Studies on the middle-phase microemulsions of alkyl polyglucosides with mixed hydrocarbon chain [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] => ,middlephasemicroemulsion,alkylpolyglucoside,solubilization,fishlikephasediagram [jl_keyword_cn] => ,鱼状相图,增溶,烷基聚葡糖苷,中相微乳液 [jl_clc] => o6433 [jl_publisher] => sciencechinapress [company_id] => 0,43,169 [author_id] => 25398 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 5 [name] => 张国艳 [irtag] => 7 [t_index] => 0 [person_id] => 25398 ) ) [sys_author_id_arr] => [cscd_No] => CSCD:1512178 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => 鱼状相图,solubilization,中相微乳液,middlephasemicroemulsion,增溶,烷基聚葡糖苷,fishlikephasediagram,alkylpolyglucoside [sys_author_id] => [format_cscd_No] => 827cc9d9bddcf023ff6aecc92b464f51-1880333689 [format_title_en_publication_en_pub_year] => 5ec49a2bfd5426a67629896066b45d5c-52340373 [format_wos_No] => 7de5565e81b162ef4f02ca9cb93cef34583655459 [format_title_en_issn_pub_year] => f510fa03368cd5e01554fb4ec74d85ff251112082 [datebase] => Scopus [format_scopus_No] => ff0433967aa3b3cfe39884e50471aa13-1890847460 [cite_scopus] => 12 [sys_priority_field] => 76 [standard_in] => Key Laboratory for Colloid and Interface Chemistry, Ministry of Education, Shandong University, Jinan 250100, China; Department of Chemistry, Shandong Normal University, Jinan 250014, China; Beijing Municipal Institute of Drug Controls, Beijing 100035, China [scopus_No] => 2-s2.0-30744475113 [sys_subject_sort] => 0,0 [college_parent_id] => 43,169 [company_test] => Array,Array [id] => zw1FvmUBFjIhTVEbZaRs [tags] => 0 ) [14] => Array ( [batch2] => 1,2,6 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-26844529868&partnerID=40&md5=76a59e5c985aaed05df12d743f220d7e [tag] => 0 [abstract_cn] => 利用聚合物大分子作构建组分 ,将其掺杂到不同类型表面活性剂构成的溶致液晶中 ,考察对液晶相结构的影响 .利用小角X射线散射及偏光显微镜对聚合物掺杂前后液晶的结构进行表征 ,并讨论了聚合物与液晶模板间的相互作用 .对阴离子型表面活性剂琥珀酸二异辛酯磺酸钠 (AOT) /水液晶体系 ,聚合物的嵌入使层间距d增大 ;而对非离子表面活性剂十二烷基聚氧乙烯醚 (C1 2 EO4) /水体系 ,除小分子量的聚乙二醇PEG40 0外 ,其它聚合物嵌入使d减小 ,表明聚合物分子类型、大小及浓度对溶致液晶的结构参数甚至组装方式有不同的影响机制 [keyword_cn] => 表面活性剂;;溶致液晶;;聚合物;;掺杂;;小角X射线散射 [fund_No] => 国家自然科学基金; 高等学校博士点专项科研基金; 山东省优秀中青年科学家奖励基金 [article_id] => 554770,329712,490126,237928,68522,661464 [clc] => O636 [author_jg] => [王庐岩] 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.@@@[陈晓] 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.@@@[庄文昌] 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.@@@[赵继宽] 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.@@@[隋震鸣] 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.@@@[柴永存] 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] => b153490438cc0dfa131e278ccb88b2e5-1427381590 [hints] => 4 [issue] => 11 [author_first] => 王庐岩 [sys_level_num] => 2_3 [sys_jg_type] => 10,5 [format_issn_issue_page_pub_year] => 6c8797c80ae6424a8008cac69417aa112082109966 [source_type] => 351 [pub_year] => 2004 [pub_date] => JUN 14 [pages] => 7 [from_id] => 76,75,73,80,78,85 [author_cn] => 王庐岩;陈晓;庄文昌;赵继宽;隋震鸣;柴永存 [issn] => 0567-7351 [batch] => 3249,3250,3252,3254,3243,3241 [publication_cn] => 化学学报 [title_cn] => 掺杂聚合物对溶致液晶结构的影响 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 953f3ed62e97b34a5b46da014bd821481151109805 [page] => 1007-1013+1003 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 2 [check_3Y] => 5 [language] => Chinese [delivery_No] => 828IN [format_title] => 01bf47fa850decb3ae8c15f2ee0a4c331794081149 [cauthor_ad] => [Wang, LY]Shandong Univ, Key Lab Colloid & Interface Chem, Minist Educ, Jinan 250100, Peoples R China. [author_fn] => Wang, LY; Chen, X; Zhuang, WC; Zhao, JK; Sui, ZM; Chai, YC [reference] => Alexandridis P, 1998, LANGMUIR, V14, P2627, DOI 10.1021/la971117c@@@ALEXANDRIDIS P, 1995, COLLOID SURFACE A, V96, P1, DOI@@@10.1016/0927-7757(94)03028-X@@@Attard GS, 1998, ACTA MATER, V46, P751, DOI@@@10.1016/S1359-6454(97)00256-5@@@Bechthold N, 1999, J COLLOID INTERF SCI, V215, P106, DOI@@@10.1006/jcis.1999.6199@@@@@@BOLTENHAGEN P, 1991, J PHYS II, V1, P1233@@@[陈伟 Chen Wei], 2003, [生物医学工程学杂志, Journal of Biomedical Engineering],@@@V20, P143@@@Chen X, 2001, SCI CHINA SER B, V44, P492, DOI 10.1007/BF02880679@@@Coleman NRB, 2001, MICROPOR MESOPOR MAT, V44, P73, DOI@@@10.1016/S1387-1811(01)00170-6@@@@@@Feng PY, 2000, LANGMUIR, V16, P5304, DOI 10.1021/la991444f@@@Ficheux MF, 1997, COLLOID SURFACE A, V123, P253, DOI@@@10.1016/S0927-7757(96)03802-2@@@FICHEUX MF, 1995, J PHYS II, V5, P823, DOI 10.1051/jp2:1995167@@@Firestone MA, 2001, NANO LETT, V1, P129, DOI 10.1021/nl0155025@@@Firestone MA, 2003, BIOMACROMOLECULES, V4, P1539, DOI 10.1021/bm034134r@@@Freyssingeas E, 1999, Eur.Phys.J.B, V9, P133@@@Hentze HP, 2003, CURR OPIN COLLOID IN, V8, P164, DOI@@@10.1016/S1359-0294(03)00018-9@@@Hentze HP, 2001, CURR OPIN SOLID ST M, V5, P343, DOI@@@10.1016/S1359-0286(01)00008-0@@@Huang LM, 2002, ADV MATER, V14, P61, DOI@@@10.1002/1521-4095(20020104)14:1<61::AID-ADMA61>3.3.CO;2-P@@@Israelachvili J, 1997, P NATL ACAD SCI USA, V94, P8378, DOI@@@10.1073/pnas.94.16.8378@@@Ivanova R, 2000, LANGMUIR, V16, P9058, DOI 10.1021/la000373d@@@Ivanova R, 2000, LANGMUIR, V16, P3660, DOI 10.1021/la991235v@@@@@@Javierre I, 2001, LANGMUIR, V17, P5417, DOI 10.1021/la010167l@@@Johnsson M, 2001, LANGMUIR, V17, P3902, DOI 10.1021/la0101245@@@JORGENSEN HB, 1997, LANGMUIR, V13, P4204@@@Liang HJ, 2003, J AM CHEM SOC, V125, P11786, DOI 10.1021/ja036529o@@@Minewaki K, 2001, LANGMUIR, V17, P1864, DOI 10.1021/la000791i@@@Ponsinet V, 1996, J PHYS CHEM-US, V100, P5035, DOI 10.1021/jp952828r@@@@@@Qi LM, 1999, COLLOID SURFACE A, V157, P285, DOI@@@10.1016/S0927-7757(99)00053-9@@@@@@Ramos L, 1996, J PHYS CHEM-US, V100, P4533, DOI 10.1021/jp951920k@@@Ruppelt D, 1997, LANGMUIR, V13, P3316, DOI 10.1021/la9610258@@@@@@Yang BS, 2001, LANGMUIR, V17, P5834, DOI 10.1021/la001391y@@@Yang BS, 2001, LANGMUIR, V17, P6692, DOI 10.1021/la0105533@@@ZHANG KW, 1995, J PHYS CHEM-US, V99, P9130, DOI 10.1021/j100022a027@@@@@@郭荣, 2000, 化学学报, V58, P1196@@@赵继宽, 2003, 化学进展, V15, P451 [publication_29] => ACTA CHIM SINICA [end_page] => 1013 [abstract_en] => Fabrication of polymer or polymer-modified nanomaterials templated by lyotropic liquid crystals (LLC) is a promising way to obtain expected nanostructured functional materials. However, the structures of LLC are easy to be changed by environmental conditions. Therefore, investigation on interactions between polymers (or monomers) and LLC templates is significant for better controlling the structures and properties of nanomaterials. In this paper, polymers are doped into lyotropic lamellar liquid crystals formed with different types of surfactants. Effects of doped components on the phase behaviors of the lamellae are investigated in detail by small angle X-ray scattering and polarized optical microscope. In LLC made of anionic surfactant, sodium bis(2-ethylhexyl) sulfosuccinate (AOT), and water, doped polymers induce a swelling lamellar phase and an increased periodic spacing. While in LLC made of nonionic surfactant, tetraethylene glycol monododecyl ether (C12EO4), and water, polymer doping results in more orderly phase and a reduced interlayer spacing, with an exception of a low molecular weight polymer (PEG400). Results show that interactions between doped polymers and LLC vary with types and sizes of polymer molecules and also doping concentrations, which strongly influence the phase structures. Obtained results are helpful for designing suitable LLC templates and controlling the structures of expected nanomaterials. [author_in] => [Wang, L.-Y] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Ministry of Education, Jinan 250100, China@@@[ Chen, X] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Ministry of Education, Jinan 250100, China@@@[ Zhuang, W.-C] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Ministry of Education, Jinan 250100, China@@@[ Zhao, J.-K] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Ministry of Education, Jinan 250100, China@@@[ Sui, Z.-M] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Ministry of Education, Jinan 250100, China@@@[ Chai, Y.-C] Key Laboratory of Colloid and Interface Chemistry, Shandong University, Ministry of Education, Jinan 250100, China [publication_type] => J [begin_page] => 1007 [author_en] => Wang, LY; Chen, X; Zhuang, WC; Zhao, JK; Sui, ZM; Chai, YC [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => surfactant; lyotropic liquid crystal; polymer; doping; small angle X-ray; scattering [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => OXIDE) BLOCK-COPOLYMER; X-RAY-SCATTERING; LAMELLAR PHASE; SILVER NANOPARTICLES; MICELLAR-SOLUTIONS; WATER; SYSTEM; TERNARY; NANOSTRUCTURES; SOLVENTS [publication_iso] => Acta Chim. Sin. [format_title_en] => 5e3b6453c35127ccaa7fc09436d17fa2733503048 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 34 [email] => xchen@sdu.edu.cn [cite_awos] => 2 [wos_No] => WOS:000221967100001 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Effects of doped polymers on the phase behaviors of lyotropic liquid crystals [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] => surfactant,polymer,smallanglexray,doping,scattering,lyotropicliquidcrystal [jl_keyword_cn] => ,小角x射线散射,掺杂,溶致液晶,表面活性剂,聚合物 [jl_clc] => o636 [jl_publisher] => sciencechinapress [company_id] => 0,0,0,0,0 [author_id] => 20324,20322 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 2 [name] => 陈曦 [irtag] => 7 [t_index] => 0 [person_id] => 20322 ) [1] => Array ( [sure] => 1 [irmagnum] => 0 [u_index] => 2 [name] => 陈晓 [sys_author_id] => Array ( [0] => 20324 ) [irtag] => 0 [t_index] => 0 [person_id] => 20324 ) ) [sys_author_id_arr] => 20324陈晓 [cscd_No] => CSCD:1657209 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => surfactant,溶致液晶,polymer,小角x射线散射,掺杂,表面活性剂,smallanglexray,聚合物,doping,scattering,lyotropicliquidcrystal [sys_author_id] => 20324 [format_cscd_No] => eacdba24ca8e68901e4b6b26f5f5ae91-249143597 [format_title_en_publication_en_pub_year] => d1a15a794f687acb222cd1e2f40b77a226809580 [format_wos_No] => 71518fe2fa91261e261abdcbe1f19395-74286718 [format_title_en_issn_pub_year] => f5ede05d5788a8c3e69cbf476aadb4ff-963617359 [datebase] => Scopus [format_scopus_No] => 3d88f9e6d96e888e936a6c122fe6371338404839 [cite_scopus] => 1 [sys_priority_field] => 76 [standard_in] => Key Laboratory of Colloid and Interface Chemistry, Shandong University, Ministry of Education, Jinan 250100, China [scopus_No] => 2-s2.0-26844529868 [id] => og5JvmUBFjIhTVEbudND [tags] => 0 ) [15] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3241,3254,3243,3252 [tag] => 0 [abstract_cn] => 采用动态光散射法研究了电解质对Mg-A1类水滑石(HTlc)溶胶聚集动力学行为的影响,发现随惰性电解质(NaCl,NaNO3)浓度的增大,Mg-A1 HTlc溶胶经历稳定、慢速聚集和快速聚集三个区域,而特性吸附电解质(NaOH)在所研究的浓度范围(0~4 mmol/L)内未观察到快速聚集.NaCl和NaNO3的临界聚沉浓度分别为127和180mmol/L,慢速聚集区稳定比与NaCl,NaNO3和NaOH浓度间的关系式分别为:logW=10.18-4.44logC,logW=11.98-4.79logC,logW=1.92-0.74logC.NaOH诱导体系聚集的能力大大高于NaCl和NaNO3. [keyword_cn] => 电解质;聚集动力学;动态光散射;镁-铝类水滑石溶胶; [clc] => O648.16 [author_jg] => [金志琳] 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.@@@[孙德军] 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.@@@[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.@@@[戴国亮] 中国科学院力学研究所, 国家微重力实验室, 北京 100080, 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 [format_title_cn_publication_cn_pub_year] => 2e021aa5301160d79a27144004ac3908-102966725 [from_id] => 76,75,73,80,78,85 [issue] => 20 [sys_level_num] => 2_1 [sys_jg_type] => 10,5 [source_type] => 351 [pub_year] => 2004 [article_id] => 45675,490188,661635,329313,554755,238400 [pages] => 5 [hints] => 5 [author_cn] => 金志琳 [1];侯万国 [1];戴国亮 [2];孙德军 [1];张春光 [1];孙祉伟 [2] [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33750488151&partnerID=40&md5=853cf79bc3d06104a1fd29a57b673b6c [publication_cn] => 化学学报 [title_cn] => 电解质对Mg-Al HTlc溶胶聚集动力学行为的影响 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => b076911927cb821cb0394066ad9bd0ab-258532916 [hb_type] => 2 [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 1 [fund_No] => 教育部跨世纪人才基金资助项目; 国家自然科学基金 [check_3Y] => 3 [language] => Chinese [delivery_No] => 867JZ [format_title] => 2a200e09ccd7d39b9196b05769269b79-1382962991 [cauthor_ad] => [Jin, ZL]Shandong Univ, Key Lab Colloid & Interface Chem, Educ Minist, Jinan 250100, Peoples R China. [author_fn] => Jin, ZL; Hou, WG; Dai, GL; Sun, DJ; Zhang, CG; Sun, ZW [reference] => ALBISTON L, 1996, J MATER CHEM, V6, P71@@@AMAL R, 1990, COLLOID SURFACE, V46, P1, DOI 10.1016/0166-6622(90)80045-6@@@Aurell C., 2000, COLLOID SURF A, V168, P277, DOI DOI@@@10.1016/S0927-7757(00)00488-X@@@BROWN JC, 1975, J CHEM PHYS, V62, P1136, DOI 10.1063/1.430557@@@Brown W, 1993, Dynamic Light Scattering@@@CAMETTI C, 1989, J COLLOID INTERF SCI, V131, P409, DOI@@@10.1016/0021-9797(89)90183-5@@@@@@Costantino U, 1998, J. Inorg. Chem, V10, P1439@@@Hiemenz P C, 1997, Principles of Colloid and Surface Chemistry(3rd ed)@@@Holthoff H, 1996, LANGMUIR, V12, P5541, DOI 10.1021/la960326e@@@Hou W.G., 2001, LANGMUIR, V17, P1885@@@Israelachvili J N, 1985, Intermolevular and surface forces with@@@applications to colloidal and biological systems@@@[金志林 Jin Zhilin], 2003, [化学学报, Acta Chemical Sinica], V61, P1208@@@Kim AY, 2000, LANGMUIR, V16, P2101, DOI 10.1021/la990841n@@@@@@PESIC L, 1992, J MATER CHEM, V2, P1069, DOI 10.1039/jm9920201069@@@PRIEVE DC, 1980, J COLLOID INTERF SCI, V73, P539, DOI@@@10.1016/0021-9797(80)90100-9@@@@@@SPIELMAN LA, 1970, J COLLOID INTERF SCI, V33, P562, DOI@@@10.1016/0021-9797(70)90008-1@@@@@@Stumm W, 1981, J. Aquatic Chemistry: An Introduction Emphasizing@@@Chemical Equilibria in Natural Waters, 2nd ed@@@VIRDEN JW, 1992, J COLLOID INTERF SCI, V149, P528, DOI@@@10.1016/0021-9797(92)90439-S@@@von Smoluchowski, 1917, Phys. Chem, V92, P129@@@李淑萍, 2001, 高等学校化学学报, V22, P1173@@@侯万国, 1995, 高等学校化学学报, V16, P1292@@@经春光, 1993, 钻井液与完井液, V10, P1 [publication_29] => ACTA CHIM SINICA [end_page] => 2029 [abstract_en] => Colloidal stability and aggregation kinetics of the Mg-Al HTlc dispersion were investigated at various electrolyte concentrations by dynamic light scattering (DL-S). It was found that the Mg-Al HTlc dispersions go through mostly stable, slow aggregating and fast aggregating stages in turn with the increase of the inertia electrolyte concentration ( NaCl, NaNO3), while those phenomena do not occur in the dispersions with various NaOH concentrations (0 similar to 4 mmol/L) in our studies. The critical electrolyte concentrations of NaCl and NaNO3 for this MgAl HT1c dispersion are found to be 127 and 180 mmol/L respectively. The relations between the stability ratio and the concentration of NaCl, NaNO3 and NaOH in the slow aggregating stage have been measured to be log W = 10.18 - 4.44logC, logW = 11.98 - 4.79logC and logW = 1.92 - 0.74logC, respectively. The aggregation of this dispersion has been induced much more easily by NaOH than by NaCl or NaNO3. [author_in] => [Jin, Z.-L] Key Laboratory for Colloid and Interface Chemistry of Education Ministry, Shandong University, Jinan 250100, China@@@[ Hou, W.-G] Key Laboratory for Colloid and Interface Chemistry of Education Ministry, Shandong University, Jinan 250100, China@@@[ Dai, G.-L] National Microgravity Laboratory, Institute of Mechanics, Chinese Academy of Sciences, Beijing 100080, China@@@[ Sun, D.-J] Key Laboratory for Colloid and Interface Chemistry of Education Ministry, Shandong University, Jinan 250100, China@@@[ Zhang, C.-G] Key Laboratory for Colloid and Interface Chemistry of Education Ministry, Shandong University, Jinan 250100, China@@@[ Sun, Z.-W] National Microgravity Laboratory, Institute of Mechanics, Chinese Academy of Sciences, Beijing 100080, China [publication_type] => J [begin_page] => 2025 [article_dt] => Article [author_en] => Jin, ZL; Hou, WG; Dai, GL; Sun, DJ; Zhang, CG; Sun, ZW [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => aggregation kinetics; dynamic light scattering (DLS); zeta-potential;; hydrotalcite-like compound (HTlc) [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => PHOTON-CORRELATION; LIGHT-SCATTERING; COAGULATION; AGGREGATION; HYDROXIDE; PARTICLES [publication_iso] => Acta Chim. Sin. [format_title_en] => 05e8549e06e3d1892f5bf93258dc7675-1852976608 [publisher_city] => BEIJING [pub_date] => OCT 28 [hx_id] => 2377,2378,2371 [reference_No] => 23 [email] => wghou@sdu.edu.cn [cite_awos] => 2 [wos_No] => WOS:000224840200011 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Effect of electrolytes on kinetic behavior of colloidal dispersions of Mg-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] => ,aggregationkinetics,dynamiclightscatteringdls,hydrotalcitelikecompoundhtlc,zetapotential [jl_keyword_cn] => ,镁铝类水滑石溶胶,聚集动力学,电解质,动态光散射 [jl_clc] => o64816 [jl_publisher] => sciencechinapress [company_id] => [author_id] => 21153,23456 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 侯万国 [irtag] => 7 [t_index] => 0 [person_id] => 21153 ) [1] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 孙德军 [irtag] => 7 [t_index] => 0 [person_id] => 23456 ) ) [sys_author_id_arr] => 21153侯万国,23456孙德军 [cscd_No] => CSCD:1810934 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => hydrotalcitelikecompoundhtlc,聚集动力学,aggregationkinetics,动态光散射,镁铝类水滑石溶胶,zetapotential,dynamiclightscatteringdls,电解质 [sys_author_id] => 21153,23456 [format_cscd_No] => 17100b1eefc478324bb2991159de7708-88972987 [format_title_en_publication_en_pub_year] => 8ed3d748b06bf0deb8f5bae56bf674c61002573814 [format_wos_No] => 2d489b968d6ac723d561a28c987c8612315481241 [format_title_en_issn_pub_year] => 1b79e079c4c666f571859e7019a07179-962206880 [datebase] => Scopus [format_scopus_No] => c62d748401fd249ae7e84a55b2c84854-1497267786 [page] => 2025-2029 [cite_scopus] => 3 [format_issn_issue_page_pub_year] => b4d20db3077a05d4f3a9a7157f3977ee1086015112 [sys_priority_field] => 76 [standard_in] => Key Laboratory for Colloid and Interface Chemistry of Education Ministry, Shandong University, Jinan 250100, China; National Microgravity Laboratory, Institute of Mechanics, Chinese Academy of Sciences, Beijing 100080, China [scopus_No] => 2-s2.0-33750488151 [id] => VQoyvmUBFjIhTVEbeVMR [tags] => 0 ) [16] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3241,3254,3243,3252 [tag] => 0 [abstract_cn] => 从炼油厂污水排放口取得的土样中筛选到一株能降解二苯并噻吩(DBT)的菌株,用GC/MS方法,证明其降解DBT走硫专一脱除途径,即\\\'4S途径\\\'.该菌株被命名为SDUZAWQ,用微生物生理生化实验及16S rDNA序列分析初步鉴定为红球菌属(Rhodococcus sp.).实验结果表明,红球菌SDUZAWQ可有效降解苯并噻吩(BT)和DBT及其甲基衍生物.在2 d内,BT与DBT可同时完全降解,0.5 mmol·L-1的BT在1 d内可降解掉86%,降解速度高于DBT的降解.5-MBT的降解率也高于4,6-DMDBT和4-MDBT.4-MDBT较4,6-DMDBT更难降解,在2 d内,红球菌SDUZAWQ可降解62%的4,6-DMDBT,而相同条件下,4-MDBT仅能被降解36%. [keyword_cn] => 红球菌;脱硫菌株;脱硫特性;二苯并噻吩;化石燃料; [clc] => TQ517 Q939 [author_jg] => [马翠卿] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.@@@[于波] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.@@@[曾义勇] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.@@@[冯进辉] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.@@@[李福利] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.@@@[许平] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.@@@[佟友] 中国石油化工股份有限公司抚顺石油化工研究院, 抚顺, 辽宁 113001, 中国.@@@[方向晨] 中国石油化工股份有限公司抚顺石油化工研究院, 抚顺, 辽宁 113001, 中国.@@@[张全] 中国石油化工股份有限公司抚顺石油化工研究院, 抚顺, 辽宁 113001, 中国 [format_title_cn_publication_cn_pub_year] => 69c0ac168915020c949e75156fca4169 [from_id] => 76,75,73,80,78,85 [issue] => 19 [sys_level_num] => 2_1 [sys_jg_type] => 8,5,0,8,8 [source_type] => 351 [pub_year] => 2004 [article_id] => 45674,490197,581867,329296,661671,238384 [pages] => 6 [hints] => 6 [author_cn] => 马翠卿 [1];佟明友 [2];于波 [1];曾义勇 [1];方向晨 [2];冯进辉 [1];张全 [2];李福利 [1];许平 [1] [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33645834002&partnerID=40&md5=ec5225910af020c4f27dcdb2fc335d6b [publication_cn] => 化学学报 [title_cn] => 一株红球菌脱硫菌株脱硫特性的研究 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 0e14dbd2633e16d123073cef0555316a [hb_type] => 2 [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 4 [fund_No] => 国家自然科学基金项目; 中国石油化工股份有限公司重点项目; 国家十五科技攻关项目 [check_3Y] => 4 [language] => Chinese [delivery_No] => 863BZ [format_title] => 5cca99cfe7f1e2167f8d3e34133831f11539479235 [cauthor_ad] => [Ma, CQ]Shandong Univ, State Key Lab Microbial Technol, Jinan 250100, Peoples R China. [author_fn] => Ma, CQ; Tong, MY; Yu, B; Zeng, YY; Fang, XC; Feng, JH; Zhang, Q; Li, FL; Xu, P [reference] => Constani M, 1994, Microbiol Biotechnol., V10, P510@@@CRAWFORD DL, 1990, CURR MICROBIOL, V21, P229, DOI 10.1007/BF02092161@@@Folsom BR, 1999, APPL ENVIRON MICROB, V65, P4967@@@Gilbert SC, 1998, MICROBIOL-UK, V144, P2545, DOI@@@10.1099/00221287-144-9-2545@@@Gou ZX, 2002, SCI CHINA SER B, V45, P521, DOI 10.1360/02yb9069@@@@@@Grossman M J, 2001, J.Appl.Environ.Microbiol., V67, P1949@@@Grossman MJ, 1999, APPL ENVIRON MICROB, V65, P181@@@Kilbane II J J, 1992, Chem.Abstr., V115, P154959@@@Kobayashi M, 2000, FEMS MICROBIOL LETT, V187, P123, DOI@@@10.1111/j.1574-6968.2000.tb09147.x@@@Konishi J, 2000, FEMS MICROBIOL LETT, V187, P151, DOI@@@10.1111/j.1574-6968.2000.tb09152.x@@@Konishi J, 2000, FEMS Microbiol.Lett., V187, P123@@@Matsui T, 2000, BIOSCI BIOTECH BIOCH, V64, P596, DOI 10.1271/bbb.64.596@@@McFarland BL, 1999, CURR OPIN MICROBIOL, V2, P257, DOI@@@10.1016/S1369-5274(99)80045-9@@@MONTICELLO DJ, 1985, ANNU REV MICROBIOL, V39, P371, DOI@@@10.1146/annurev.mi.39.100185.002103@@@Monticello DJ, 2000, CURR OPIN BIOTECH, V11, P540, DOI@@@10.1016/S0958-1669(00)00154-3@@@Ohshiro T, 1999, BIOSCI BIOTECH BIOCH, V63, P1, DOI 10.1271/bbb.63.1@@@Ohshiro T, 1996, Ferment. Bioeng., V81, P121@@@Oldfield C, 1997, MICROBIOL-UK, V143, P2961, DOI@@@10.1099/00221287-143-9-2961@@@OMORI T, 1995, BIOSCI BIOTECH BIOCH, V59, P1195, DOI 10.1271/bbb.59.1195@@@@@@Reichmuth K S, 2000, Biotechnol.Bioeng, V67, P72@@@Rhee SK, 1998, APPL ENVIRON MICROB, V64, P2327@@@Setti L, 1999, APPL MICROBIOL BIOT, V52, P111, DOI 10.1007/s002530051496@@@@@@Tanaka Y, 2002, APPL MICROBIOL BIOT, V59, P325, DOI@@@10.1007/s00253-002-0985-9@@@Tanaka Y, 2001, CURR MICROBIOL, V43, P187, DOI 10.1007/s002840010285@@@Wang P, 1996, APPL ENVIRON MICROB, V62, P1670@@@Xu P, 2002, CHINESE SCI BULL, V47, P1077, DOI 10.1360/02tb9242@@@Xu P, 2001, Appl.Microbiol.Biotechnol, V57, P460 [publication_29] => ACTA CHIM SINICA [end_page] => 1888 [abstract_en] => A strain named SDUZAWQ was isolated from soil contaminated by waste water of a refinery. Using GC/MS method, the strain was determined to biodesulfurize dibenzothiophene (DBT) via a sulfur-specific pathway, as so-called \"4S pathway\". This culture was identified as Rhodococcus sp. based on a partial 16S rDNA gene sequence and physiological and biochemical methods. Rhodococcus sp. SDUZAWQ can effectively desulfurize benzo[b]thiophene (BT), DBT and their derivatives. In two days, BT and DBT were degraded completely and 86% of BT was desulfurized in 24 h with the degrading rate being higher than that of DBT. The rate of 5-methyl-benzo[b]thiophene (5-MBT) was also higher than those of DBT derivatives, 4,6-dimethyldibenzothiophene (4,6-DMDBT) and 4-methyldibenzothiophene (4-MDBT). The degradation of 4-MDBT was more refractory than that of 4,6-DMDBT. In 48 h 62% of 4,6-DMDBT was degraded, but only 36% of 4-MDBT was desulfurized under the same conditions. [researcherID] => Li, Fu-Li/B-5894-2015; Unciano, Noel/B-6810-2009; Yu, Bo/A-9467-2008 [orcID] => Li, Fu-Li/0000-0003-0381-2234; Yu, Bo/0000-0003-3148-0986; Ma,; Cuiqing/0000-0002-7468-1027 [author_in] => [Ma, C.-Q] State Key Laboratory of Microbial Technology, Shandong University, Jinan 250100, China@@@[ Tong, M.-Y] Fushun Research Institute of Petroleum and Petrochemicals, SINOPEC, Fushun 113001, China@@@[ Yu, B] State Key Laboratory of Microbial Technology, Shandong University, Jinan 250100, China@@@[ Zeng, Y.-Y] State Key Laboratory of Microbial Technology, Shandong University, Jinan 250100, China@@@[ Fang, X.-C] Fushun Research Institute of Petroleum and Petrochemicals, SINOPEC, Fushun 113001, China@@@[ Feng, J.-H] State Key Laboratory of Microbial Technology, Shandong University, Jinan 250100, China@@@[ Zhang, Q] Fushun Research Institute of Petroleum and Petrochemicals, SINOPEC, Fushun 113001, China@@@[ Li, F.-L] State Key Laboratory of Microbial Technology, Shandong University, Jinan 250100, China@@@[ Xu, P] State Key Laboratory of Microbial Technology, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 1883 [article_dt] => Article [author_en] => Ma, CQ; Tong, MY; Yu, B; Zeng, YY; Fang, XC; Feng, JH; Zhang, Q; Li, FL; Xu, P [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => dibenzothiophene; benzo [b] thiophene; biodesulfurization; metabolic; pathway [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => HYDRODESULFURIZED MIDDLE DISTILLATE; MICROBIAL DESULFURIZATION; DIBENZOTHIOPHENE; BENZOTHIOPHENE; OIL; ERYTHROPOLIS; BACTERIUM; EXPRESSION; PETROLEUM; PATHWAY [publication_iso] => Acta Chim. Sin. [format_title_en] => 5a6eaefdebe5a7579a6374c96cd62049-2004946215 [publisher_city] => BEIJING [pub_date] => OCT 14 [hx_id] => 2377,2378,2371 [reference_No] => 27 [email] => pingxu@sdu.edu.cn [cite_awos] => 7 [wos_No] => WOS:000224536500006 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Biodesulfurization of organic sulfur by a newly isolated Rhodococcus sp strain SDUZAWQ [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] => pathway,biodesulfurization,metabolic,dibenzothiophene,benzobthiophene [jl_keyword_cn] => 红球菌,脱硫特性,脱硫菌株,化石燃料,二苯并噻吩 [jl_clc] => tq517q939 [jl_publisher] => sciencechinapress [company_id] => [author_id] => 22744 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 马翠卿 [irtag] => 7 [t_index] => 0 [person_id] => 22744 ) ) [sys_author_id_arr] => [cscd_No] => CSCD:1689298 [jl_publication_cn_publication_en] => 化学学报,actachimicasinica [jl_keyword_cn_keyword_en] => 红球菌,脱硫菌株,metabolic,biodesulfurization,化石燃料,dibenzothiophene,脱硫特性,benzobthiophene,二苯并噻吩,pathway [sys_author_id] => [format_cscd_No] => 36471a71e79665df709f52cf303eca39 [format_title_en_publication_en_pub_year] => 4bfd5bacc6fdfc8600524690b864297e [format_wos_No] => ce65252e926908756b1a64c2a8116a49 [format_title_en_issn_pub_year] => d4d08e9bb1dc88a088fc6d10b713c712 [format_scopus_No] => 37b3e8b5875c909c0181c6340a4e5e6d [standard_in] => State Key Laboratory of Microbial Technology, Shandong University, Jinan 250100, China; Fushun Research Institute of Petroleum and Petrochemicals, SINOPEC, Fushun 113001, China [datebase] => Scopus [page] => 1883-1888 [cite_scopus] => 4 [format_issn_issue_page_pub_year] => 7f1605bb22054bd6b810efd680d2becd [sys_priority_field] => 76 [scopus_No] => 2-s2.0-33645834002 [jl_pub_year] => 2004 [jl_author_test] => usureu0,unameuu9a6cu7fe0u537f,uuindex0,upersonid22744,utindex0,uirtag7,uirmagnum0 [sys_author_jg_last_arr] => 中国 [sys_author_in_last_arr] => china [id] => VAoyvmUBFjIhTVEbeVMR [tags] => 0 ) [17] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3252,3254,3243,3241 [tag] => 0 [abstract_cn] => 合成了一种新的导电分子晶体 (PyMe) [Ni(dmit) 2 ] 2 (Py =pyridine ,dmit =(C3 S5) 2 -=4,5 dimercapto 1,3 dithiole 2 thio nato) ,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 7483 7( 9)nm ,b =1 15 479( 16)nm ,c =1 9775 ( 3 )nm ,α =99 2 68( 12 )° ,β =99 14 0 ( 10 )° ,γ =99 673 ( 11)° ;V =1 63 2 0 ( 4 )nm3 ,Dc=... [keyword_cn] => 分子导体;合成;结构;导电性 [article_id] => 490046,329868,238388,661700,554778,68523 [clc] => O657.3 [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.@@@[雷虹] 山东大学信息科学与工程学院, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => f71fb4c81e733f2a1a5681cdb3614878-177070849 [hints] => 11 [issue] => 6 [sys_level_num] => 2_3 [sys_jg_type] => 3,5 [format_issn_issue_page_pub_year] => 031e61190bd69c2c77ce1970e97488271342737324 [source_type] => 351 [pub_year] => 2004 [pub_date] => MAR 28 [pages] => 6 [from_id] => 76,75,73,80,78,85 [author_cn] => 许文,方奇,薛刚,于文涛,刘国群,雷虹 [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33750474901&partnerID=40&md5=9e3868410fa1e152525cf0e06e4aa988 [publication_cn] => 化学学报 [title_cn] => 分子导体(Py Me)[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] => d93f76394a5fa915dc62099c1d353bd8-1217582845 [page] => 587-592+533 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 0 [fund_No] => 国家自然科学基金 [check_3Y] => 3 [language] => Chinese [delivery_No] => 806MF [format_title] => 2c053a5d7453d933072b9c044b305a061273333861 [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; Lei, H [reference] => ALVAREZ S, 1985, J AM CHEM SOC, V107, P6253, DOI 10.1021/ja00308a018@@@BOUSSEAU M, 1986, J AM CHEM SOC, V108, P1908, DOI 10.1021/ja00268a032@@@Cassoux P, 1999, COORDIN CHEM REV, V185-6, P213, DOI@@@10.1016/S0010-8545(98)00272-0@@@CORNELISSEN JP, 1992, J CHEM SOC DALTON, P2911, DOI 10.1039/dt9920002911@@@Fang Q, 2002, J CHEM SOC DALTON, P1377, DOI 10.1039/b105854c@@@KATO R, 1988, SYNTHETIC MET, V27, pB359@@@Kobayashi A, 1987, Chem. Lett.@@@Liu G Q, 2003, Spectrochim. Acta. Part A, pin press@@@MIYAZAKI A, 1992, B CHEM SOC JPN, V65, P2528, DOI 10.1246/bcsj.65.2528@@@@@@Schlueter JA, 1999, COORDIN CHEM REV, V190, P781, DOI@@@10.1016/S0010-8545(99)00121-6@@@@@@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@@@@@@[许文 Xu Wen], 2002, [化学学报, Acta Chemical Sinica], V60, P2153@@@Xu W, 2001, SYNTHETIC MET, V122, P409, DOI 10.1016/S0379-6779(00)00405-7@@@许文, 2003, 中国科学, V33 [publication_29] => ACTA CHIM SINICA [end_page] => 592 [abstract_en] => A new molecular conductor (PyMe) [Ni(dmit)(2)](2)(Py = pyridine, dmit = (C3S5)(2-) =4,5-dimercapto-1,3-dithiole-2-thionato) has been synthesized and its structure determined by four-circle X-ray diffraction analysis. Crystallographic parameters for (PyMe) [Ni(dmit)(2)](2): triclinic system, P-1 space group; a = 0.74837 (9) nm, b = 1.15479(16) nm, c = 1.9775(3) nm, alpha = 99.268(12)degrees, beta = 99.140(10)degrees, gamma = 99.673(11)degrees; V = 1.6320(4) nm(3), D-c = 2.029 g/cm(3), Z = 2. Structure analysis reveals that four-fold [Ni(dmit)(2)](0.5-) units stack to form columns along [- 110] direction, and these columns further form 2-D conducting sheet by (SS)-S-... intermolecular contacts. The conductivity on (001) plane is measured to be 10(-1) similar to 10(-4) Omega(-1) (.) cm(-1). The relationship between conductivity and structure was discussed based on the structure parameters and intermolecular orbital overlap. [orcID] => Liu, Guoqun/0000-0002-3342-5780 [author_in] => [Xu, W] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China, School of Chemistry and Chemical Engineering, 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@@@[ 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@@@[ Lei, H] School of Information Science and Engineering, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 587 [author_en] => Xu, W; Fang, Q; Xue, G; Yu, WT; Liu, GQ; Lei, H [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => molecular conductor; synthesis; structure; conductivity [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => ELECTRICAL-CONDUCTIVITY; CRYSTAL-STRUCTURES; METAL; TRANSITION [publication_iso] => Acta Chim. Sin. 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[keyword_cn] => 体块TiO2多孔纳米固体;比表面积;强制交换方法;降解作用 [article_id] => 329106,249094,489986,82209,661739,539400 [clc] => O647.2 [author_jg] => [刘秀琳] 山东大学, 晶体材料国家重点实验室,中国.@@@[徐红燕] 山东大学, 晶体材料国家重点实验室,中国.@@@[李梅] 山东大学, 晶体材料国家重点实验室,中国.@@@[蒋民华] 山东大学, 晶体材料国家重点实验室,中国.@@@[崔得良] 山东大学, 晶体材料国家重点实验室,中国.@@@[余丽丽] 山东大学物理与微电子学院, 济南, 山东 250100, 中国.@@@[王成建] 山东大学物理与微电子学院, 济南, 山东 250100, 中国 [format_title_cn_publication_cn_pub_year] => 39a2229ed6739de1d6f0d2e7a2e171e6-259962841 [hints] => 10 [issue] => 24 [sys_level_num] => 2_3 [sys_jg_type] => 10,5 [format_issn_issue_page_pub_year] => 7be75816b6e4e21fe2f9ecc74116e6901300303874 [source_type] => 351 [pub_year] => 2004 [pub_date] => DEC 28 [pages] => 5 [from_id] => 76,75,73,80,78,85 [author_cn] => 刘秀琳,余丽丽,徐红燕,李梅,王成建,蒋民华,崔得良 [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33244476361&partnerID=40&md5=3ebbdfecb54aa1cf944570681a7b0e8b [publication_cn] => 化学学报 [title_cn] => TiO_2多孔纳米固体对罗丹明B的热催化降解作用 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 2040cd380678d9223ee078e63ba6dd4a-1101385966 [page] => 2398-2402+2366 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 3 [fund_No] => 国家自然科学基金; 教育部科学技术研究重点项目; 博士点基金 [check_3Y] => 6 [language] => Chinese [delivery_No] => 883BB [format_title] => 6f912aeef04581c80c3b129565c8eed01672441944 [cauthor_ad] => [Cui, DL]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Liu, XL; Yu, LL; Xu, HY; Li, M; Wang, CJ; Jiang, MH; Cui, DL [reference] => Awati PS, 2003, CATAL COMMUN, V4, P393, DOI@@@10.1016/S1566-7367(03)00092-X@@@Chen DW, 1998, WATER RES, V32, P3223, DOI 10.1016/S0043-1354(98)00118-3@@@Chen J, 1999, WATER RES, V33, P661, DOI 10.1016/S0043-1354(98)00261-9@@@Coronado JM, 2003, J CATAL, V219, P219, DOI@@@10.1016/S0021-9517(03)00199-4@@@DOLIVEIRA JC, 1990, ENVIRON SCI TECHNOL, V24, P990, DOI@@@10.1021/es00077a007@@@@@@Fernandez A, 1995, APPL CATAL B-ENVIRON, V7, P49, DOI@@@10.1016/0926-3373(95)00026-7@@@Fujishima A., 1992, NATURE, V37, P238@@@HARADA K, 1990, WATER RES, V24, P1415, DOI 10.1016/0043-1354(90)90162-Y@@@Hidaka H, 1997, J PHOTOCH PHOTOBIO A, V109, P165, DOI@@@10.1016/S1010-6030(97)00137-8@@@@@@HIDAKA H, 1992, J PHYS CHEM-US, V96, P2226, DOI 10.1021/j100184a037@@@@@@HOFFMANN MR, 1995, CHEM REV, V95, P69, DOI 10.1021/cr00033a004@@@HOFSTADLER K, 1994, ENVIRON SCI TECHNOL, V28, P670, DOI@@@10.1021/es00053a021@@@MATTHEWS RW, 1987, J PHYS CHEM-US, V91, P3328, DOI 10.1021/j100296a044@@@Molinari A, 2000, J MOL CATAL A-CHEM, V158, P521, DOI@@@10.1016/S1381-1169(99)00446-X@@@OLLIS D F, 1991, Environmental Science and Technology, V25, P1523@@@Peill NJ, 1996, ENVIRON SCI TECHNOL, V30, P2806, DOI 10.1021/es960047d@@@Ranjit KT, 1998, J PHYS CHEM B, V102, P9397, DOI 10.1021/jp982694s@@@Ray AK, 1998, CATAL TODAY, V40, P73, DOI 10.1016/S0920-5861(97)00123-5@@@ROSS H, 1994, SOL ENERG MAT SOL C, V33, P475, DOI@@@10.1016/0927-0248(94)90007-8@@@[孙静 Sun Jing], 2003, [化学学报, Acta Chemical Sinica], V61, P74@@@WATANABE T, 1977, J PHYS CHEM-US, V81, P1845, DOI 10.1021/j100534a012@@@Xu H, Mater. Lett.@@@Zhang BL, 2003, APPL CATAL B-ENVIRON, V40, P253@@@谢晶曦, 1987, 红外光谱在有机化学和药物化学中的应用, P41 [publication_29] => ACTA CHIM SINICA [end_page] => 2402 [abstract_en] => Using bulk TiO2 porous nanosolids and Rhodamine B (RhB) as the starting materials, TiO2/RhB composite was synthesized by assembling RhB into the channels of TiO2 porous nanosolids. The properties of the composite were characterized by scanning electron microscopy, mercury intrusion porosimetry, Fourier transformation infrared spectroscopy and visible light absorption spectroscopy. The results showed that the specific surface area and major pore radius distribution of TiO2 porous nanosolids were 60.6 m(2)/g and 5 - 13 nm, respectively. In addition, the catalytic effect of TiO2 porous nanosolids on the degradation of RhB was also investigated in this paper. It was found that, the catalytic efficiency of TiO2 porous nanosolids was affected by both temperature and time of exchange process. [author_in] => [Liu, X.-L] State Key Laboratory of Crystal Materials, School of Physics and Microelectronics, Shandong University, Jinan 250100, China@@@[ Yu, L.-L] School of Physics and Microelectronics, Shandong University, Jinan 250100, China@@@[ Xu, H.-Y] State Key Laboratory of Crystal Materials, School of Physics and Microelectronics, Shandong University, Jinan 250100, China@@@[ Li, M] State Key Laboratory of Crystal Materials, School of Physics and Microelectronics, Shandong University, Jinan 250100, China@@@[ Wang, C.-J] School of Physics and Microelectronics, Shandong University, Jinan 250100, China@@@[ Jiang, M.-H] State Key Laboratory of Crystal Materials, School of Physics and Microelectronics, Shandong University, Jinan 250100, China@@@[ Cui, D.-L] State Key Laboratory of Crystal Materials, School of Physics and Microelectronics, Shandong University, Jinan 250100, China [publication_type] => J [begin_page] => 2398 [author_en] => Liu, XL; Yu, LL; Xu, HY; Li, M; Wang, CJ; Jiang, MH; Cui, DL [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => bulk TiO2 porous nanosolid; specific surface area; exchange process;; degradation [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => PHOTOCATALYTIC PROCESSES; NANOCRYSTALLINE TIO2; WATER-PURIFICATION; TITANIUM-DIOXIDE; PHOTODEGRADATION; SUSPENSIONS; OXIDATION; REACTOR; SURFACE; DECOMPOSITION [publication_iso] => Acta Chim. Sin. [format_title_en] => 7c61f34e21a98d53499f223e780aa5161561958329 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 24 [email] => cuidl@sdu.edu.en [cite_awos] => 3 [wos_No] => WOS:000225983900006 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Degradation of RhB catalyzed by TiO2 bulk porous nanosolids [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] => ,specificsurfacearea,degradation,bulktio2porousnanosolid,exchangeprocess [jl_keyword_cn] => 强制交换方法,比表面积,降解作用,体块tio2多孔纳米固体 [jl_clc] => o6472 [jl_publisher] => sciencechinapress [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 [author_id] => 21790,21791,21792,20439 [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] => 李梅 [irtag] => 7 [t_index] => 0 [person_id] => 21790 ) [2] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 李梅 [irtag] => 7 [t_index] => 0 [person_id] => 21791 ) [3] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 李梅 [irtag] => 7 [t_index] => 0 [person_id] => 21792 ) ) [sys_author_id_arr] => 20439崔得良 [cscd_No] => CSCD:1791545 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => specificsurfacearea,体块tio2多孔纳米固体,degradation,比表面积,强制交换方法,exchangeprocess,bulktio2porousnanosolid,降解作用 [sys_author_id] => 20439 [format_cscd_No] => 6261d90911c006011094edd6cae4df4d-1300979711 [format_title_en_publication_en_pub_year] => 43c13e4951437d0391badf3a45763b19-1897170165 [format_wos_No] => 9cb9c4bc7d550a6d9066370455d336401636562967 [format_title_en_issn_pub_year] => 25e58ae017949fa03e04895b4dfa5011109000335 [format_scopus_No] => 8a923b4b8a7c631abf33dec22bbc640a-1634367685 [standard_in] => State Key Laboratory of Crystal Materials, School of Physics and Microelectronics, Shandong University, Jinan 250100, China; School of Physics and Microelectronics, Shandong University, Jinan 250100, China [datebase] => Scopus [cite_scopus] => 3 [sys_priority_field] => 76 [scopus_No] => 2-s2.0-33244476361 [id] => 9A9KvmUBFjIhTVEbYAQa [tags] => 0 ) [19] => Array ( [batch2] => 1,2,6 [batch] => 3249,3250,3252,3254,3243,3241 [tag] => 0 [abstract_cn] => 采用扩展休克尔 -紧束缚方法 (EHTB)研究了ET类分子导体 [ET =bis (ethylenedithio) tetrathiafulvalene]的能带 .讨论了硫原子 3d轨道对能带结构的影响 ,添加 3d轨道导致ET分子柱间的横向作用大为增强 ,并与纵向作用处于同一数量级 ,这一结论解释了晶体二维导电性的实验结果 .计算得到 (ET) 2 C3 H5SO3 ·H2 O ,(ET) 2 HgCl3 ·TCE两个晶体的带隙分别为0 5 79,0 .5 72eV ,与实验得到的导电激活能 0 .3 19,0 .3 0 8eV符合较好 . [keyword_cn] => 能带结构;ET类分子导体;导电性 [article_id] => 238391,490057,45672,661567,629390,330531 [clc] => O641.1 [author_jg] => [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.@@@[方奇] 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 [format_title_cn_publication_cn_pub_year] => 1ebfe94ecc0cc4299432021ba6e25c9a-665964868 [hints] => 11 [issue] => 1 [sys_level_num] => 2_3 [sys_jg_type] => 3,5 [format_issn_issue_page_pub_year] => 3d22fd7003a38fab7d55cae49590c3f31656327777 [source_type] => 351 [pub_year] => 2004 [pub_date] => JAN 14 [pages] => 6 [from_id] => 76,75,73,80,78,85 [author_cn] => 刘国群,雷虹,方奇 [issn] => 0567-7351 [uri] => https://www.scopus.com/inward/record.uri?eid=2-s2.0-33750386741&partnerID=40&md5=8a64a5646c3c507ca3a3437a5714093e [publication_cn] => 化学学报 [title_cn] => ET类分子导体3d轨道对晶体能带及导电性的影响 [CSSN] => 31-1320/O6 [SYS_TAG] => 3 [format_title_cn_issn_pub_year] => 23468cf034b267688d3fba6250215351-1991568721 [page] => 10-15 [hb_type] => 2 [article_dt] => Article [hb_batch] => title_cn_publication_cn_pub_year_2_3 [publication_en] => ACTA CHIMICA SINICA [cite_wos] => 0 [fund_No] => 国家自然科学基金; 教育部高等学校骨干教师基金资助项目 [check_3Y] => 3 [language] => Chinese [delivery_No] => 762TK [format_title] => d54f2a7e33da5f847431b795a9434714-134163010 [cauthor_ad] => [Fang, Q]Shandong Univ, State Key Lab Crystal Mat, Jinan 250100, Peoples R China. [author_fn] => Liu, GQ; Lei, H; Fang, Q [reference] => BERLINSKY AJ, 1976, SOLID STATE COMMUN, V19, P1165, DOI@@@10.1016/0038-1098(76)90810-3@@@@@@BERLINSKY AJ, 1974, SOLID STATE COMMUN, V15, P795, DOI@@@10.1016/0038-1098(74)90666-8@@@COFFEN DL, 1971, J AM CHEM SOC, V93, P2258, DOI 10.1021/ja00738a028@@@@@@FERRARIS J, 1973, J AM CHEM SOC, V95, P948, DOI 10.1021/ja00784a066@@@KOBAYASHI H, 1983, CHEM LETT, P581, DOI 10.1246/cl.1983.581@@@Liu Z, 2003, CHINESE CHEM LETT, V14, P433@@@Mori T, 1998, B CHEM SOC JPN, V71, P2509, DOI 10.1246/bcsj.71.2509@@@MORI T, 1984, B CHEM SOC JPN, V57, P627, DOI 10.1246/bcsj.57.627@@@Mori T, 1999, B CHEM SOC JPN, V72, P179, DOI 10.1246/bcsj.72.179@@@MORI T, 1984, CHEM LETT, P957, DOI 10.1246/cl.1984.957@@@UNDERWOOD DJ, 1985, J AM CHEM SOC, V107, P5968, DOI 10.1021/ja00307a023@@@WANG HH, 1992, MATER RES SOC SYMP P, V247, P471@@@WHANGBO MH, 1982, SOLID STATE COMMUN, V43, P637, DOI@@@10.1016/0038-1098(82)90480-X@@@@@@WHANGBO MH, 1985, J AM CHEM SOC, V107, P5815, DOI 10.1021/ja00306a047@@@@@@WILLIAMS DR, 1971, J CHEM SOC B, P312, DOI 10.1039/j29710000312@@@@@@WILLIAMS JM, 1990, INORG CHEM, V29, P3272, DOI 10.1021/ic00343a003@@@@@@刘陟, 2000, 化学学报, V58, P1567 [publication_29] => ACTA CHIM SINICA [end_page] => 15 [abstract_en] => Energy band of ET-type molecular conductors were calculated using the Extended Huckel-Tight Binding method (EHTB). The introducing of sulfur 3d orbitals to the EHTB calculation leads to a great enhancement of the transverse interactions between ET stacks. Consequently, the transverse and longitudinal interactions in the ET stacks have the same order of magnitude. The results could well explain the two-dimensional conductivity nature of this kind of molecular conductors. Calculated band gaps of the (ET)(2)C3H5SO3 . H2O and (ET)(2)HgCl3 . TCE crystals are 0. 579 and 0. 572 eV respectively, which were in good agreement with the experimental conductive activation energy 0. 319 and 0. 308 eV. [orcID] => Liu, Guoqun/0000-0002-3342-5780 [author_in] => [Liu, G.-Q] State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China@@@[ Lei, H] School of Information Science and Engineering, 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 [publication_type] => J [begin_page] => 10 [author_en] => Liu, GQ; Lei, H; Fang, Q [volume] => 62 [get_data] => 2018-08-29 [publisher] => SCIENCE CHINA PRESS [keyword_en] => energy band structure; ET-type molecular conductor; electrical; conductivity [format_publication_cn] => 6918be3b26b1fa6ec0424f6071208a75331227575 [keyword_plu] => ORGANIC SUPERCONDUCTOR; STRUCTURAL GENEALOGY; TTF; TRANSITION; TCNQ [publication_iso] => Acta Chim. Sin. [format_title_en] => 61ebf88bd3aad1a5ce925527d2d8a016-689620017 [publisher_city] => BEIJING [hx_id] => 2377,2378,2371 [reference_No] => 17 [email] => fangqi@icm.sdu.edu.cn [cite_awos] => 0 [wos_No] => WOS:000187998100003 [wos_sub] => Chemistry, Multidisciplinary [research_area] => Chemistry [check_180] => 0 [publisher_ad] => 16 DONGHUANGCHENGGEN NORTH ST, BEIJING 100717, PEOPLES R CHINA [title_en] => Influence of 3d orbital on the energy band and electrical conductivity in ET-type molecular conductor [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] => ettypemolecularconductor,energybandstructure,electrical,conductivity [jl_keyword_cn] => 能带结构,et类分子导体,导电性 [jl_clc] => o6411 [jl_publisher] => sciencechinapress [company_id] => 24,151,142,43,169,15 [sys_subject_sort] => 0,0,0,0,0,0 [college_parent_id] => 24,151,15,43,169,142 [company_test] => Array,Array,Array,Array,Array,Array [author_id] => 20672 [author_test] => Array ( [0] => Array ( [sure] => 0 [irmagnum] => 0 [u_index] => 0 [name] => 方奇 [irtag] => 7 [t_index] => 0 [person_id] => 20672 ) ) [sys_author_id_arr] => 20672方奇 [cscd_No] => CSCD:1512042 [jl_publication_cn_publication_en] => actachimicasinica,化学学报 [jl_keyword_cn_keyword_en] => 能带结构,导电性,et类分子导体,energybandstructure,ettypemolecularconductor,electrical,conductivity [sys_author_id] => 20672 [format_cscd_No] => 1a314a643bd90c1bce6c8c2c05989fad1171698285 [format_title_en_publication_en_pub_year] => 1832014fcd7cbbf62784d0b4a761ce2a-1551182550 [format_wos_No] => 36f33762122bba569227471c42282bca-1562672936 [format_title_en_issn_pub_year] => dc43ddc0ca1d0c74273ececc77d24797-669005679 [format_scopus_No] => 15ac84b1fc7fc3da99688cfa56c8bc141183681486 [standard_in] => State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100, China; School of Information Science and Engineering, Shandong University, Jinan 250100, China; School of Chemistry and Chemical Engineering, Shandong University, Jinan 250100, China [datebase] => Scopus [sys_priority_field] => 76 [scopus_No] => 2-s2.0-33750386741 [id] => zg1FvmUBFjIhTVEbZaRs [tags] => 0 ) ) 1-->
81. 三代碳硅烷光致变色液晶树状物的光化学研究——端基含108个4-丁氧基偶氮苯介晶基元 CSCD SCOPUS SCIE

作者:张其震,殷晓颖,王艳

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

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.10,941-946+872

WOS被引数:2

资源类型:期刊论文

WOS:000229327000013

82. 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

83. 银纳米粒子表面油酸盐吸附的分子模拟 CSCD SCOPUS SCIE

作者:杨春杰;陈晓;赵继宽;刘成卜

作者机构:[杨春杰] 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.;[陈晓] 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.;[赵继宽] 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,2005,Vol.63,Issue.8,769-773+669

WOS被引数:3

资源类型:期刊论文

WOS:000228513700019

84. 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

85. 聚合氯化铝中Al_(13)形态的分离纯化方法及特性 CSCD SCOPUS SCIE

作者:高宝玉,孔春燕,岳钦艳,王晓娜,初永宝,王曙光

作者机构:[高宝玉] 山东大学环境科学与工程学院, 济南, 山东 250100, 中国.;[岳钦艳] 山东大学环境科学与工程学院, 济南, 山东 250100, 中国.;[王晓娜] 山东大学环境科学与工程学院, 济南, 山东 250100, 中国.;[初永宝] 山东大学环境科学与工程学院, 济南, 山东 250100, 中国.;[王曙光] 山东大学环境科学与工程学院, 济南, 山东 250100, 中国.;[孔春燕] 德州学院化学系, 德州, 山东 253023, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.18,1671-1675+1636

WOS被引数:1

资源类型:期刊论文

WOS:000232089800007

86. 支型长链均三嗪衍生物的合成与光谱性质 CSCD SCOPUS SCIE

作者:尹磊;方奇;崔月芝

作者机构:[尹磊] 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.;[崔月芝] 山东轻工业学院化工系, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.23,85-90

资源类型:期刊论文

WOS:000233813100015

87. 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

88. 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

89. 两个具有强双光子荧光的有机硼化合物 CSCD SCOPUS SCIE

作者:曹笃霞;刘志强;王东;方奇

作者机构:[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.;[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.;[王东] 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

来源:化学学报,ACTA CHIMICA SINICA,2005,Vol.63,Issue.15,44-49

WOS被引数:3

资源类型:期刊论文

WOS:000231163200007

90. 离子对生成反应Li+I2→Li^++I2^-的理论研究:从头算势能面和反应几率 CSCD SCOPUS SCIE

作者:孙孝敏 [1];张君 [1];冯大诚 [1];蔡政亭 [1];边文生 [2]

作者机构:[孙孝敏 ;张君 ;冯大诚 ;蔡政亭 ]山东大学理论化学研究所,济南,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,2004,Vol.62,Issue.16,1477-1483

资源类型:期刊论文

WOS:000223627900005

91. 端基含4个丁氧基苯介晶基元光致变色液晶树状物的合成、结构及液晶性研究 CSCD SCOPUS SCIE

作者:张其震,刘建强,李爱香,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.;[李爱香] 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.3,312-316

WOS被引数:4

资源类型:期刊论文

WOS:000188877700015

92. 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

93. 正十二硫醇自组装单层膜改善环氧涂层腐蚀防护性能的研究 CSCD SCOPUS SCIE

作者:孔燕[1];张树永[1];李红娟[1]

作者机构:[孔燕] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[张树永] 山东大学化学与化工学院, 济南, 山东 250100, 中国.;[李红娟] 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.17,1612-1616

WOS被引数:2

资源类型:期刊论文

WOS:000223836000007

94. 混合碳链烷基聚葡糖苷中相微乳液的研究 CSCD SCOPUS SCIE

作者:柴金岭;李东祥;李干佐;梁芳珍;张高勇山东大学胶体与界面化学教育部重点实验室;夏瑞

作者机构:[柴金岭] 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.;[李东祥] 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.;[张高勇] 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.;[梁芳珍] 山东师范大学化学系, 济南, 山东 250014, 中国.;[夏瑞] 北京药品检验所, 北京 100035, 中国

来源:化学学报,ACTA CHIMICA SINICA,2004,Vol.62,Issue.1,47-52

WOS被引数:11

资源类型:期刊论文

WOS:000187998100010

95. 掺杂聚合物对溶致液晶结构的影响 CSCD SCOPUS SCIE

作者:王庐岩;陈晓;庄文昌;赵继宽;隋震鸣;柴永存

作者机构:[王庐岩] 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.;[陈晓] 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.;[庄文昌] 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.;[赵继宽] 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.;[隋震鸣] 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.;[柴永存] 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.11,1007-1013+1003

WOS被引数:2

资源类型:期刊论文

WOS:000221967100001

96. 电解质对Mg-Al HTlc溶胶聚集动力学行为的影响 CSCD SCOPUS SCIE

作者:金志琳 [1];侯万国 [1];戴国亮 [2];孙德军 [1];张春光 [1];孙祉伟 [2]

作者机构:[金志琳] 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.;[孙德军] 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.;[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.;[戴国亮] 中国科学院力学研究所, 国家微重力实验室, 北京 100080, 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,2004,Vol.62,Issue.20,2025-2029

WOS被引数:1

资源类型:期刊论文

WOS:000224840200011

97. 一株红球菌脱硫菌株脱硫特性的研究 CSCD SCOPUS SCIE

作者:马翠卿 [1];佟明友 [2];于波 [1];曾义勇 [1];方向晨 [2];冯进辉 [1];张全 [2];李福利 [1];许平 [1]

作者机构:[马翠卿] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.;[于波] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.;[曾义勇] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.;[冯进辉] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.;[李福利] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.;[许平] 山东大学, 微生物技术国家重点实验室, 济南, 山东 250100, 中国.;[佟友] 中国石油化工股份有限公司抚顺石油化工研究院, 抚顺, 辽宁 113001, 中国.;[方向晨] 中国石油化工股份有限公司抚顺石油化工研究院, 抚顺, 辽宁 113001, 中国.;[张全] 中国石油化工股份有限公司抚顺石油化工研究院, 抚顺, 辽宁 113001, 中国

来源:化学学报,ACTA CHIMICA SINICA,2004,Vol.62,Issue.19,1883-1888

WOS被引数:4

资源类型:期刊论文

WOS:000224536500006

98. 分子导体(Py Me)[Ni(dmit)_2]_2的合成、结构与导电性 CSCD SCOPUS SCIE

作者:许文,方奇,薛刚,于文涛,刘国群,雷虹

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.;[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,2004,Vol.62,Issue.6,587-592+533

资源类型:期刊论文

WOS:000220437300011

99. TiO_2多孔纳米固体对罗丹明B的热催化降解作用 CSCD SCOPUS SCIE

作者:刘秀琳,余丽丽,徐红燕,李梅,王成建,蒋民华,崔得良

作者机构:[刘秀琳] 山东大学, 晶体材料国家重点实验室,中国.;[徐红燕] 山东大学, 晶体材料国家重点实验室,中国.;[李梅] 山东大学, 晶体材料国家重点实验室,中国.;[蒋民华] 山东大学, 晶体材料国家重点实验室,中国.;[崔得良] 山东大学, 晶体材料国家重点实验室,中国.;[余丽丽] 山东大学物理与微电子学院, 济南, 山东 250100, 中国.;[王成建] 山东大学物理与微电子学院, 济南, 山东 250100, 中国

来源:化学学报,ACTA CHIMICA SINICA,2004,Vol.62,Issue.24,2398-2402+2366

WOS被引数:3

资源类型:期刊论文

WOS:000225983900006

100. ET类分子导体3d轨道对晶体能带及导电性的影响 CSCD SCOPUS SCIE

作者:刘国群,雷虹,方奇

作者机构:[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.;[方奇] 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,2004,Vol.62,Issue.1,10-15

资源类型:期刊论文

WOS:000187998100003

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