Click here to load reader
Upload
trinhkiet
View
279
Download
9
Embed Size (px)
Citation preview
4
15
24
30
35
38
41
43
46
48
50
53
55
56
58
60
61
65
69
71
73
75
79
81
83
85
86
87
89
91
93
95
97
98
99
100
102
103
104
105
106
107
108
109
111
112
114
116
118
119
120
121
122
123
125
126
127
1964-198520002005
[1] 99035199971
[2] 9909010199970.25
[3] 200026200072
[4] 20011024200178
[5] 20021221
[6] \20030332003122.255-2
[7] 200370.64-2
[8] 200411.5
[9] 5053410020058205-3
[10] 2057505720058265-1
[11] 20051031200578
[12] SPR20055014200577.5
[13] 20045037200516
[14] 2008Q9200810.94-2
[15] 2008k10200810.86-4
[16] -2008k22008115-2
[17] 2008110
[18] /2009011015-12009188-1
[19] 21175085201186010-1
[20] 2137508320138858-1
[21] 201340
[22] 1312013100
[23] i-motif DNA20140202015135-2
[24] 201510420151038-2
[25] Cd2+Cu2+Hg2+2015025201510107-2
[26] i-motif DNA201502320151058-2
[27] i-motif DNA20151792015335-2
[28] MSN201615
[1] 19884(2)24-26
[2] 4-19895(2)88-90
[3] Didls-Alder 19942(2)67-72
[4] 199410(2)69-72
[5] 199410(3)14-16
[6] 2-1199511(3)86-90
[7] 1995(3)291
[8] 1995(2)76-80
[9] ()19957(4)82
[10] 199511(3)31-34
[11] 1997(S1)124-128
[12] 2-1199713(5)26-28
[13] 19971328-29
[14] 2-2199814(5)46-48
[15] 3-1199915(3)24 -27
[16] 3-1L-(+)-2,3-0-200021(4)552-555
[17] 200019(1)88-92
[18] 2-1200016(4)93-94
[19] 3-33,4--2-1,4--5,7 200016(3)48-50
[20] 200117(5)21-23
[21] (2-2). A Sensitive Optode Membrane for Berberine Using Conjugated Polymer as Sensing Material. Analytical Sciences, 2002, 18(10): 1111-1115.
[22] 2-1200218(2)22-25
[23] 7-1200324(12)2189-2191
[24] 2-1200319(3)1-5
[25] (3-1, ). Flow injection renewable drops spectrofluorimetry for sequential determinations of Vitamins B1, B2, B6. Anal Chim Acta, 2004, 527(2): 187-193.
[26] 8-1200425(7)1257-1259
[27] 200425(1)60-62
[28] 3-120042582-83
[29] 7-34--2,5-(II)200420(3)263-265
[30] 5-52--3--5-200423(2)11-13
[31] (4-2). Quantitative determination of zinc in milkvetch by anodic stripping voltammetry with bismuth film electrodes. Talanta, 2005, 65: 1052-1055.
[32] (5-4). Comparative study on the inclusion behavior between meso-tetrakis (4-N-ethylpyridiniurmyl) porphyrin and cyclodextrin derivatives. Spectrochimica Acta A, 2005, 61: 413-418.
[33] (3-3). Effect of cyclic third components on non-deoxygenated RTP and their potential in developing optical thermometer. Spectrochimica Acta A, 2005, 61: 3038-3042.
[34] 4-2B2B62005, 9(3)136-139
[35] 3-2200525(3)53-57
[36] 3-2200521(2)9-12
[37] (6-1, ). Spectrofluorimetric study of the interaction of copper (II) and bis-heterocyclictriazene reagent in the presence of -cyclodextrin. Anal Chim Acta, 2006, 575: 68-75.
[38] (4-3). Novel self-protective phosphorescence from crystalline nanoparticles assembled by 3-bromo- and 3-iodo-carbazoles based on halogen-halogen interaction in suspension solutions. Anal Chim Acta, 2006, 572: 295-302.
[39] (6-6). Highly selective determination of methylmercury with methylmercury-imprinted polymers. Anal Chim Acta, 2006, 575(2): 159-165.
[40] 3-2(2-)-3,3,5,5-200627(5)863-866
[41] 4-4200626(2)29-64
[42] 3-33,5-200626(3)59-61
[43] (5-4). Determination of trace heavy metals in waters by flame atomic absorption spectrometry after preconcentration with 2, 4-dinitrophenyldiazoaminoazobenzene on amberlite XAD-2. Microchimica Acta, 2007, 157: 209-214.
[44] 6-1200723(1)31-33
[45] (6-2). A Coumarin-Derived Fluorescence Chemosensors Selective for Copper (II). Analytical Letters, 2008, 41(12): 2203-2213.
[46] (5-5). Carbon Composites Reinforced by Graphite Grains. J Nucl Mater, 2008, 375: 280-282.
[47] 7-21,8-(2-)200829(8)1560-1563
[48] 7-21-(8-)-3-(2-)-200829(6)1133-1136
[49] 6-2200828(7)1612-1616
[50] 4-34-Schiff200830(12)935-936943
[51] 7-2200827(s2)44-47
[52] 5-32008(7)83-87
[53] 5-5()200824(5)26-29
[54] (5-3). Bis(2,2 '-bi-1H-imidazole-k2N3, N3')(thiocyanato-kN)copper (II) chloride. Acta Cryst. E, 2009. 65, 1488-1489.
[55] (4-4). 1-[1-(Hydroxyimino)ethyl]-N-(2-methoxyphenyl) cyclopropanecarboxamide. Acta Cryst. E, 2009. 65, 1618-1618.
[56] (6-2, ). Synthesis and Analytical Application of Bis(2-diazoaminobenzothiazoyl)-benzidine for the Determination of Mercury Ion by Fluorimetry. Chem Res Chinese U, 2009, 25(2): 628-632.
[57] (6-3). Fluorescent pH probes based on boron dipyrromethene dyes. Dyes and Pigments, 2009, 81: 58-62.
[58] (4-2). A new selective fluorescent probe for lead ions. Chinese Chemical Letters, 2009, 20: 326-329.
[59] 7-2B6200928(10)21-25
[60] 7-5200928(1)59-62
[61] 7-2200925(3)27-31
[62] 7-6B6200925(1)34-36
[63] (8-4). Electro-Oxidation of Methane on Roughened Palladium Electrode in Acidic Electrolytes at Ambient Temperatures. Analytical Letters, 2010, 43(6): 1055-1065.
[64] (8-2, ). A novel chemosensor for Fe(III) based on phosphorescence quenching of 9-bromophenanthrene induced by -cyclodextrin combining with flow injection renewable drop. Analytical Letters, 2010, 43(4): 711-720.
[65] 5-5-201046(1)1-4
[66] 6-6201022(10)1929-1939
[67] 6-6/201031(10)1-4
[68] 4-4201026(1)44-47
[69] (6-6). Growth of carbon nanotubes on natural organic precursors by chemical vapor deposition. Carbon, 2011, 49(6): 2155-2158.
[70] (6-3). Microstructure and thermal properties of a paraffin/expanded graphite phase-change composite for thermal storage. Renewable Energy, 2011, 36(5): 1339-1342.
[71] 5-3201132(1)62-66
[72] 4-2B12201128(3)1331-1335
[73] 6-52-201127(3)45-47
[74] 5-31,4-DNI201127(2)37-39
[75] (5-2, ). Determination of puerarin in pharmaceutical and biological samples by capillary zone electrophoresis with UV detection. Talanta. 2012, 91: 83-87.
[76] 6-2IgY 201233(6)1177-1181
[77] 5-2CdS201228(6)33-37
[78] 6-64--3-201228(5)39-42
[79] 7-72-[2,3-d]-4(3H)-201228(2)32-35
[80] 3-2201228(2)28-31
[81] (5-3, ). Room temperature phosphorescence of 9-bromophenanthrene and the interaction with various metal ions. Spectrochimica Acta Part A. 2013, 102: 425-431.
[82] (9-2, ). Aptamer/thrombin/aptamer-AuNPs sandwich enhanced surface plasmon resonance sensor for the detection of subnanomolar thrombin. Biosensors and Bioelectronics, 2013, 47: 265-270.
[83] (5-2). HPLC-UV quantitative analysis of acrylamide in baked and deep-fried Chinese foods. Journal of Food Composition and Analysis. 2013, 31(1): 7-11.
[84] (2-2). Crystal structure of catena-((u2-4-amino-3,5-bis(4-pyridyl)-1,2,4-triazole)copper(I)chloride. Z. Kristallogr. NCS, 2013, 228: 17-18.
[85] (2-2). Crystal structure of tris(1,8-diazabicyclo[5.4.0]undec-7-ene)[(u12-phosphato)-tetracosakis(u2-oxo)-dodecaoxo-dodeca-molybdenum]. Z. Kristallogr. NCS, 2013, 228: 13-14.
[86] (2-2). Crystal structure of 1-methyl-5-(4-(1-methyl-1H-tetrazol-5-ylthio)butylthio)-1H-tetrazole. Z. Kristallogr. NCS, 2013, 228: 11-12.
[87] 4-2201329(2)243-247
[88] 5-2201330(6)3315-3317
[89] 5-5201329(4)34-37
[90] 4-2201329(2)34-37
[91] 5-2201329(3)36-39
[92] 5-5. HPLC6-201336(1)80-83
[93] 6-3201329(1)37-39
[94] (4-3,). A Novel Coumarin-based Fluorescence Chemosensor for Fe3+. Chemical Research in Chinese Universities, 2014, 30(4): 560-565.
[95] (5-5, ). A label-free fluorescent sensor for Pb2+ based on G-quadruplex and graphene oxide. Analytical methods, 2014, 6(20): 8120-8123.
[96] (6-2, ). A turn-on fluorescent aptasensor for adenosine detection based on split aptamers and graphene oxide. Analyst, 2014, 139: 1843-1846.
[97] (6-2, ). A label-free fluorescent sensor for Hg2+ based on target-induced structure-switching of G-quadruplex. Analytical methods, 2014, 6(3): 662-665.
[98] 6-6-BFe3+201430(2)39-42
[99] 5-5201430(1)33-37
[100] 6-3201430(1)40-43
[101] (6-6, ). Development and cell imaging applications of a novel fluorescent probe for Cu2+. RSC Advances, 2015, 5(85): 69453-69457.
[102] (7-2, ). Carbon dots isolated from chromatographic fractions for sensing applications. RSC Advances, 2015, 5(129): 106838-106847.
[103] (9-2, ). Capillary electrophoretic study of green fluorescent hollow carbon nanoparticles. Electrophoresis, 2015, 36(17): 2110-2119.
[104] (9-2, ). Sensitive determination of kaempferol using carbon dots as a fluorescence probe. Talanta, 2015, 144: 390-397.
[105] (7-2, ). Sensitive detection of carcinoembryonic antigen using surface plasmon resonance biosensor with gold nanoparticles signal amplification. Talanta, 2015, 140: 143-149.
[106] 6-2Cu2+201534(6)717-721
[107] 7-25201536(18)85-88
[108] 7-2-201536(8)206-210
[109] 7-2201531(4)33-37
[110] (4-4, ). A highly selective and commercially available fluorescence probe for palladium detection. Sensors and Actuators B: Chemical, 2016, 232: 611-618.
[111] (5-4, ). The effect of meta-substituted or para-substituted phenyl as side chains on the performance of polymer solar cells. Synthetic Metals, 2016, 220: 402-409.
[112] (8-7, ). The Influence of Fluorination on Nano-Scale Phase Separation and Photovoltaic Performance of Small Molecular/PC71BM Blends. Nanomaterials, 2016, 6: 80-91.
[113] (4-3, ). A graphene oxide-based fluorescent aptasensor for alpha-fetoprotein detection. Analytical Methods, 2016, 8: 6131-6134.
[114] (4-3, ). The development of a novel chemiluminescent glucose sensor using hydrophilic Co3O4@SiO2 mesoporous nanoparticles. Analytical Methods, 2016, 8: 2923-2928.
[115] (4-4). Crystal structure of 4-(4-((3-bromophenyl)amino)-6-(tert-butyl)-3-(2- hydroxypropan-2-yl)cinnolin-8-yl)-2-methylbut-3-yn-2-ol, C26H30BrN3O2. Z. Kristallogr. NCS, 2016, 231(4): 1211-1213.
[116] 4-2201628(4)432-436
[117] 6-6BCu2+201638(7)673-676685
[118] 7-24 201637(4)73-76
[119] 4-4201638(2)153-156
[120] 5-5201639(1)113-116
[121] 4-4Hg2+201632(2)41-43
[122] 4-2201632(6)36-39
[1] 1993
[2] 2-120007
[1] 199612
[2] 1998
[3] 2019988
[4] 19988
[5] 200393-1
[6] 20065
[7] 200774-1
[8] 20073
[9] 200824-1
[1] 4-1200510012653.2ZL200510012653.22007214
[2] /6-2200610102223.4ZL200610102223.420081112
[3] 5-5200610048346.4ZL200610048346.4200934
[4] 1-(8-)-3-(2-)-5-1200810054989.9ZL200810054989.9 2010623
[5] (8-)-5-1200810054990.1ZL200810054990.12010 811
[6] 3,5--(4-)7-7200710185313.9ZL200710185313.920101124
[7] pH6-4200810079711.7ZL200810079711.720101222
[8] 4,4-(5--8--7-)-3,5,3,5-5-5200910074909.0ZL200910074909.02011518
[9] 4,4-[5,6--2-]-3,3-6-5200810080130.5ZL200810080130.52011622
[10] 8-6201010227369.8ZL 201010227369.8201274
[11] //7-5201010160176.5ZL201010160176.5201288
[12] 1,8-(2-)5-1200810054987.XZL200810054987.X 201295
[13] 7-7200710165313.2ZL200710165313.22013123
[14] N-(2-)-7--3--4-1201310007753.0ZL201310007753.02015422
[15] N-()-3--7-N,N--4-1201310042509.8ZL201310042509.8201578
[16] 4-3201620177777XZL201620177777X2016727
[17] 4-32016201755130ZL20162017551302016727
[18] 4-32016201755145ZL20162017551452016921
(1958-)197920002005
[1]FIB011286200221-1
[2]2006011025
[3]06107200688-1
[4]III2008-B-11101-1
[5]--200801104920085-2
[6]508710802009306-2
[7]/2010081026 106-2
[8]210731132011.1-2013.12 287-1
[9]2013508-1
[10]2014601-1
[11]2014301-1
[12]2014301-1
[13]201455-1
[14]20152301-1
[1](4-4). Spectrophotometric determination of lead in vegetables with dibromo-p-methyl carboxysulfonazo. Talanta, 2002, 57(6): 1155-1160.
[2](3-2). The entropy of a kim black hole and the nernst theorem. Il Nvovo Cimento, 2003, 118: 685-691.
[3](3-2). Statistical entropy of a higher dimensional black hole. Journal of the Korean Physical Society, 2003, 43: 987-990.
[4](6-4). Solid-phase spectrophotometric determination of nickel in water and vegetable samples at sub-mug I(-1) level with o-carboxylphenyldiazoaminoazobenzene loaded XAD-4. Talanta, 2004, 64(1): 160-166.
[5](6-4). Direct spectrophotometric determination of trace cadmium (II) in food samples with 2-Acetylmercap tophenyldiazoamino azobenzene (AMPDAA). Microchimica Acta, 2004, 147(4): 265-271.
[6](6-1). Preconcentration of trace metals with 2-(methylthio)aniline- functionalized XAD-2 and their determination by flame atomic absorption spectrometry. Analytica Chimica Acta, 2004, 504: 319-324.
[7](3-1). Solid-phasespectrophoto-metris determination of nickel in water and vegetable samples at sub-ug/I lever with o-carboxylpheyl diazoaminoazo benzene loaded XAD-4. Talanta, 2004, 64(1): 160-166.
[8](6-1). Preconcentration and determination of trace elements with 2-amino acetylthiophenol functionalized Amberlite XAD-2 by inductively coupled plasma-atomic emission spectrometry. Talanta, 2004, 62(1): 207-213.
[9](5-1). Determination of lead using a new chromogenic reagent2-(2sulfo4- acetylphenylazo)-7-(2,4,6-trichlorophenylazo)-1,8-dihydroxynaphthalene-3,6-disulfonic acid. Microchimica Acta, 2004, 144(4): 257-261.
[10](5-4). Highly selective determination of inorganic mercury(II) after preconcentration with Hg(II)-imprinted diazoaminobenzene-vinylpyridine copolymers. Analytica Chimica Acta, 2005, 538: 85-91.
[11](6-4). Highly selective determination of total mercury(II) sub microgram per liter by -cyclodextrin polymer solid-phase spectrophotometry using 1.3-di-(4- nitrodiazoamino)-benzene. Analytica Chimica Acta, 2005, 532(2): 121-128.
[12](6-2). Column solid-phase extraction with 2-acetylmercaptophenyl- diazoaminoazobenzene (AMPDAA) impregnated amberlite XAD-4 and determination of trace heavy metals in natural waters by flame atomic absorption spectrometry. Microchimica Acta, 2005, 149(1): 95-101.
[13](3-1). Solid phase extraction and preconcentration of trace heavy metals ions in natural water with 2,2-dithiobisaniline modified amberlite XAD-2. Solvent Extraction and Ion Exchange, 2005, 23(5): 725-740.
[14](6-1). The color reaction of mercury(II) with the new reagent 2-Methyiophenyldizoaminoazobenzene and its application. Journal of Analytical Chemistry, 2005, 60: 625-628.
[15](5-5). Preparation of CuCr25 contact materials by vacuum induction melting. Journal of Materials Processing Technology, 2006, 178, 283-286.
[16](6-4). Highly selective determination of total mercury(II) sub microgram per liter by -cyclodextrin polymer solid-phase spectrophotometry using 1.3-di-(4-nitrodiazoamino)-benzene. Analytical Chimica Acta, 2006, 532(2): 121-128.
[17](4-2). Highly selective determination of methylmercury with methylmercury-imprinted polymers. Analytical Chimica Acta, 2006, 575(2): 159-165.
[18](6-6). Double-interface growth mode of fractal silver trees within replacement reaction. Applied Physics Letters, 2006, 89(17):173104-1-3.
[19](4-3). Biosorption and preconcentration of lead and cadmium on waste Chinese herb Pang Da Hai. Journal of Hazardous Material, 2006, 135(1-3): 389-349.
[20](5-2). Online separation and preconcentration of trance heavy metals with 2,6-dihydroxylphenyldiazoaminoazobenzene impregnated amberlite XAD-4. Microchimica Acta, 2007, 158(3): 239-245.
[21](5-2). Determination of trace heavy metals in waters by flame atomic absorption spectrometry after preconcentration with 2,4-dinitrophenyldiazoaminoazo- benzene on Amberlite XAD-2. Microchimica Acta, 2007, 157(3): 209-214.
[22](7-6). Growth of gold nanoplates: The case of a self-repair mechanism. Crystal Growth & Design, 2007, 7(11), 22582261.
[23](3-3). Caten-Poly[(1,12,15,26-tetra-aza-5,8,19,22tetra-oxa- 3,4:9,10:17,18: -23,24-tetrabenzocyclooctacosane-k4N1N12N15N26) nickel () -terph thalato--k2O1:O4]. Acta crystallographica section E, 2008, E64: m143.
[24](4-4). Bis(acetylacetonato-kO,O') (methanol-kO)thiocyanato-kN)manganese(). Acta crystallographica section E, 2008, E64: m1363.
[25](6-5). Spectrophotometric determination of nickel in biological samples using 1-Azobenzene-3-(3-hydroxyl-2-pyridyl)-triazene. Journal of Analytical Chemistry, 2008, 63(12): 1158-1163.
[26](5-2). Methane sensor based on palladium/MWNT nanocomposites. Chinese Chemical Letters, 2009, 20: 608-610.
[27](4-4,). Spectrophotometric determination of leadin traditional Chinese medicines with dibromo-p-methyl- acethylsulfonazo. Journal of Analytical Chemistry, 2009, 64(11): 1136-1141.
[28](4-4). Dynamics of cathode SPOT movement on a carbon/carbon composite in vacuum. Modern Physics Letters B, 2009, 23(01): 89-96.
[29](4-2). A molecular dynamic study of water/ methane/propane. Journal of physics B, 2009, 42,035302.
[30](5-2). Complex formation of Sudan I with Cu(II) and its identification from chilli species. Bioinformatics and Biomedical Engineering, 2010, 1: 18-20.
[31](5-2). Effect of the indices of crystal plane of gold electrodes on the transport properties of C20 fullerene. Journal of Applied Physics, 2010, 107 (10): 103702-4.
[32](5-2). Negative differential resistance and rectifying behaviors in atomic molecular device with different anchoring groups. Physica E, 2010, 43(1): 524-528.
[33](5-2).Torsion angle dependence of the rectifying performance in molecular device with asymmetrical anchoring groups. Physics Letters A, 2010, 374 (48): 4876-4879.
[34](6-2). Effect of intermolecular distance and contact hollow-type on the transport properties of parallel atomic wires. Physics Letters A, 2010, 374 (5): 778-781.
[35](4-3, ). Preparation of nanometer-sized black iron oxide pigment by recycling of blast furnace flue dust. Journal of Hazardous Materials, 177(1-3): 495-500, 2010.
[36](5-5, ). Spectrophotometric determination of trace cadmium in vegetables with 3,5-bis(4-phenylazophenylaminodiazo)benzoic acid. Journal of Analytical Chemistry, 2011, 66: 31-36.
[37](6-6, ). 2-amino-6-benzyl-4,5,6,7-tetra-hydrothieno[2,3-c] pyridine-3-carboxylate. Acta Crystallographica Section E, 2011, E67: o226.
[38](5-5, ). N-Phenymorpholine-4-carboxamide. Acta Crystallographica Section E, 2011, E67: o225.
[39](3-2, ). Effect of the encapsulation of Li atom on the electronic transport properties of C20F20 cage. Physics B, 2011, 406 (18): 3442-3445.
[40](6-2). Microstructure and thermal properties of a paraffin/expanded graphite phase-change composite for thermal storage. Renewable Energy, 2011, 36(5): 1339-1342.
[41](4-2). Chitosan-mediated preparation of porous amorphous NiB nanoparticles from silver-catalyzed electroless plating. Advanced Materials Research, 2012, 361-363: 565-568.
[42](3-3, ). Cloud point extraction for the determination of trace amounts of cobalt in water and food samples by flame atomic absorption spectrometry. Journal of Spectroscopy, 2012, 2013:1-7.
[43](7-2). An approach for synthesizing grapheme with calcium carbonate and magnesium. Carbon, 2012, 50(13): 4939-4944.
[44](7-5). A green chemical approach for preparation of PtxCuy nanoparticles with a concave surface in molten salt for methanol and formic acid oxidation reactions. Journal of Materials Chemistry, 2012, 22(11): 4780-4789.
[45](3-3). Preparation of polypyrrole films on insulating substrates by self-assembled monolayers. Materials Letters, 2012, 86: 38-41.
[46](4-3). Decomposition of methylamine on nitrogen atom modified Mo(100): a density functional theory study. Physical Chemistry Chemical Physics, 2012, 14(19): 6869-6882.
[47](4-3). A DFT+U Study of Acetylene Selective Hydrogenation on Oxygen Defective Anatase (101) and Rutile (110) TiO2 Supported Pd4 Cluster. Journal of Chemical Physics, 2012, 136(10): 104-107.
[48](4-4). Decomposition of Methylamine on Mo(100) Surface: A DFT study. Journal of Natural Gas Chemistry, 2012, 21(2): 132-137.
[49](4-2). Synthesis of large spherical mesoporous silica using tween-80 and starch hydrolysis solution. Advanced Science Letters, 2012, 5(1): 204-207.
[50](5-4, ). Preparation of cobalt hydroxide film modified electrode and its analytical application. Journal of Analytical Chemistry, 2012, 67(4): 416-423.
[51](3-3, ). Cloud point extraction for the determination of trace amounts of cobalt in water and food samples by flame atomic absorption spectrometry. Journal of Spectroscopy, 2012, 2013(1): 1-7.
[52](8-8, ). A rapid and easy approach for the reduction of graphene oxide by formamidinesulfinic acid. Carbon, 2013, 54(8): 36-41.
[53](4-3, ). Theoretical study of the adsorption and dissociation mechanism for methylamine on Pd(111). Applied Surface Science, 2013, 271(8): 291-298.
[54](4-3). HPLC-UV quantitative analysis of acrylamide in baked and deep-fried Chinese foods. Journal of Food Composition and Analysis, 2013, 31(1): 7-11.
[55](4-4). Junru Tan. Preparation and formation mechanism of nano-iron oxide black pigment from blast furnace flue dust. Ceramics International, 2013, 39(1): 737-744.
[56](5-5, ). Large negative differential resistance and rectifying performance modulated by contact sites in fused thiophene trimmer-based molecular device. Physics Letters A, 2013, 377 (31-33): 1920-1924.
[57](7-7, ). Tensile fatigue of a 2.5D-C/SiC composite at room temperature and 900 C. Materials & Design, 2013, 49: 814-819.
[58](4-4, ). Synthesis and magnetic properties of Fe3O4 nanoparticles from the blast furnace flue dust. Optoelectronics and Advanced Materials-Rapid Communications, 2013, 7(7-8): 525-529.
[59](7-7, ). Thermal shock properties of a 2D-C/SiC composite and its damage mechanisms. Advances in Applied Ceramics, 2013, 112(8): 499-504.
[60](5-5, ). Spectrophotometric determination of trace mercury(II) in cereals with 2,4-bis(4-phenylazophenylaminodizao)benzenesulfonic acid. Journal of Analytical Chemistry, 2013, 68(6): 488-494.
[61](5-5). Influence of a TiAlN coating on the mechanical properties of a heat resistant steel at room temperature and 650C. Journal of Wuhan University of Technology-Materials Science Edition, 2013, 28(5): 1029-1033.
[62](5-4, ). A novel chemical synthesis of bowl-shaped polypyrrole particles. Materials Letters, 2014, 126: 185-188.
[63](7-7, ). Facile synthesis of macroporous silicon photocathodes with enhanced photoelectrochemical performance. Materials Letters, 2014, 128: 148-151.
[64](7-3, ). Facile co-precipitation synthesis of shape-controlled magnetite nanoparticles. Ceramics International, 40(1, part B): 2014, 40(1): 1519-1524.
[65](6-6, ). Preparation of solid superacid S2O82-/TiO2-exfoliated graphite (EG) and its catalytic performance. Ceramics International, 2014, 40(10): 16183-16187.
[66](5-5, ). Molecular rectification modulated by alternating boron and nitrogen Co-doping in a combined heterostructure of two zigzag-edged trigonal graphenes. Physics Letters A, 2014, 378 (7-8): 646-649.
[67](4-4, ). Size dependence rectification performances induced by boron and nitrogen Codoping in rhombic graphene nanoribbons. Physics Letters A, 2014, 378 (11-12): 904-908.
[68](5-4). Reaction mechanism of methylamine decomposition on Ru(0001): a density functional theory study. Journal of Molecular Modeling, 2014, 20(3): 2137.
[69](6-6, ). Magnetically recoverable Cu2O/Fe3O4 composite photocatalysts: Fabrication and photocatalytic activity. Chinese Chemical Letters, 2014, 25(2): 287-291.
[70](4-4, ). Electrochemical behaviors of ionic liquid confined into nanopores of silica gel matrix. Journal of Electrochemistry, 2014, 20(2): 121-127.
[71](5-5, ). Spectrophotometric determination of trace copper() in biological samples with 2,4-bis(4-phenylazophenylaminodiazo)phenol. Journal of Analytical Chemistry, 2014, 69(4). 357-361.
[72](5-5, ). Facile synthesis of thieno[2,3-d]pyrimidine derivatives using inorganic base catalysis. Synthetic Communications, 2014, 45(10): 1461-1465.
[73](8-7, ). Methanol conversion to propylene over Mo-HZSM-5 zeolite. Advanced Materials Research, 2014, 834-836: 476-480.
(9-9, ). Morphology-controlled synthesis of ZSM-5/ MCM-41 composite zeolite. Applied Mechanics and Materials, 2014, 599-601: 77-80.
[74](4-4, ). Expanded vermiculite applied in the catalytic process as a catalyst support. Applied Mechanics and Materials, 2014, 556-562: 335-338.
[75](6-5, ). Bipolar spin-filtering effect in B- or N-doped zigzag graphene nanoribbons with asymmetric edge hydrogenation. Phys. Lett. A, 2015, 379 (43-44): 2860-2865.
[76](4-4, ). Modulation of low bias negative differential resistance in a molecular device by adjusting anchoring groups. Adv. Mater. Res, 2015, 1070-1072: 479-482,.
[77](9-9). SAPO-34 zeolites prepared using calcined-MCM-41 as silica source. Advanced Materials Research, 2015, 1061-1062: 162-165.
[78](5-3). Polypyrrole films prepared on self-assembled silane monolayers and applications. Materials Technology: Advanced Performance Materials, 2015, 30(3): 182-188.
[79](4-3). Molten salt medium synthesis of wormlike platinum silver nanotubes without any organic surfactant or solvent for methanol and formic acid oxidation. Physical Chemistry Chemical Physics,2015,17(46):3117.
[80](7-5). Highly active carbon supported Pd/C catalysts decorated by a trace amount of Pt by an in-situ galvanic displacement reaction for formic acid oxidation. Journal of Power Sources, 2015, 278: 332-339.
[81](5-3). DFT + U investigation on the adsorption and initial decomposition ofmethylamine by a Pt single-atom catalyst supported on rutile (110)TiO2. Applied Surface Science, 2016, 389: 411418.
[82](8-2). Highly stable and efficient platinum nanoparticles supported on TiO2@Ru-C: investigations on the promoting effects of the interpenetrated TiO2. Electrochimica Acta, 2016, 216(20): 8-15.
[83](6-6, ). Preparation of Cu2O/exfoliated graphite composites with high visible light photocatalytic performance and stability. Ceramics International, 2016, 42(11): 13273- 13277.
[84](6-6, ). Enhanced catalytic activity and stability of SO42-/ZrO2 solid acid catalyst combined with carbon nanotubes. Ceramics International, 2015, 41(9): 12186-12191.
[85](4-4, ). Prediction of film performance by electrochemical impedance spectroscopy. Corrosion science. 2015, 99: 42-52.
[86](5-4). Adsorption and decomposition of methylamine on a Pt(100) surface: a density functional theory study. RSC Advances, 2015, 5(26): 20208-20217.
[87](5-4). Efficient synthesis of 2-oxazolidinones from epoxides and carbamates catalyzed by aminefunctionalized ionic liquids. RSC Advances, 2015, 5(88): 71765-71769.
[88](5-5, ). The effects of negative differential resistance, bipolar spin-filtering, and spin-rectifying on step-like zigzag graphene nanoribbons heterojunctions with single or double edge-saturated Hydrogen. Journal of Electronic Materials, 2017, 46: 1-9
[89](5-6, ). Negative differential resistance effect in similar right triangle graphene devices. Journal of Computational Electronics,2016,15(4):1-7.
[90](5-5, ). Tuning electronic transport of zigzag graphene nanoribbons by ordered B or N atom doping. J. Comput. Electron, 2016, 15 (3): 891-897.
[91](5-5, ). Vertex-atom-dependent rextification in triangular h-BNC/triangular graphene heterojunctions. J. Electron. Mater, 2016, 45 (8): 4484-4490,.
[92](5-5, ). Nitrogen doping position-dependent rectification of spin-polarized current and realization of multifunction in zigzag graphene nanoribbons with asymmetric edge hydrogenation. J. Electron. Mater, 2016, 45 (2): 1165-1174.
[93](5-4, ). Density Functional Theoretical Studies on the Methanol Adsorption and Decomposition on Ru(0001) Surfaces. Chem. Res. Chin. Univ, 2016, 32(2): 234-241.
[1] . 1-1. 2001.
[2] . 6-1. 2002.
[3] . 4-1. 200310.
[1] 20024-4.
[2] 20047-1.
[3] ----20135-1.
[4] 20135-5.
[5] 20136-1.
[6] 20144(6-1).
[1] 4-1CN 03 138753.5ZL 03 138753.520043.
[2] /6-3CN 200610102223.4ZL 200610102223.420077.
[3] ZSM-485-520111 0020053.6 ZL 20111 0020053.620115.
[4] Ru8-1CN20101 0203792.4ZL 20101 0203792.4201012.
[5] UZM-54-3CN 201110020066.3ZL 201110020066.3 20115.
[6] 2,6--(1,1'-)(1,2-d;4,5-d')(5-5)CN 201110455936.XZL 201110455936.X20127.
[7] ZSM-48(9-4)CN 2013 1 0226831.6ZL 2013 1 0226831.6201411.
[8] (7-2)CN 201310250780.0ZL 201310250780.0201312.
[9]Ti-Beta(7-3)CN 20131 0250820.1ZL 20131 0250820.1201311.
[10](6-3)CN 201310251349.8ZL 201310251349.820139.
[11]/(6-3)CN 201310250772.6ZL 201310250772.620139.
[12](9-4)CN 201310568955.2ZL 201310568955.220166.
1971-199620022005
[1] /.200610.0.5-1.
[2] .20070300920072.5.5-1.
[3] /.2008103520083.0.6-1.
[4] .09-90920095.6-1.
[5] 200910.1-1.
[6] /.2009-Y-13200910.0.5-1.
[7] .2010048072720103.1-1.
[8] /.2010081026201010.4-1.
[9] /.(51072105)201074.(9-1).
[10] .(21073113)201056.(7-2).
[11] .2011011023-220118.9-1.
[12] .(20111035)201130.(6-1).
[13] /.201104321201110.1-1.
[14] 201220.1-1.
[15] .NCET-11-1033201250.1-1.
[16] .[2013]2832013551-1.
[17] .(20131035),201380.8-1.
[18] .2013152013108.12-1.
[19] . 201712320170215.19-1.
[20] 201704D1310332017150.12-2.
[21] . 201705D2110102017113.1-1.
[22] . 201705D1410342017110.1-1.
[1] 4-1. 2001196481-484.
[2] 3-2 . 2002306,641-644.
[3] 4-1. /CVI2004, 33(6): 44-48.
[4] 3-1. 20046(20): 583-585.
[5] 3-1. /, 2005, 19(3):293-298.
[6] 4-1. /2005, 35(6):41-43.
[7] 5-1. /, 2005,26(4):1-4 .
[8] 4-1. -, 2005,6,71-73.
[9] 5-1. /200526(1): 1-4 .
[10] 4-2. CVI/, 2005, 13(5): 449-452.
[11] 4-1.The influence of thermal gradient on pyrocarbon deposition of carbon/carbon composites during the CVI process, Carbon, 2006, 44(4):786-791.
[12] 4-1.The thermal expansion of carbon/carbon composites from room temperature to 1400, Journal of materials science, 2006, 41(24):8356-8358.
[13] 4-1.Thermal gradient CVI for manufacture carbon/carbon composites tubesJournal of Materials Engineering20067(suppl)345-348 .
[14] 4-1. /2006, 26S2,59-63.
[15] 5-1. /CVI20067(sl)326-328.
[16] 5-1. /200627(6): 1-4.
[17] 4-1.200738(S):2212-2213
[18] 5-1./, 2007, 15(5): 163-166.
[19] 4-2/2007, 27,(S1):304-306 .
[20] 5-1. CVD2007S111-14.
[21] 6-1. 2007S120-22.
[22] 4-1. CLVI/2007S18-10.
[23] 3-1.C/C, , 2007, 22(1): 12-16 .
[24] 6-1. An artificial neural network model of the CVD processes for carbon/carbon composites, Carbon Science and Technology, 2008, 1:60-65.
[25] 3-1.Carbon composites reinforced by graphite grains, Journal of Nuclear Materials, 2008, 375(2): 280282.
[26] 6-1.Growth of carbon nanotubes on the surface of carbon fibersCarbon, 2008, 46(2): 380-383.
[27] 5-1./2008, 28(9): 46-47.
[28] 5-1., 2008, 302 (7), 83-87.
[29] 6-1. , 2008, 23 (1): 12-16.
[30] 4-1. Carbon nanotube growth in the pores of expanded graphite by chemical vapor deposition, Carbon, 2009, 47(7): 1747-1751.
[31] 7-1. /, , 2009, 24(2): 114-118 .
[32] 3-2. , 2009, 6(3): 1-5.
[33] 6-1. /, 2010, 31(10): 1-4 .
[34] 6-1. Growth of carbon nanotubes on natural organic precursors by chemical vapor deposition, Carbon, 2011, 49(6): 2155-2158 .
[35] 6-1. Microstructure and thermal properties of a paraffin/expanded graphite phase-change composite for thermal storage, Renewable Energy, 2011, 36(5): 1339-1342.
[36] 2-2./, 2011, 30(3), 6-9.
[37] 2-2., , 2011, 30(2), 6-8.
[38] 5-2. , 2011, 44(8): 9-11.
[39] 6-2. , , 2012, 27(3): 175-180 .
[40] 7-1.An approach for synthesizing graphene with calcium carbonate and magnesium, Carbon, 2012, 50(13): 4939-4944.
[41] 4-3.Chitosan-mediated preparation of porous amorphous NiB nanoparticles from silver-catalyzed electroless plating. Advanced Materials Research, 2012, 361-363, 565-568.
[42] 8-7.A rapid and easy approach for the reduction of graphene oxide by formamidinesulfinic acid. Carbon, 2013, 54, 36-41 .
[43] 4-4.Synthesis and magnetic properties of Fe3O4 nanoparticles from the blast furnace flue dust. Optoelectronics and advanced materials-rapid communications. 2013, 7(7-8), 525-529.
[44] 3-3. TiO2, 2013, 36(2): 130-134.
[45] 5-5. , , 2013, 42(4): 620-623.
[46] 3-3. , 2013, 29(1): 42-44.
[47] 5-3.Facile preparation of graphene by high-temperature electrolysis and its application in supercapacitor[J]. Acta Chimica Slovenica, 2014, 61(4): 852-857.
[48] 7-7.Facile co-precipitation synthesis of shape-controlled magnetite nanoparticles. Ceramics International, 2014, 40, 1519-1524.
[49] 6-3Bipolar spin-filtering effect in B-or N-doped zigzag graphene nanoribbons with asymmetric edge hydrogenation, PhysicsLettersA, 2015, 379:2860-2865.
[50] 8-2.2015201511(6-7):137.
[51] 8-2./201511(8-9):54.
[52] 4-2.,2015,11(08-09):34.
[53] 9-2..2015201511(6-7):76.
[54] 4-2.201511(08-09):35.
[55] 10-2..201511(8-9):33.
[56] 6-1.Growth of carbon nanotubes on graphene by chemical vapor depositionNew carbon materials, 2016, 31(1):31-36.
[57] 9-3. Superior performance asymmetric supercapacitors based on a directly grown three-dimensional lawn-like cobalt-zinc hydroxyfluorides nanoneedle arrays electrodeChemical Engineering Journal20173261048-1057.
[58] 10-4.Comparison of -NiMoO4 nanorods and hierarchical -NiMoO4@-MnO2 core-shell hybrid nanorod/nanosheet aligned on Ni foam for supercapacitors, Journal of Alloys and Compounds 2017 70814-22.
(10-1)./20144.
[1] /2005127-7.
[2] /.20096(6-1).
[3] .20125-1.
[4] /.()201511(6-1).
[1] 5-1200610048346.4475494200934.
[2] 6-1200710165314.76781422010915.
[3] 8-8201010227381.99476752012523.
[4] 8-1201010227369.8995188201274.
[5] 6-1200710165313.211270982013123.
[6] 8-1201310161310.714857822014917.
[7] 6-6201310000224.815168022014115.
[8] 5-1201310169697.0148705120151125.
[9] 6-2201410057112.0185329220151125.
[10] 5-1201310220005.019566092016217.
1968-1988199620082001.09-2002.082012.09-2014.08
[1] . (200310), 200311, 6. (6-1).
[2] . 2008910. (2-1).
[3] . (20090980), 20099, 7.5. (6-1).
[4] /2009011015-1200918. (5-4).
[5] . 21175085. 20121120. (10-2).
[6] i-motif DNA. (2015179), 20153. (5-5).
[1] (3-1). , . 1996, 4 (4): 68-71.
[2] (4-4). GMT-PP, . 1999, 7 (2): 50-54.
[3] (2-1). . . 1999, 15 (6): 66-71
[4] (4-4). , . 2000, 8 (1): 16-20.
[5] (4-3). , . 2001, 17 (6): 41-43+54.
[6] (3-1, ). T300CF/, 2001, 17 (6): 28-31.
[7] (2-1). , . 2003, 17 (02): 25-27.
[8] (2-2). , . 2003, 19 (5): 37-40.
[9] (2-2). , . 2004, 19 (02): 14-16.
[10] (7-2). 4--2,5-(), . 2004, 20 (3), 263-265.
[11] (2-1, ). APSABT(), . 2004, 278-281.
[12] (4-2). . , 2004, 20 (5), 23-25.
[13] (7-2, ). 2-. , 2004, 24 (5), 5-7.
[14] (6-6). Preconcentration of trace metals with 2-(methylthio)aniline-functionalized XAD-2 and their determination by flame atomic absorption spectrometry. Analytica Chimica Acta. 2004, 504: 319-324.
[15] (6-3). The Color Reaction of Mercury(II) with the New Reagent 2-Methylthiophenyldi- azoaminoazobenzene and Its Application. Journal of Analytical Chemistry. 2005, 60 (7): 625-628.
[16] (5-4). Colorimetric and Ratiometric Fluorescence Sensing of Fluoride: Tuning Selectivity in Proton Transfer [J]. J. Org. Chem. 2005, 70(25):10524-10531.
[17] (5-4). Banana lectin is unique in its recognition of the reducing unit of 3-O--glucosyl/mannosyl disaccharides: a calorimetric study. Glycobiology. 2005, 15 (10): 1043-1050.
[18] (3-3, ). 1- (4-) -3- (8-) -. , 2006, 23(4)827-830.
[19] (4-3). (BODIPY). . 2007, 36 (2), 198-201.
[20] (3-3, ).. 200724 (5)86-89.
[21] (5-2). Spectrophotometric Determination of Thorium in Food Using 2-(2,5- disulfonic-4-methoxy-phenylazo)-7-(2-hydroxyl-5-carboxylphenylazo)-1,8- dihydroxy naphthalene-3,6-disulfonic acid. Journal of Analytical Chemistry, 200762: 1051-1055.
[22] (8-5). Synthesis and spectral properties of new boron dipyrromethene dyes [J]. Dyes and Pigments. 2007, 73, 206-210.
[23] (7-5). Fluorescence Sensing of Anions Based on Inhibition of Excited-State Intramolecular Proton Transfer [J]. J. Org. Chem. 2007, 72 (1): 62-70.
[24] (4-1). . . 200634: S283-S288.
[25] (3-1). 8-[4-[N,N-bis(2-chloroethyl) amino] phenyl]- 4,4-difluoro-1,3,5,7-tetramethyl -4-bora-3a,4a-diaza-s-indacene. Acta Crystallographica, Section E. 2007, E63, o3317.
[26] (3-3, ). 1-4--2--4-. 2008, 27 (2), 54-57.
[27] (2-1, ). 3,6-Bis(ethylamino)-2-[(2-hydroxyethyl)amino]-2,7- dimethylspiro- [isoindoline-1,9-xanthen]-3-one. Acta Crystallographica, Section E. 2008, E64, o1645.
[28] (2-1, ). 3,6-Bis(diethylamino)-2-(2-hydroxyethylamino) spiro [isoindoline-1,9-xanthen]-3-one. Acta Crystallographica, Section E. 2008, E64, o1252.
[29] (4-1, ). A new selective fluorescent probe for lead ions. Chinese Chemical Letters, 2008, 20: 326-329.
[30] (7-4). . (). 2009, 25 (3): 27-31.
[31] (4-3). 1-[1-(Hydroxyimino)ethyl]-N-(2-methoxyphenyl)cyclopropanecarboxamide. Acta Crystallographica, Section E. 2009, E65: o1618.
[32] (8-4). A fluorescent chemodosimeter specific for cysteine: effective discrimination of cysteine from homocysteine. Chem. Commun., 2009, 59045906.
[33] (6-1). Fluorescent pH probes based on boron dipyrromethene dyes. Dyes and Pigments, 2009, 81: 58-62.
[34] (5-2, ). . 2010, 22 (10): 1929-1939.
[35] (5-3, ). . , 2011, 32 (1): 62-66.
[36] (7-5). IgY. , 201233(06): 1177-1181.
[37] (5-1). A fluorescent sensor for pH based on rhodamine fluorophore. Dyes and Pigments, 2012, 95: 112-115.
[38] (5-3). . 201329 (4), 34-36+39.
[39] (5-5). Room temperature phosphorescence of 9-bromophenanthrene, and the interaction with various metal ions. Spectrochim. Acta, Part A, 2013, 102: 425-431.
[40] (9-6). Aptamer/thrombin/aptamer-AuNPs sandwich enhanced surface plasmon resonance sensor for the detection of subnanomolar thrombin. Biosens. Bioelectron, 201347(15): 265270.
[41] (7-1). Rhodamine-based turn-on fluorescent probe for Cu(II) and its fluorescence imaging in living cells. Bioorganic & Medicinal Chemistry Letters, 2013, 23: 2916-1919.
[42] (5-4). Self-Assembly of Intramolecular Charge-Transfer Compounds into Functional Molecular Systems. Acc. Chem. Res., 2014, 47 (4): 11861198.
[43] (6-5). , (). 2014, 30 (1): 40-43.
[44] (8-1, ). An unusual OFFON fluorescence sensor for detecting mercury ions in aqueous media and living cells. Chemical Communication, 2014, 50: 2055-2057.
[45] (6-2, ). Development and cell imaging applications of a novel fluorescent probe for Cu2+. RSC Adv., 2015, 5: 6945369457.
[46] (4-2, ). Hg2+. 201632 (2): 41-43.
[47] (4-2, ). . 201638(2): 153-156.
[48] (4-2, ). Crystal structure of 4-(4-((3-bromophenyl)amino)-6-(tert-butyl)-3-(2- hydroxypropan-2-yl)cinnolin-8-yl)-2-methylbut-3-yn-2-ol, C26H30BrN3O2. Z. Kristallogr. NCS , 2016, 0138.
[1] /1-1. : 20103.
[1] /: , 2004
[1] . , 200411. (7-4).
[1] . (6-6)CN03138753.520043
[2] . (7-7)CN200510046876.020061.
[3] pH, (6-1)CN200810079711.7, 72000020095.
[4] . (7-2)CN201010601070.4.
[5] N-(2-)-7--3--(4-4)ZL201310007753.0164432920139
[6] N-()-3--7-N,N--(4-4)ZL201310042509.8171681920139.
1978-199920042007
[1] 2008-B-2020081210
[2] 200811040200871.55-2
[3] /200810352008826-4
[4] /5107210520108376-2
[5] Fe3O4/PPy201210172012635-1
[6] 2012021020-52012645-2
[7] Fe3O4@PPy5130309820138256-1
[8] Fe3O4/2147706920148787-2
[9] Fe3O4/PPy201422-2201412107-5
[1] 3-1. . (), 2009, 25(4): 32-35.
[2] 4-3. PPy. (), 2009, 25(6): 37-40.
[3] 4-1, Preparation of nanometer-sized black iron oxide pigment by recycling of blast furnace flue dust. Journal of Hazardous Materials, 2010, 177(1-3): 495-500.
[4] 4-2, . Polymerization and characterization of high conductivity and good adhension polypyrrole films for electromagnetic interference shielding. Chinese Journal of Polymer Science, 2010, 28(6): 923-930.
[5] 2-1. . (), 2011, 27(4): 31-33, 36.
[6] 3-2, . Preparation of polypyrrole films on insulating substrates by self-assembled monolayers. Materials Letters, 2012, 86: 38-41.
[7] 2-2. . (), 2012, 28(5): 32-34.
[8] 4-1. Preparation and formation mechanism of nano-iron oxide black pigment from blast furnace flue dust. Ceramics International, 2013, 39(1): 737-744.
[9] 4-1. Synthesis and magnetic properties of Fe3O4 nanoparticles from the blast furnace flue dust. Optoelectronics and Advanced Materials-Rapid Communications, 2013, 7(7-8): 525-529.
[10] 7-1. Fe3O4. , 2013, 41(9): 99-101.
[11] 3-1. Fe3O4/PPy. (), 2013, 29(4): 27-29.
[12] 3-2. Fe3O4/CS. (), 2013, 29(5): 44-46.
[13] 7-1. Facile co-precipitation synthesis of shape-controlled magnetite nanoparticles. Ceramics International, 2014, 40(1, part B): 1519-1524.
[14] 5-2, . A novel chemical synthesis of bowl-shaped polypyrrole particles. Materials Letters, 2014, 126: 185-188.
[15] 5-2, . Polypyrrole films prepared on self-assembled silane monolayers and applications. Materials Technology: Advanced Performance Materials, 2015, 30(3): 182-188.
[16] 4-2. Fe3O4/PPy. , 2015, 46(5): 532-536.
[17] 5-2. Fe3O4/SiO2Cd2+. (), 2015, 36(3): 343-347,353.
[1] 201335-4
[2] 201456-5
[1] Ru8-5201010203792.420127
[2] 2, 6--(1, 1'-)(1, 2-d;4, 5-d')6-1201110455936.X140981820145
[3] /6-2201310250772.61840943201511
[4] 6-2201310251349.8176896720158
1966-198919962006
[1] 2008910. (4-1).
[2] . 200952. (4-1).
[3] . (21073113), 20111, 28. (7-3).
[4] Fe3O4/(21477069), 20151, 78. (7-3).
[5] M1/TiO2(M=Cu,Ag,Au,Pt,Pd,Ir). 21503122, 20161, 25. (6-3).
[1] (5-1). MCM-41,. 2005, 21 (12): 1838-1842.
[2] (6-1). Encapsulation of transition metal tetrahydroschiff base complexes in zeolite Y and theircatalytic properties for the oxidation of cycloalkanes. J. Mol. Catal. A: Chem. 2006, 249 (1): 23-30.
[3] (5-1). Copper tetra-hydrosalen complex encapsulated in zeolite Y: an efficient hetero geneous catalyst for the oxidation of cycloalkanes. Chinese. Chem. Lett. 2006, 17(3): 419-422.
[4] (6-1). YCo(II)Salen. 2006, 22 (8): 942-946.
[5] (4-1). Y. () 2006, 22(4): 6-11.
[6] (5-1, ). MCM-41Cu(). 2008, 24(9): 1450-1455.
[7] (4-1, ). YCo(Salprn).2009, 37(5): 635-640.
[8] (4-1, ). MCM-41Schiff. 2009, 38 (5): 486-452.
[9] (4-1, ). . 2009, 17 (12): 50-54.
[10] (4-1, ). SO42-/Fe2O3/ZnO/ZrO21,3-. 2011, 19 (9): 56-59.
[11] (4-1). Synthesis of Large Spherical Mesoporous Silica Using Tween-80 and Starch Hydrolysis Solution. Advanced Science Letters2012, 5 (1): 204-207.
[12] (4-1). Rapid Synthesis of Functional Carbon Microspheres: Preparation, Forming Mechanism and Application in Formic Acid and Ammonia Treatment. Science of Advanced Materials, 2013, 5 (6) :663-667.
[13] (8-3). A rapid and easy approach for the reduction of graphene oxide by formamidinesuln ic acid. Carbon, 2013, 54: 36-41.
[14] (5-3). Adsorption and decomposition of methylamine on a Pt(100) surface: a density functional theory study. RSC Adv., 2015, 5: 20208-20217.
[15] (6-6, ). Bipolar spin-filtering effectin B-or N-doped zigzag graphene nanoribbons with asymmetric edge hydrogenation. Physics Letters A, 2015, 379: 2860-2865.
[16] (6-5, ). Preparation of Cu2O/exfoliated graphite composites with high visiblelightphoto catalyticperformance and stability. Ceramics International, 2016, 42:13273-13277.
[17] (4-3, ). COPtAu(111)Pt(111). , 2016, 32(4): 950-960.
[1] /4-. (5-1)200910074916.076495320114.
[2] ZSM-48. (5-1) 201110020053.695059420115.
[3] Ru. (8-4)201010203792.4 201012.
[4] //(7-2)201010160176.5 20109.
[5] UZM-5. (4-1) 201110020066.3113726020115.
[6] (7-3)201310250780.0 201312.
[7] Ti- Beta(7-2)201310250820.1 201311.
1974-199720002010
[1] /(21107063)2011922(4-1)
[1] (3-1).Adsorption of antimony(V) on kaolinite as a function of pH, ionic strength and humic acid. Environmental Earth Sciences, 2010, 60:715-722.
[2] (3-1). Adsorption of antimony(III) and antimony(V) on bentonite: Kinetics, thermodynamics and anion competition. Microchemical Journal, 2011, 97: 85-91.
[3] (4-1). Adsorption of antimony(III) on goethite in the presence of competitive anions. Journal of Geochemical Exploration, 2013, 132: 201-208.
[4] (2-1). Removal of Sb(III) and Sb(V) from aqueous media by goethite. Water Quality Research Journal of Canada, 2013, 48: 223-231.
[5] (3-1). Adsorption of antimony on sediments from typical water systems in China: A comparison of Sb(III) and Sb(V) pattern. Soil and Sediment Contamination: An International Journal, 2014, 23: 37-48.
[6] (3-1). Antimony adsorption on kaolinite in the presence of competitive anions. Environmental Earth Sciences, 2014, 71: 2989-2997.
[7] (4-1). Comparison of masking agents for antimony speciation analysis using hydride generation atomic fluorescence spectrometry. Frontiers of Environmental Science & Engineering, 2015, 9: 970-978.
[8] (3-1). Adsorption of antimony on kaolinite as a function of time, pH, HA and competitive anions. Environmental Earth Sciences, 2016, 75:136-142.
[9] (5-1)Sb(III)pH200928(1)54-57
[10] (5-1)Sb(V)201041(1)38-42.
[11] (5-1). Sb(V)pH. ()201147(1)76-79
[12] (4-1)Sb(III) Sb(V)()201427(4)382-385
[13] (3-1)Sb(V)pH201344(4)875-878
[14] (4-1)Sb(III)()201551(2)96-99
[1] (5-1)201210340604.1ZL201210340604.120136
1972-200820064-820121-1220139-20149Simom Fraser
[1] 2008K3101-1
[2] 2011111823-1
[3] SPRACL20120121-1.
[4] 20150.26-1
[5] 2015348
[6] 2011011022-585-3
[7] PLGA2013011056-634-2
[8] 21375083857-3
[9] 2017 201721624-1
[10] . 2016, (2016-14)5. (6-1)
[1] (6-1). Study on the interferation of the concentration of free calcium in peripheral human lymphocyte by low dose penicillinusing Fura-2 as fluorescent probe. Chinese Chemical Letters, 2006, 17(5), 665-667.
[2] (6-2). Study on the effects of cefotaxime on intracellular Ca2+ in human peripheral lymphocytes by fluoremetry. Chinese Chemical Letters, 2007, 18(4), 424-427.
[3] (5-1). Interference study on the free calcium in the human peripheral lymphocyte by acrylamide. Chinese Chemical Letters, 2008, 19, 756-757.
[4] (4-1). SPE/HPLC/UV studies on acrylamide in deep-fried flour-based indigenous Chinese foods. Microchemical Journal, 2008, 89, 90-97.
[5] (4-1). Influence of Tg and Na+ on the calcium signaling of asthmatic lymphocytes. The fifth Shanghai International Symposium on Analytical Chemistry, Shanghai, 2010, 9, 169.
[6] (6-1). Detection of CD4+ T-lymphocytes from hemodialyzed patients by surface plasmon resonance. Chinese Chemical Letters, 2012, 23(12), 13931395.
[7] (5-1). HPLC-UV quantitative analysis of acrylamide in baked and deep-fried Chinese foods. Journal of Food Composition and Analysis, 2013, 31(1), 7-11.
[8] (10-1). Discrimination of multidrug resistance in different ovarian cancer cells using a single-cell bioanalyzer. Canadian Journal of Pure and Applied Sciences. 2017, 11(1), 4053-4060.
[9]5-3. SRN1N-. , 1995, 23 (8): pp 984-984.
[10]3-3. Na+/Ca2+ La3+. , 2002, 32(4), 367-374.
[11] 1-1. . , 2004, 27, 124-128 .
[12] 5-1. penicillin. , 2005, 24,166-168 .
[13] 5-1. G. 2006 B 30:38 .
[14] 5-1. . 2008 403
[15]5-2. . , 2009, 10(B), 085-087
[16] 4-1. . , 2010, 1, 44-47
[17] 4-1. . , 2010, 8, 718
[18] 5-1. HPLC6-. , 2013, 36(1), 80-83
[19] 4-1. . , 2013, 4(167) , 62-64
[20] 2-1. SPRiCD4+/CD8+T. 2012 2013 84
[21] 3-1. SPRCD4 T. 2015
[22] 5-3.. , 2016,39(1), 113-116.
2016
CIP(2016)110139
1967-19902003
[1] .(20081037)200852..
[2] .(2011011023-2)2011112.8.( 9-2).
[3] .(2016023)20161110.(8-1).
[1] (2-1). . . 2000,(1):36-37.
[2] (2-1). . . 2000,(3):51-52
[3] (5-1). . . 2002,19(5):380-383
[4] (4-1). . . 2005,(2):44-46.
[5] (4-1). . . 2005,22(3):216-219.
[6] (4-1). HDF-1. . 2005,(4):29-32.
[7] (3-1). Photocatalytic Isomerization of Norbornadiene Over Y Zeolites. React. Kinet. Catal. Lett. 2008,95(1),143-151.
[8] (2-1). . . 2011, 30(2), 6-8.
[9] (3-1). . . 2011,28(3):33-36.
[10] (2-1). . . 2011,8(2): 9-11.
[11] (2-1). Synthesis of TS-1 Films on Porous Supports for Epoxidation of Allyl Chloride by Hydrogen Peroxide. China Petroleum Processing and Petrochemical Technology. 2013,15(3),45-49.
[12] (4-3). A NOVEL CO-TEMPLATING METHOD FOR HIERARCHICAL MESOPOROUS ALUMINA MONOLITHS REPLICA. Functional Materials Letters. 2013,6(6) ,1350059 (4 pages).
[13] . Esterication by the Plasma Acidic Water: Novel Application of Plasma Acid. Plasma Science and Technology. 2014163223-225.
[14] (5-1). A Novel Deep Eutectic Solvent for Biodiesel Preparation Using a Homogeneous Base Catalyst. Chemical Engineering Journal. 2015,259647652.
[15](4-1).Morphology-controlled synthesis of mesoporous alumina dependent on triblock copolymer. CIESC Journal. 2015,66(9),3782-3787.
[16] (4-3). Synthesis of rod-like mesoporous -Al2O3 by an ionic liquid-assisted solgel method. Materials Letters. 2015.151,2023.
[1] . /. 2004-3-1.
[1] . (8-1)CN201010227381ZL 201010227381.92012.5.23.
1962-198519972006
[1] 2007-044-772007121(6-1).
[2] /-(2014011031-2)20141(7-4).
[3] 2014105-32014123(5-1).
[4] i-motifDNA2015023201512(5-3).
[1] . Excel2000.200218(2)34-37.
[2] (4-1)..200326(4)341-342.
[3] 3-1.. 200312(1)22-24.
[4] 3-3.. 200319(5)46-47.
[5] 2-1..200522(2)362-365.
[6] 5-1. Quantitative determination of zinc in milkvetch by anodic strippingvoltammetry with bismuth film electrodes. Talanta200565(4)10521055.
[7] 3-2..200716(4)4446
[8] 2-1..200929(1)33-35.
[9] 2-2..200926(1)5-8.
[10] 4-1.. 201019(1)79-80.
[11] 3-2.. 201120(6)1-3.
[12] 3-2.. 201228(4):37-39.
[13] 2-2..201235(3)55-57.
[14] 2-2. .201431(3) 352-355.
[15] ..201632(6)40-42.
[1] . 19938.
[2] . 2-1200310.
[1] (5-3). 201210340604.1ZL 201210340604.1. 20136
[2] (4-4). 2016201755145ZL201620175514.5. 20169.
1968-199172001
[1] 200304103200370.5(5-1)
[2] 20045036200451.6. (6-1)
[3] 2005K02200570.8(4-2)
[4] 200611038200671.5(6-1)
[5] 20113212011710(6-2)
[6] 2011K2201281.0(5-1)
[7] 201501920155(6-4)
[1](5-2)200120317-19
[2](5-2)200238180-83
[3](5-2)2002223483-484
[4](4-2)--2002226 1043-1044
[5](3-2)Flow Injection Hydride Generation AAS for the Indirect Determination of 6-Mercaptoprine, Atomic Spectroscopy, 2002, 23(5): 160-164.
[6](2-1)200218512-15
[7](3-2)--2003204513-516
[8](3-2)200312122-23
[9](3-1)200319546-47
[10](2-2)--200418125-26
[11](4-2)2004212355-358
[12](3-1)V 200413424-26
[13](4-2)2006234863-865
[14]20072304343542
[15](5-2)200723231-3239
[16] 2007 2911665-666686
[17](2-2)200817177-79
[18](5-1)-200929356-58
[19](5-1)2009253370-372
[20](5-2)201030238-41
[21](5-2)-2010, 325431-433
[22](3-1)Cloud Point Extraction for the Preconcentration of Silver and Determination by Flame Atomic Absorption SpectrometryProceedings of the 6th international conference on separation science and technology201010:56
[23](4-2)2011, 283: 1336-1338
[24](4-1)20112014-6
[25](5-2)2012,28626-27
[26](4-1)-2012,28332-34
[27] (3-1)Cloud Point Extraction for the Determination of Trace Amounts of Cobalt in Water and Food Samples by Flame Atomic Absorption Spectrometry. Journal of Spectroscopy, 2012, 2013(1)1-7
[28](4-1)-201332236-38
[29](6-1)201329137-39
[30](6-3)3,5,6,8--[4',3':4,5][2,3-d]4-2013, 29(6):28-3051
[31](6-3)A general sensing srategy for detection of Fe3+ by using amino acid-modified graphene quantum dots as fluorescent probeApplied Surface Science, 2016, 995-1002
[1]20028
[1] 3,5--(4-)(7-2)ZL 200710185313.970172920101124.
[2] 3,3--4,4-1,1-(4-1)201110216097.61254130 20130814.
[3] 3,3--4,4-8--5-(6-1)201110456522.91303768 20131113.
[4]9-4ZL 201210430609.321416912016706.
1964-19862006,
[1] .2005K03,,200570.7. (5-1).
[2] SBA-16M-Salen.(21346002)2013110.(8-4).
[3].(21301111)2014124.(6-2).
[4] .(2014021016-2)201413.(5-3).
[5] .20161102016115.(6-2).
[1] (5-1). 2,4,6-Triamino-1,3,5-triazin-1-ium 4-methylbenzenesulfonate monohydrate. Acta Crystallographica Section E2005, E61:o811- o813.
[2] (5-1). Bis{[tris(1H-benzimidazol-2-ylmethyl)amine]chlorobalt()}tetrachlorocobaltate()methanol tetrasolvate. Acta Crystallographica Section E2005, E61: m1067-m1069.
[3] (5-3). Bis(biguanido 2N,N) copper()dehydrate. Acta Crystallographica Section E2005, E61: 910912.
[4] (5-3). A co-crystal of 2-methylbenzimidazole and ammonium octamolybdate . Acta Crystallographica Section E2005, E61: 659-661.
[5] (5-5). Aminoacetato-2ONbisquinolin-8-olato-2ONcobaltmethanol solvate. Acta Crystallographica Section E2008, E64m795.
[6] (3-3).Al-.200831529-31.
[7] (4-1). .2009.02:37-39.
[8] (5-1). Bis(2,4,6-triamino-1,3,5-triazin-1-ium)hydrogen phosphate trihydrate. Acta Crystallographica Section E, 2010, E66: o239o240.
[9] (4-3). Sb(III)Sb(V). 2013, 27 (4): 382-385.
[10] (6-1). A Zinc(II) Complex Chelated by 1,10-phenanthroline Ligand: Synthesis, Crystal Structure and Hirshfeld Surface Analysis. ChemXpress2014, 5(02): 41-47.
[11] (4-1). .2014, 12.
[12] (5-3). .2014, 30(04): 28-29.
[13] (4-1)..2015, 12.
[14] (5-4). DFT + U investigation on the adsorption and initial decomposition ofmethylamine by a Pt single-atom catalyst supported on rutile (110)TiO2. Applied Surface Science2016389411418.
[1] . (3-1). 20056.
1958-1996
[1] (5-4). Spectrophotometric Determination Of Trace Copper(II) In Biological Samples With 2,4-Bis(4-Phenylazophenyl aminodiazo)Phenol. Journal of Analytical Chemistry, 2014, 69(04): 1-6.
[2] (5-4). Facile Synthesis of Thieno[2,3-d]pyrimidine Derivatives Using Inorganic Base Catalysis. Synthetic Communications, 2014, 44: 1-5.
[3] (6-2). -BFe3+. (), 2014, 30(02): 39-41+47.
[4] (5-5). SO42 /Fe2O3 /Al2O3 /ZnO/ZrO2. , 2014, 43(03): 507-509.
[1] 2, 6--(1, 1-)(1, 2-d;4, 5-d). (5-1), 201110455936.X: ZL 201110455936.X20127.
[2] 3,3-(2--1-)-4,4-. (4-3) 201310585124.6ZL 201310585124.62014 03.
[3] 2,2-(2--5--4-)-6,6-. (8-1)201410190010.6, : ZL 201410190010.6201408.
1965-19882010
[1] 5-24--2-200221(1)30-32
[2] 6-15--2--4-200626(3)18-20
[3] 7-146--2-200625(12)23-25
[4] 2-1Cd()200620(6)7-9
[5] L. Xu6-1. Spectrophotometric Determination of Nickel in Biological Samples Using 1-Azobenzene-3-(3-Hydroxyl-2-Pyridyl)-Triazene. Journal of Analytical Chemistry, 2008, 63(12): 1158-1163.
[6] 2-1200828(2)37-40
[7] 5-14--2-200825(3)319-321
[8] 2-12--5--3-200923(2)27-2850
[9] 4-11-(4,5--2-)-3-(4-)-()()201026(1)48-50
[10] 3-1BABRBBT201329(2)31-33
[11] 1-1Rap-Stoermer 201477(1)44-49
[12] 5-52,6--3,5-DNA()201632(1)38-4044
[1] 5-120066
[1] 200395-5
[2] 200686-3
[1] 3,5--4-7-1ZL 200710185313.9701729201011
[2] 3,3--4,4-8--5-7-4ZL 201110456522.91303768201311
[3] 3,3-(2--1-)-4,4-4-2ZL 201310585124.61823232201510
[4] 2,2'-2--5--4--6,6'-4-4ZL 201410190010.6203357520164
1981-200420072014
[11] i-motif DNA20140202015135-1
[12] i-motif DNA20151792015335-1
[13] i-motif DNA201502320151058-1
[14] 2014-B-0320156105-1
[1] (9-1). Aptamer/thrombin/aptamer-AuNPs sandwich enhanced surface plasmon resonance sensor for the detection of subnanomolar thrombin. Biosensors and Bioelectronics, 2013, 47: 265-270.
[2] (6-1). A turn-on fluorescent aptasensor for adenosine detection based on split aptamers and graphene oxide. Analyst, 2014, 139: 1843-1846.
[3] (5-1). A label-free fluorescent sensor for Pb2+ based on G-quadruplex and graphene oxide. Analytical methods, 2014, 6(20): 8120-8123.
[4] (6-1). A label-free fluorescent sensor for Hg2+ based on target-induced structure-switching of G-quadruplex. Analytical methods, 2014, 6(3): 662-665.
[5] (4-2). A graphene oxide-based fluorescent aptasensor for alpha-fetoprotein detection. Analytical Methods, 2016, 8: 6131-6134.
[1] 4-1201620177777XZL201620177777X2016727
[2] 4-12016201755130ZL20162017551302016727
[3] 4-12016201755145ZL20162017551452016921
1978-200320072012
[6] (3-1). Efficient Synthesis and Fungicidal Activities of 3,5,6,8-Tetrahydro-4H-thiopyrano[4',3':4,5]thieno[2,3-d]pyrimidin-4-ones, Phosphorus, Sulfur, and Silicon and the Related Elements, 2009, 184( 2 ),480-491.
[7] (3-1). Temperature-Dependent Regioselective Synthesis of 1,2,4-Triazino[2,3-b]indazoles and 3H-1,4-Benzodiazepines by Domino-Staudinger/Aza-Wittig/Isomerization Reaction, European Journal of Organic Chemistry, 2011, 34, 69336938.
[8] (3-1). Unexpected Synthesis of 2,4,5-Trisubstituted Oxazoles via a Tandem aza-Wittig/Michael/Isomerization Reaction of Vinyliminophosphorane, J. Org. Chem., 2012, 77(6), 2954-2958.
[9] (2-1). New efficient synthesis of trisubstituted imidazolidine-2-thiones and thiazoles via vinyliminophosphoranes. Tetrahedron, 2012, 68, 7984-7990.
[10] (3-1). Facile Synthesis of 3-Arylidene-3H-1,4-benzodiazepines by a Sequential Ugi/Staudinger/Aza-Wittig Reaction, Synthesis, 2016; 48(24): 4541-4547.
1978-2002200520102014201211201310
[1] . (21301111)2014124. (6-1).
[2] . (2015011017)201553. (5-1).
[3] . 20147 10. (1-1).
[4] 131. 2014 2. (1-1).
[5] /DNA. (2015021049)201553. (5-2).
[6] /DNA. (2015181)201533. (5-2).
[7] //DNA. (21016-105)201662. (6-2).
[8] . (2015019)2015105. (6-2).
[1] (6-1). A general sensing strategy for detection of Fe3+ by using amino acid-modified graphene quantum dots as fluorescent probe. Applied Surface Science, 2016, 389: 9951002.
[2] (6-1). Colorimetric detection of riboflavin by silver nanoparticles capped with-cyclodextrin-grafted citrate. Colloids and Surfaces B: Biointerfaces,2016, 148:l 6672.
[3] (6-1, ). Structures and spectroscopic properties of Ni(II) and Mn(II) complexes based on 5-(30, 50-dicarboxylphenyl) picolinic acid ligand. Journal of Molecular Structure, 2016, 1111: 126-131.
[4] (6-1, ). /Nafion. ,2016, 5: 705-708.
[5] (5-2, ). Preparation of Silver Nanoparticles Reduced by Formamidinesulfinic Acid and Its Application in Colorimetric Sensor. Journal of Cluster Science, 2016, 27(4): 12031212.
[6] (6-1). Controllable Assembly and Spectroscopic Behavior of Brilliant Cresyl Violet in different Environments. Journal of Applied Spectroscopy, 2016, 83(6): 1018-1027.
[7] (5-2). Self Assembly, Crystal Structure and Spectroscopy Properties of Two New Complexes with 1,10 phenanthroline 5,6 dione and SCN Ligands. Russian Journal of Coordination Chemistry, 2015, 41(7): 436-441.
[8] (5-1). Synthesis and characterization of grapheneCu nanocomposites by one-pot solvothermal approach. Applied Mechanics and Materials, 2015, 723524-527.
[9] (5-2). Graphene/SnO2/Citric Acid Nanocomposites as the Excellent Sorbent for Removal of Crystal Violet and Methylene Blue. Advanced Materials Research, 2015Vols. 1073-1076 pp 990-994.
[10] (4-2). A simple and green approach for the preparation of chemical reduced graphene oxide by using guanidine hydrochloride. , 2015, 9: 1-5.
[11] (6-1). L-. 2015, 3106: 31-33.
[12] (4-2). Al3+.2015 311 28-30.
[13] (6-1, ). Luminol/Nafion. , 2014, 35:74-77.
[14] (8-1). A rapid and easy approach for the reduction of graphene oxide by formamidinesulfinic acid. carbon, 2013, 54: 36-41.
[15] (5-1). Trinuclear-based coordination compounds of Mn(II) and Co(II) with 4-amino-3,5-dimethyl- 1,2,4-triazole and azide and thiocyanate anions:Synthesis, structure and magnetic properties. Inorganica Chimica Acta, 2011, 370: 102-107.
[16] (4-1). Synthesis and characterisation of Mn, Co and Cd coordination polymers of 1,2,4-triazole-3, 5-dicarboxylic acid. Dalton Trans, 2010, 39: 5877-5884.
[17] (6-1). A Molecular Helix: Self-Assembly of Coordination Polymers from d10 Metal Ions and 1,10-phenanthroline-5,6-dione (pdon) with the Bridges of SCN- and Cl- Anions. Crystal Growth & Design, 2010, 10: 1706-1714.
[18] (4-1). Tris[2-(1H-imidazol-2-yl) imidazol- 1-ido]-cobalt(III). Acta Crystallogr.Section E, 2010, E66, m500.
[19] (4-1). Bis[2-(1H-benzimidazol-2-yl)phenolato] dimethanolmanganese (III) chloride. Acta Crystallogr.Section E, 2010, E66: m523.
[20] (5-1). Bis(2,2-bi-1H- imidazole-2N3,N3) (thiocyanato-N)copper(II) chloride. Acta Crystallogr. Section E, 2009, E65: m1488-m1489.
[21] (3-1). 1,2-Bis(2-furylmethylene)hydrazine. Acta Crystallogr. Section E, 2008, E64: o2026.
[22] (2-1). SnO2-TiO2. 200837(3): 317-319.
[23] (2-1). TiO2 . 200723(3): 30-31.
[24] (4-2). . 30, 2016/7/1-4.
[25] (4-4, ). A 2D stairs coordination polymer based on 5-(3',5'-dicarboxylphenyl) picolinic acid. , 2015/7/25-29.
[1] . (3-2). 20123.
[1] . 20145. (6-3).
[1] . (5-1) CN201410490875.4213202920151.
[2] . (3-1) CN2015 20738547.15003750, 20162.
[3] . (3-1) CN201520929045.7, 510611320164.
[4] . (3-1) CN201520929039.1, 510680320164.
[5] . (3-2) CN20152 0738868.1, 498584120162.
[6] . (3-2) CN201520644366.24878601201512.
[7] . (3-2) CN20152 0191822.2, 449305920158.
[8] . (3-2) CN201520158511.6454054620158.
1970-199420022013
[1].\2003033.2003121.5.(6-1).
[2].(20051031)20057 8.(6-2).
[3].205750572006152. (5-3).
[4]./2009011015-1200918. (8-6).
[5].2117508520121120. (10-7).
[6].213750832014185. (8-5).
[7].. (2015104)201573. (8-1).
[8]i-motif DNA201515. (5-4).
[9]i-motif DNA201515. (8-5).
[1] (6-1)..20022361044 -1046.
[2] (5-4).SPR.200222133-36.
[3] (7-1)..200361(1) 137 -140.
[4] (6-3)Flow injection renewable drops spectro- fluorimetry for sequential determinations of Vitamins B1, B2, B6. Anal Chim Acta, 2004, 527(2)187-193.
[5] (4-1). B2B6.2005 9(3) 136 -139.
[6] (3-3)..200525 (3)53-57.
[7] (4-1). ...2005200(T-006)
[8] (3-3). (2-)-3,3,5,5.200627(5)863-866.
[9] (3-3). Spectrofluorimetric study of the interaction of copper (II) and bis-heterocyclictriazene reagent in the presence of -cyclodextrin. Anal Chim Acta, 2006, 575: 68-75.
[10] (4-1). Studies on the reaction between vitamin B6 and bovine albumins by flow injection renewable drops fluorimetry. Proceedings of the first Shengyang international colloquium on Microfluidics. ShengYang, China, 2007, 10: 143-144.
[11] (5-1). 200824526-29.
[12] (6-1). .20082871612 -1615.
[13] (7-3). 1-(8-)-3-(2-)-. 200829(6)1133 -1136.
[14] (7-3). 1,8-(2-). 200829(8)1560 -1563.
[15] (7-1). 200827 (s2)44-47.
[16] (6-3). Synthesis and Analytical Application of Bis(2-diazoaminobenzo thiazoyl) -benzidine for the Determination of Mercury Ion by Fluorimetry. Chemical Research in Chinese Universities2009, 25(2): 628-632.
[17] (7-3). B6 ()200925(1)34-36+39.
[18] (7-3).200928(1)59-62.
[19] (7-3).B6200928(10)21-25.
[20] (8-4). A novel chemosensor for Fe (III) based on phosphorescence quenching of 9-bromophenanthrene induced by -cyclodextrin combining with flow injection renewable drop. Analytical Letters, 2010, 43(4): 711-720.
[21] (5-4).-201046 (1)1-4.
[22] (4-3).B12201128 (3)1331-1335.
[23] (5-2). Silica nanoparticles based label-free aptamer hybridization for ATP detection using hoechst33258 as the signal reporter. Biosensors and Bioelectronics, 2011, 29(1), 46-52.
[24] (7-4).IgY201233(6)1177-1181.
[25] (5-1). Covalent conjugation of avidin with dye-doped silica nanopaticles and preparation of high density avidin nanoparticles as photostable bioprobes. Biosensors and Bioelectronics 2012, 37(1), 75-81.
[26] (5-2). MUC-1 aptamer-conjugated dye-doped silica nanoparticles for MCF-7 cells detection. Biomaterials 2013, 34(2), 371-381.
[27] (6-4).A label-free fluorescent sensor for Hg2+ based on target-induced structure-switching of G-quadruplex. Analytical methods, 2014, 6(3): 662-665.
[28] (6-4).A turn-on fluorescent aptasensor for adenosine detection based on split aptamers and graphene oxide. Analyst, 2014, 139: 1843-1846.
[29] (5-3).A label-free fluorescent sensor for Pb2+ based on G-quadruplex and graphene oxide. Analytical methods, 2014, 6(20): 8120-8123.
[30] (3-1).Protein A-Conjugated Dye-doped Silica Nanoparticles for Detection of E. Coli O157:H7 Based on Indirect Immunofluorescence Microscopy and Flow Cytometry Technique. 6th International Symposium on Bioanalysis, Biomedical Engineering and Nanotechnology, Changsha, 2014. 5. 29-31
[31] (6-1). Indirect immunofluorescence detection of E. coli O157: H7 with fluorescent silica nanoparticles. Biosensors and Bioelectronics, 2015, 66, 95-102.
[32] (7-3). Sensitive detection of carcinoembryonic antigen using surface Plasmon resonance biosensor with gold nanoparticles signal amplification. Talanta, 2015, 140, 143-149.
[33] (9-6).Capillary electrophoretic study of green fluorescent hollow carbon nanoparticles. Electrophoresis, 2015, 36, 2110-2119.
[34] (9-6).Sensitive determination of kaempferol using carbon dots as a fluorescence probe. Talanta, 2015, 144, 390-397.
[35] (7-4). -. 201536(8)206-210.
[36] (7-5).5201536(18)85-88.
[37] (6-3).Cu2+201534(6)717-721.
[38] (7-3).()201531(4)33-37.
[39] (4-3). A highly selective and commercially available fluorescence probe for palladium detection. Sensors and Actuators B: Chemical, 2016, 232: 611-618.
[40] (7-5).4 201637(4)73-76.
[41] (6-2).BCu2+201638(7)673-676685-687.
[1]. .20077.4-2.
[2]. . 20082. 4-2.
[1]. .4-3ZL 2005 1 0012653.230954120072.
[2]. 3,3,5,5-.4-3200510012799.7.
[3]./. (6-6), 200610102223.4 200811.
[4]. 1-(8-)-3-(2-)-. 5-3200810054989.9 20106.
[5]. (8-)-. 5-3200810054990.1 20108.
[6]. 1,8-(2-). 5-3200810054987.X 20129
[7].(2-)-. 5-3200810054988.4
1978-20007200372012201210201312
[1]CO221506120201520. (6-1).
[2]SAPO-342016-10420163. (5-1).
[1] (6-1). A DFT theoretical study of CH4 dissociation on gold-alloyed Ni(111) surface, Journal of Natural Gas Chemistry, 2011, 20: 611-617.
[2] (6-1). CH4 dissociation on NiCo (111) surface: A first-principles study, Applied Surface Science, 2011, 257: 8955-8964.
[3] (6-1). A first-principles study of C plus O reaction on NiCo(111) surface, Applied Surface Science, 2011, 257: 9455-9460.
[4] (3-1). CH4Fe(111), 201243(5): 319-324. ()
[5] (6-1). Insight into CH4 dissociation on NiCu catalyst: A first-principles study, Applied Surface Science, 2012, 258: 8177-8184.
[6] (3-1). Fluorescence of tryptophan in aqueous solution, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2013, 106: 5459.
[7] (3-1). The substitution reaction of (CNC)Fe2N2 with CO, Journal of Molecular Modeling, 2013, 19: 26252633.
[8] (7-1). Study on carbon deposition associated with catalytic CH4 reforming, Fuel, 2013, 113: 712718.
[9] (6-1). CH4 dissociation on the perfect and defective MgO(001) supported Ni4, Fuel, 2014, 123: 285-292.
[10] (5-2). Insight into C+O(OH) reaction for carbon elimination on different type of CoNi(111) surfaces: A DFT study, RSC Advances, 2015, 5: 19970-19982.
[11] (5-2). Interaction between bimetal cluster Ni2Co2 and MgO and its effect on H adsorption and H2 dissociation: A DFT study Applied Surface Science, 2016, 390:7-12.
[12] (4-1). 2016,13(10):221-222
1977-200020032007
[1] . 2083301020091220. 8-5.
[2] /. 510721052011137. 8-3.
[3] . 2012021020-5201214. 5-3.
[4] . 2015178201412. 5-4.
[5] Fe3O4/PPy.201422-22014110. 5-3.
[6] . 2014105-5201413. 6-3.
[1]5-2. Preparation of Lanthanide Hydrides of Nanometric Size by the Catalytic Method, Chin. J. Chem., 2002, 20(11): 1450~1452
[2]1-1. 2005, 5:106-107
[3]3-1.2005121-3
[4]4-1.Ni-B/2007284:351-356
[5]4-1.SiO2Ni-B2007239:1311-1315
[6]2-1. 2008378:516-518
[7]1-1.2008245:24-2529.
[8]4-1. NiB2011,27(4):953-958
[9]4-1. Chitosan-mediated preparation of porous amorphous NiB nanoparticles from silver-catalyzed electroless plating, Advanced Materials Research , 2012, 361-363 : 565-568
[10]2-2. , 201222:3070~3074
[11]4-1.2013295:48~50
[12]6-1.Preparation and characterizations of platinum electrocatalysts supported on thermally treated CeO2C composite support for polymer electrolyte membrane fuel cells, Electrochimica Acta , 2014, 139: 308-314
[13]4-1.Expanded Vermiculite Applied in the Catalytic Process as a Catalyst Support, Applied Mechanics and Materials, 2014, 556-562
[14]6-3.Fabrication of nanofibrous A- or B-sites substituted LaCoO3 perovskites with macroscopic structures and their catalytic applications, Materials Research Bulletin, 2014,51: 295-301
[15]6-1.Synthesis and characterizations of palladium catalysts with high activity and stability for formic acid oxidation by hydrogen reduction in ethylene glycol at room temperature, Journal of Power Sources, 2015, 294: 556-561
[16]4-3.V2 O5 -K2 SO4 / Al2 O3 -SiO2 201530:445-450.
[1]. 4-20214735.0ZL 0214735.020058.
[2] . 2-2201010228507.4ZL 201010228507.420144.
[3] 3,3-2--1--4,4-. 4-1201310585124.6ZL 201310585124.620158.
1978-200120072010
[1]SBA-16M-Salen(21346002)20131010. (8-1).
[2]. (2014021016-2)201483. (5-1)
[3]M1/TiO2(M=Cu,Ag,Au,Pt,Pd,Ir)(21503122)2015820. (6-1).
[4]. (2015031017) 2015810. (6-2).
[5]SCR. (2015022) 2015720. (8-2).
[1] (3-1). Mo(100). , 2009, 25(11): 2336-2342.
[2] (4-1). C(N, O)Mo(100). , 2008, 24(08): 1366-1370.
[3] (3-1). Pd(111) Pd(111) . , 2009, 12(30): 1269-1275.
[4] (3-1). Methylamine decomposition on nickel surfaces: a density functional theory study. Surface Science. 2010, 604: 779-787.
[5] (3-1). Methane combustion on Pd-based model catalysts: structure sensitive or insensitive? The Journal of Chemistry Physics. 2009, 131: 144704.
[6] (5-1). First-principles analysis of the CN bond scission of methylamine on Mo-based model catalysts. The Journal of Chemistry Physics. 2010, 132: 044111.
[7] (4-1). Decomposition of methylamine on nitrogen atom modified Mo(100): a density functional study. Physical Chemistry Chemical Physics, 2012, 14: 6869-6882
[8] (4-2). Decomposition of methylamine on mo(100) surface: a DFT study. Journal of Natural Gas Chemistry, 2012, 21(2): 132-137.
[9] (4-1). Reaction mechanism of methylamine decomposition on Ru(0001): a density functional theory study. J Mol Model, 2014, 20: 2137.
[10] (3-1). A DFT study of methanol oxidation on Co3O4. Catalysis Communications, 2014, 45: 83-90.
[11] (3-1). Origin of CO promotedmethanol oxidation in alkalinemedia catalyzed by gold: A first-principle investigation. Catalysis Communications, 2015, 60: 60-64.
[12] (3-2). Chemisorbed oxygen atom on the activation of CH bond in methane: a Rh model study. RSC Advances, 2015, 5: 66221-66230.
[13] (5-1). DFT + U investigation on the adsorption and initial decomposition ofmethylamine by a Pt single-atom catalyst supported on rutile (110)TiO2. Applied Surface Science, 2016, 389: 411-418.
[14] (4-1). Reaction mechanism of ethylene glycol decomposition on Pt modelcatalysts: A density functional theory study. Applied Surface Science, 2016, 390: 1015-1022.
[1] . 2012(1-1) .
[2] . 20145(6-4) .
[1] Ti-Beta.(7-4) 201310250820.1CN201310250820.1 20136.
[2] . (7-1)201310250780.0ZL 201310250780.0201312.
1979- 200220092013201210201310
[1] /DNA. (2015021049)201553. (5-1).
[2] /DNA. (2015181)201533. (5-1).
[3] //DNA. (21016-105)201662. (6-1).
[4] . (2015019)2015105. (6-1).
[5] . (21301111)2014124. (6-3).
[6] . (2015011017)201553. (5-2).
[1] (6-2, ). A general sensing strategy for detection of Fe3+ by using amino acid-modified graphene quantum dots as fluorescent probe. Applied Surface Science,2016, 389: 9951002.
[2] (6-2, ). Colorimetric detection of riboflavin by silver nanoparticles capped with-cyclodextrin-grafted citrate. Colloids and Surfaces B: Biointerfaces,2016, 148:l 6672.
[3] (6-2). Structures and spectroscopic properties of Ni(II) and Mn(II) complexes based on 5-(30, 50-dicarboxylphenyl) picolinic acid ligand. Journal of Molecular Structure, 2016, 1111: 126-131.
[4] (6-4). /Nafion. , 2016, 5: 705-708.
[5] (5-1). Preparation of Silver Nanoparticles Reduced by Formamidinesulfinic Acid and Its Application in Colorimetric Sensor. Journal of Cluster Science, 2016, 27(4): 12031212.
[6] (6-2, ). Controllable Assembly and Spectroscopic Behavior of Brilliant Cresyl Violet in different Environments. Journal of Applied Spectroscopy, 2016, 83(6): 1018-1027.
[7] (5-1). Self Assembly, Crystal Structure and Spectroscopy Properties of Two New Complexes with 1,10 phenanthroline 5,6 dione and SCN Ligands. Russian Journal of Coordination Chemistry, 2015, 41(7): 436-441.
[8] (5-2). Synthesis and characterization of grapheneCu nanocomposites by one-pot solvothermal approach. Applied Mechanics and Materials, 2015, 723524-527.
[9] (5-1). Graphene/SnO2/Citric Acid Nanocomposites as the Excellent Sorbent for Removal of Crystal Violet and Methylene Blue. Advanced Materials Research, 2015Vols. 1073-1076 pp 990-994.
[10] (4-1). A simple and green approach for the preparation of chemical reduced graphene oxide by using guanidine hydrochloride. , 2015, 9: 1-5.
[11] (6-5). L-. 2015, 3106: 31-33.
[12] (4-1).BAl3+. 2015 3101 28-30.
[13] (6-2). Luminol/Nafion. , 2014, 35: 74-77.
[14] (6-1). A general strategy to create RNA aptamer sensors using regulated graphene oxide adsorption. ACS Applied Materials & Interfaces, 2014, 6: 21806-21812.
[15] (8-2). A rapid and easy approach for the reduction of graphene oxide by formamidinesulfinic acid. carbon, 2013, 54: 36-41.
[16] (5-1). Synthesis of neutral red covalently functionalized graphene nanocomposite and the electrocatalytic properties toward uric acid. Journal of Materials Chemistry, 2012, 22: 602-608.
[17] (5-1). Spectroscopic studies on the inclusion interaction of p-sulfonatocalix[6]arene with vitamin B6. Journal of Inclusion Phenomena and Macrocyclic Chemistry, 2012, 72: 389-395.
[18] (5-2). Study on the inclusion behavior of p-sulfonatocalix[6]arene with propranolol by spectrofluorometry. Spectrochimica Acta Part A: Molecularand Biomolecular Spectroscopy, 2012, 97: 155-160.
[19] (6-1). Assemblies of brilliant cresyl violet to DNA in the presence of -cyclodextrin. Talanta, 2010, 82: 681-686.
[20] (4-1). Study on the inclusion interaction of ethyl violet with cyclodextrins by MWNTs/Nafion modified glassy carbon electrode. Journal of Inclusion Phenomena and Macrocyclic Chemistry, 2010, 68: 467-473.
[21] (4-1). Electrochemical behavior of brilliant cresyl violet at multi-wall carbon nanotubes/Nafion modified glassy carbon electrode and its interaction with cyclodextrins. J Incl Phenom Macrocycl Chem, 2009, 64: 115-120.
[22] (4-1). Study on the supramolecular systems of two basic violets with cyclodextrins by MWNTs/Nafion modified glassy carbon electrode. Chinese Chemical Letters, 2009, 20: 981-984.
[23] (6-1). Aggregation behavior of phenosafranine at MWNTs/Nafion modified electrode. 5th Shanghai International Symposium on Analytical Chemistry (analytica China Conference 2010), 124-125, Shanghai, 2010.
[24] (2-2). SnO2-TiO2. 200837(3): 317-319.
[25] (2-2). TiO2 . 200723(3): 30-31.
[26] (4-1). . 30, 2016/7/1-4.
[27] (4-1). A 2D stairs coordination polymer based on 5-(3',5'-dicarboxylphenyl) picolinic acid. , 2015/7/25-29.
[1] . (3-1) CN20152 0738868.1498584120162.
[2] . (3-1)CN201520644366.24878601201512.
[3] . (3-1) CN2015 2 0191822.2449305920158.
[4] . (3-1)CN201520158511.6454054620158.
[5] . (5-2) CN201410490875.4213202920151.
[6] . (3-2) CN 201520738547.1500375020162.
[7] . (3-2) CN201520929045.7510611320164.
[8] . (3-2)CN201520929039.1510680320164.
1979-20032010
[1] 2012021006-12012, 56-1
[2] (2015178), , 2015, 2, 5-1
[3] (2014105-5), 2015, 3, 6-1
[4] /201701D121016, 201736-1
[1] 4-1, 2012, 31, 1631-1640.
[2] 4-1, , 2013, 29(3): 40-42.
[3] 5-1Cu2O, , 2014, 30(6), 33-35.
[4] 6-1, 2014, 35, 530-534.
[5] 6-1Magnetically recoverable Cu2O/Fe3O4 composite photocatalysts: Fabrication and photocatalytic activity. Chinese Chemical Letters, 2014, 25, 287-291.
[6] 4-1Abnormal electrochemical behaviors of ionic liquid confined into nanopores of silica gel matrix. Chinese Journal of Electrochemistry, 2014, 20(2), 121-127.
[7] 7-1Facile synthesis of macroporous silicon photocathodes with enhanced photoelectrochemical performance. Materials Letters, 2014, 128, 148-151.
[8] 5-1, Preparation and characterizations of carbon-supported PtOs electrocatalysts via a polyol reduction method for methanol oxidation reaction. Journal of Power Sources, 2014, 268, 824-830.
[9] 5-1, Preparation and characterizations of highly dispersed carbon supported PdxPty/C catalysts by a modified citrate reduction method for formic acid electrooxidation. Journal of Power Sources, 2014, 254, 183-189.
[10] 7-1, Highly active carbon supported Pd/C catalysts decorated by a trace amount of Pt by an in-situ galvanic displacement reaction for formic acid oxidation. Journal of Power Sources, 2015, 278, 332-339.
[11] 5-52015, 34(11), 3915-3925
[12] 8-1, Highly stable and efficient platinum nanoparticles supported on TiO2@Ru-C: investigations on the promoting effects of the interpenetrated TiO2. Electrochimica Acta, 2016, 216, 8-15.
1983 -200620092012
[1] . (21375083), 2014185. (9-2).
[2] Cd2+Cu2+Hg2+. (2015025), 201510, 10. (7-1).
[3] . (21671123), , 20171, 65. (10-4).
[1] Yuzhen Wang (7-1). Development of a highly sensitive and specific monoclonal antibody-based enzyme-linked Immunosorbent assay (ELISA) for detection of sudan I in food samples. Talanta, 2009, 77(5):1783-1789.
[2] Yuzhen Wang(6-2). Establishment of an immunoaffinity chromatography for simultaneously selective extraction of Sudan I, II, III and IV from food samples. Journal of Chromatography A, 2010, 1217:78407847.
[3] Yuzhen Wang (4-1). A sensitive and selective direct competitive enzyme-linked immunosorbent assay for fast detection of Sudan I in food samples. J Sci Food Agric, 2011, 91:18361842.
[4] (3-2). 18-. , 2011, 23(5):622-625.
[5] Yuzhen Wang(5-2). Preparation and characterization of molecularly imprinted microspheres for selective extraction of trace melamine from milk samples. Microchim Acta, 2011, 174:191199.
[6] Yuzhen Wang (7-1). Highly sensitive and specific determination of mercury(II) ion in water, food and cosmetic samples with an ELISA based on a novel monoclonal antibody. Anal Bioanal Chem, 2012, 403:25192528.
[7] (5-1). . ()2013, 29(03):36-39.
[8] Yuzhen Wang(8-1). A femtogram level competitive immunoassay of mercury(II) based on surface-enhanced Raman spectroscopy. Chemical Communications, 2014, 50:9112-9114.
[9] (4-4, ). . , 2016, 28(4):432-436.
[10] (4-1). . ()2016, 32(06):36-39.
[11] (3-2). TiO2/CdS. (), 2016, 32(05):34-37.
1979-,200220052013
[1] .(2013-B-01)20131210.(6-1).
[1] Zhen Lu(5-1).Triindole-cored star-shaped molecules for organic solar cells[J].Journal of Materials Chemistry A,2013,1,76577665.
[2]Zhen Lu(5-1).6,7-DIALKOXY-2,3-DIPHENYLQUINOXALINE BASED CONJUGATED POLYMERS FOR SOLAR CELLS WITH HIG CIRCUIT H OPEN- VOLTAGE[J].Chinese Journal of Polymer Science,2013,31(6),901-911.
[3] Zhen Lu(7-2).The enhanced photovoltaic performance of fluorinated acenaphtho 1,2-b quinoxaline based low band gap polymer.Polymer,2015,71,43-50.
[4] Zhen Lu(4-2).The side chain effect on difluoro-substituted dibenzo a,c phenazine based conjugated polymers as donor materials for high efficiency polymer solar cells. Polym. Chem, 2015, 6 (9), 1613-1618.
[5] Zhen Lu(5-1).The effect of meta-substituted or para-substituted phenyl as side chains on the performance of polymer solar cells[J]. Synthetic Metals,2016220402-409.
[6] Zhen Lu(8-1).The Influence of Fluorination on Nano-Scale Phase Separation and Photovoltaic Performance of Small Molecular/PC71BM Blends [J],Nanomaterials,2016,6,80,1-12.
[7] Zhen Lu(9-2).Elimination of the J-V hysteresis of planar perovskite solar cells by interfacial modification with a thermo-cleavable fullerene derivative. Journal of Materials Chemistry A, 2016, 4 (45), 17649-17654.
[1] 2,2`-2--5--4--6,6`-., 4-1:ZL201410190010.6, 2033575,201604.
[2] -.(1-1):ZL201520913675.55105075,201604.
[3] .(1-1):ZL201520913673.65278503,201606.
[4] .,(1-1):ZL201521023615.25269188,201606.
[5] .,(1-1):CN201620330641.85530142,201604.
[6] .(1-1):CN201620284842.9 5542722,201609.
[7] .(1-1):CN201620228286.35549320,201609.
[8] .(2-1):CN201620227232.55548784,201609.
[9] .(2-1):CN201620206340.45548076,201609.
[10] .(2-1):CN201620159853.4 5548078,201609.
[11] .(5-1) :ZL201620306219.95707927,201611.
1982-)200720102013
[1]i-motifDNA.(2014020)201513. (5-5).
[2]i-motifDNA.(2015023)2015105. (8-8).
[3].20151042015103. (8-8).
[1](4-1).The development of a novel chemiluminescent glucose sensor using hydrophilic Co3O4@SiO2mesoporous nanoparticles. Anal. Methods, 2016, 8(14), 2923-2927.
[2](5-5).Cu2+Hg2+.302016.
1974-199720062012
[1] .(2014-B-14)2015610.1-1.
[2] .(2014-B-11)2015610.5-4.
[1] 5-2. Enzymatic pretreatment of activated sludge, food waste and their mixture for enhanced bioenergy recovery and waste volume reduction via anaerobic digestion. Applied Energy, 2016, 179: 1131-1137.
[2] 2-1..,2016,3:36-39.
1971-19932003
[1] XJY20111122011110.55-4
[2] 2014105-320141235-4
[3] 21671123201687812-8
[1]1-1200016324-26
[2]1-1200218351-53.
[3]5-5200218680-82
[4]2-2200319477-78
[5]5-12--3--5-(II)200514431-33
[6]4-22--3--5-2005225966-968
[7]4-4NO2-NO3-200610286-88
[8]2-2200824132-33+40
[9]5-12008252205-208
[10]3-1 200925140-41
[11]3-3-201026335-36+49
[12]5-1201027(4)1607-1609
[13]5-1RP-HPLC()201026435-38
[14]4-3201127543-44
[15]3-2201228432-33
[16]2-2-20133052475-2477
[1] .2003
[2] 2009
[1] 35--4-7-3ZL 2007 1 0185313.9201011
1968-19911999
[1] .2004K820041. 5-1.
[2] .2008K6200870.9.5-1.
[1] 5-2,Simultaneous determination of catecholamines by ion chromatography with direct conductivity detection.Talanta,2000501197-1123SCI.
[2] 1-1.200413127-29.
[3] 1-1NO2-NO3-.200617286-88.
[4] 1-1.-2007448765-767.
[5] 2-2RP-HPLC.09-P-068.
[6] 2-1HPLC.09-P-055.
[7] 2-1.()201026(2)38-40+53.
[8] 5-2RP-HPLC.201026435-38.
[9] 2-2HPLC.201329148-4980.
[1] .5-320004.
[1] 4,4-[5,6--2-]-3,3-.4-2ZL200810080130.516097.620138.
1966-19882007
[1] . (200310), 200311, 6. (6-2).
[2] . 2008910. (2-2).
[3] . (20090980), 20099, 7.5. (6-2).
[4] . 21175085. 20121120. (10-4).
[1] (2-2). . . 1999, 15 (06): 66-6871.
[2] (2-2). , . 2003, 17 (02): 25-27.
[3] (2-1). , . 2004, 19 (02): 14-16.
[4] (2-1). , . 2003, 19 (05): 37-40.
[5] (2-2). APSABT(), . 2004, 278-281.
[6] (4-1). . , 2004, 20 (05), 23-25.
[7] (7-1). 2-. , 2004, 24 (5), 5-7.
[8] (3-1). 1- (4-) -3- (8-) -. , 2006, 23(4)827-830.
[9] (3-2).. 200724 (5)86-89.
[10] (3-2). 1-4--2--4-. 2008, 27 (2), 54-57.
[11] (4-4). A new selective fluorescent probe for lead ions. Chinese Chemical Letters, 2008, 20: 326-329.
[12] (5-1). . 2010, 22 (10): 1929-1939.
[13] (5-1). . , 2011, 32 (1): 62-66.
[14] (5-1). . 201329 (04), 34-36,39.
[15] (6-1). Development and cell imaging applications of a novel fluorescent probe for Cu2+. RSC Adv., 2015, 5: 6945369457.
[16] (4-1, ). Hg2+. 201632 (02): 41-43.
[17] (4-1, ). . 201638(2): 153-156.
[18] (4-1). Crystal structure of 4-(4-((3-bromophenyl)amino)-6-(tert-butyl)-3-(2- hydroxypropan-2-yl)cinnolin-8-yl)-2-methylbut-3-yn-2-ol, C26H30BrN3O2. Z. Kristallogr. NCS , 2016, 0138.
[1] pH, (6-3)CN200810079711.7, 720000201012.
[2] . (7-1)CN201010601070.4.
1979-2003720117
[1](2013Q3) 20131(5-1).
[2]CO221506120201520. (6-3).
[3]SAPO-342016-10420163. (5-4).
[4](2016K5) 20171(5-1).
[1] (4-1). N--N-, (), 2010, 30(1):77-80.
[2] (4-1). N--N-, , 2013,196(5):38-41.
[3] (5-1). Synthesis of Piperazine Derivatives and Biological Evaluation of Its Inhibitory Activities on Vascular Smooth Muscle Cell Proliferation, Asian Journal of Chemistry, 2015, 27(4): 1299-1303.
[4] (5-1). N-[3-(2-)]-N-,,2015, 25(6):442-445.
[5] (6-1). N-2--N-, , 2016, 36(1):16-19.
[6] (4-1). -H2O2,,2016, 33(10):31-34.
[7] (5-2). CH4/CO2Ni-Co,, 2016,45(5):944-947.
[8] (5-2). , , 2016, 30(4):4-5.
[9] (4-1). , , 2017, 2:12-14.
[10] (3-2). Synthesis of aryl acetamides by aminocarbonylation of benzylic chlorides using carbamoylsilane as an amide source, Synthetic Communications, 2017, 47(7):704-709.
[11] (4-2). ----, , 2017,37:1-8.
1977-200220052015
[1] . (21301111)2013821. (6-4).
[2] . (2015011017)20153. (5-3).
[3] /DNA. (2015021049)20153. (5-3).
[4] /DNA. (2015181)20153. (5-3).
[5] . (2015019), 20155. (6-5).
[6] . (2015-B-03)201610. (5-1).
[7] (5mg)(0.25g). 201625. (8-1).
[8] //DNA. (21016-105)20162. (6-4).
[1] (3-1). 1,4-DNI2,4-DNI. 2005 13(3)141-143.
[2] (4-1). 2,4-DNI. 200513(4)269-272.
[3] (3-2). 1,4-. 200528(3)60-62.
[4] (3-2). 4,5-. 200614(5)349-351.
[5] (3-1). 4-. ()200627(4)331-334.
[6] (3-3). 3,5-(4-)Ni(). 200926(5)1179-1182.
[7] (5-2). 3,5-(3--2-)-2,4,6-. 200929(10)28-31.
[8] (4-4). 3,5-(1--4,5--2-)(II). 201027(3)1125-1127.
[9] (7-1). 2,4-. 201018(1)1-3.
[10] (5-2). 1-()-3-(4,5--2-)-(). 201128(2)875-877.
[11] (5-2). 4,4-(4-)(). 201128(5)2620-2622.
[12] (5-1). 1,4-DNI. ()201127(2) 37-38+47.
[13] (5-1). Synthesis of the novel polysubstituted N,N'-Phenylene-bis(pyrrole-3,4-dicarboxylates) via the double 1,3-Dipolar cycloaddition reactiond. 14th International Symposium on Advancing the Chemical Sciences, 2014, 14:143.
[14] (4-1). Double 1,3-Dipole cycloaddition-extrusion reaction of DMAD to bimnchnone: synthesis of asymmetric polysubstituted N,N-Phenylene-Bis(pyrrole-3,4