Bibliographic.docx

1、Bibliographic1 Bibliographic Information MWCNT-based Ag2S-TiO2 nanocomposites photocatalyst: ultrasound-assisted synthesis, characterization and enhanced catalytic efficiency. Zhu, Lei; Meng, Ze-Da; Oh, Won-Chun. Department of Advanced Materials Science & Engineering, Hanseo University, Chungnam, S.

2、 Korea. Journal of Nanomaterials (2012), 586526, 10 pp. Publisher: Hindawi Publishing Corp., CODEN: JNOABP ISSN: 1687-4129. Journal; Online Computer File written in English. AN 2012:1116139 CAPLUS AbstractMultiwalled carbon nanotube based nanoscale Ag2S and TiO2 composites have successfully synthesi

3、zed via a facile ultrasound-assisted method. The nanocomposites were characterized by Fourier transform IR (FT-IR) spectroscopy, UV-vis absorption spectra, BET surface area measurements, X-ray diffraction (XRD) and transmission electron microscopy (TEM). The Ag2S-TiO2/CNT nanocomposites exhibited mu

4、ch higher photocatalytic activity than pure TiO2 for the degrdn. of Rhodamine B (Rh.B) under UV and visible light. The improved photocatalytic activities may be attributed to increased adsorbability of Rh.B mols. and increased charge transfer rate in the presence of a one-dimensional MWCNT network.

5、Indexing - Section 74 (Radiation Chemistry, Photochemistry, and Photographic and Other Reprographic Processes) Citations1) Elfeky, S; Journal of Nanomaterials 2011, 2011, 5704382) Poliah, R; Journal of Nanomaterials 2011, 2011, 2392893) Yu, J; Physical Chemistry Chemical Physics 2011, 13(8), 34914)

6、Yu, J; Nanoscale 2012, 4(8), 26705) Xiaodan, Y; Materials Characterization 2006, 57(4-5), 3336) Su, H; Journal of Materials Chemistry 2001, 11(2), 6847) Zhao, W; Applied Surface Science 2010, 256(11), 34938) Zhu, L; Chinese Journal of Catalysis 2012, 33, 2549) Andrews, R; Accounts of Chemical Resear

7、ch 2002, 35(12), 100810) Ruan, S; Polymer 2003, 44(19), 564311) Xu, Y; Polymer 2005, 46(3), 79912) Wang, F; Carbon 2005, 43(8), 171613) Banerjee, S; Advanced Materials 2004, 16(1), 3414) Liu, Y; Materials Chemistry and Physics 2005, 91(2-3), 36515) Kim, H; Journal of Crystal Growth 2003, 255(1-2), 1

8、1416) Cho, N; Advanced Materials 2007, 19(2), 23217) Cope, R; British Journal of Applied Physics 1965, 16(10), 150118) Hodes, G; Nature 1976, 261(5559), 40319) Kryukov, A; Theoretical and Experimental Chemistry 2000, 36(2), 6320) Robert, D; Catalysis Today 2007, 122(1-2), 2021) Serp, P; Applied Cata

9、lysis A 2003, 253(2), 33722) Du, J; Journal of Physical Chemistry B 2005, 109(26), 1277223) Chen, M; Journal of Chemical Research 2010, 5, 28324) Oh, W; Journal of Ceramic Processing Research 2007, 8(5), 31625) Aviles, F; Carbon 2009, 47(13), 297026) Zhang, W; Solid State Ionics 2000, 130(1), 11127)

10、 Xie, Y; Nanotechnology 2010, 21(1), 01570328) Zhao, W; Advanced Materials Research 2011, 197, 83729) Zhu, L; Chinese Journal of Catalysis 2011, 32(6), 92630) Li, Y; Water Research 2006, 40(6), 111931) Zhao, J; BMC Cancer 2005, 5, 632) Zhang, X; Korean Journal of Chemical Engineering 2011, 28(5), 12

11、412 Bibliographic Information Synthesis and characterizations of poly(3-hexylthiophene) and modified carbon nanotube composites. Karim, Mohammad Rezaul. Center of Excellence for Research in Engineering Materials, College of Engineering, King Saud University, Riyadh, Saudi Arabia. Journal of Nanomate

12、rials (2012), 174353, 8 pp. Publisher: Hindawi Publishing Corp., CODEN: JNOABP ISSN: 1687-4129. Journal; Online Computer File written in English. AN 2012:1116124 CAPLUS AbstractPoly(3-hexylthiophene) and modified (functionalized and silanized) multiwall carbon nanotube (MWNT) nanocomposites have bee

13、n prepd. through in situ polymn. process in chloroform medium with FeCl3 oxidant at room temp. The composites are characterized through Fourier transfer IR spectroscopy (FT-IR), Raman and X-ray diffraction (XRD) measurements to probe the nature of interaction between the moieties. Optical properties

14、 of the composites are measured from UV-visible (UV-Vis) and photoluminescence (PL) spectroscopy. Cond. of the composites is followed by four probe techniques to understand the conduction mechanism. The change (if any) in C=C sym. and antisym. stretching frequencies in FT-IR, the shift in G band fre

15、quencies in Raman, any alterations in max of UV-Vis and PL spectroscopic measurements are monitored with modified MWNT loading in the polymer matrix. Indexing - Section 37 (Plastics Manufacture and Processing) Citations1) Yu, G; Science 1995, 270(5243), 17892) Campos, L; Chemistry of Materials 2005,

16、 17(16), 40313) Huynh, W; Science 2002, 295(5564), 24254) Liu, J; Journal of the American Chemical Society 2004, 126(21), 65505) Kymakis, E; Applied Physics Letters 2002, 80(1), 1126) Kymakis, E; Journal of Applied Physics 2003, 93(3), 17647) Landi, B; Progress in Photovoltaics 2005, 13(2), 1658) La

17、ndia, B; Solar Energy Materials and Solar Cells 2005, 87, 7339) Alam, M; Chemistry of Materials 2004, 16(23), 464710) Kietzke, T; Chemistry of Materials 2005, 17(26), 653211) Manoj, A; Journal of Applied Physics 2003, 94(6), 408812) Geng, J; Journal of the American Chemical Society 2006, 128(51), 16

18、82713) Karim, M; Synthetic Metals 2005, 151(2), 13114) Shaffer, M; Chemical Communications 2002, 18, 207415) Karim, M; Materials Chemistry and Physics 2008, 112(3), 77916) Liu, I; Macromolecules 2004, 37(2), 28317) Karim, M; Materials Letters 2007, 61(8-9), 168818) Kong, H; Journal of the American C

19、hemical Society 2004, 126(2), 41219) Zhao, B; Advanced Functional Materials 2004, 14(1), 7120) Karim, M; Journal of Polymer Science A 2006, 44(18), 528321) Bolognesi, A; Macromolecular Chemistry and Physics 2001, 202(12), 258622) Chen, S; Macromolecules 1992, 25(23), 608123) Shiga, T; Journal of App

20、lied Polymer Science 1996, 62(6), 90324) Tashiro, K; Journal of Polymer Science B 1991, 29(10), 122325) Mardalen, J; Solid State Communications 1991, 77(5), 33726) Hsu, W; Macromolecules 1993, 26(6), 131827) Andrews, R; Carbon 2001, 39(11), 168128) Huang, Y; Carbon 2007, 45(8), 161429) Zhang, J; Jou

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22、eci, A; Polymer 2007, 48(6), 166736) Kuila, B; Macromolecules 2007, 40(2), 27837) Liu, Y; Macromolecules 2007, 40(25), 888138) Wise, K; Chemical Physics Letters 2004, 391(4-6), 20739) Ovsyannikova, E; Russian Journal of Electrochemistry 2005, 41(4), 43940) Babel, A; Synthetic Metals 2005, 148(2), 16

23、941) Kymakis, E; Synthetic Metals 2004, 142(1-3), 16142) Chen, J; Journal of the American Chemical Society 2002, 124(31), 903443) Feng, W; Carbon 2005, 43(12), 250144) Colladet, K; Macromolecules 2007, 40(1), 6545) Mohammad, F; Journal of Physics D 1996, 29(1), 19546) Peng, H; Journal of the America

24、n Chemical Society 2008, 130(1), 4247) Barrau, S; Macromolecules 2003, 36(14), 5187 3 Bibliographic Information A peptide receptor-based bioelectronic nose for the real-time determination of seafood quality. Lim, Jong Hyun; Park, Juhun; Ahn, Jung Ho; Jin, Hye Jun; Hong, Seunghun; Park, Tai Hyun. Sch

25、ool of Chemical and Biological Engineering, Seoul National University, Seoul, Biosensors & Bioelectronics Ahead of Print. Publisher: Elsevier B.V., CODEN: BBIOE4 ISSN: 0956-5663. Journal written in English. AN 2012:1207981 CAPLUS AbstractWe herein report a peptide receptor-based bioelectronic nose (

26、PRBN) that can det. the quality of seafood in real-time through measuring the amt. of trimethylamine (TMA) generated from spoiled seafood. The PRBN was developed using single walled-carbon nanotube field-effect transistors (SWNT-FETs) functionalized with olfactory receptor-derived peptides (ORPs) wh

27、ich can recognize TMA and it allowed us to sensitively and selectively detect TMA in real-time at concns. as low as 10 fM. Utilizing these properties, we were able to not only det. the quality of three kinds of seafood (oyster, shrimp, and lobster), but were also able to distinguish spoiled seafood

28、from other types of spoiled foods without any pretreatment processes. Esp., the use of small synthetic peptide rather than the whole protein allowed PRBNs to be simply manufd. through a single-step process and to be reused with high reproducibility due to no requirement of lipid bilayers. Furthermor

29、e, the PRBN was produced on a portable scale making it effectively useful for the food industry where the on-site measurement of seafood quality is required. Indexing - Section 17 (Food and Feed Chemistry)4 Bibliographic Information Thermal conductivity of a graphene oxide- carbon nanotube hybrid/ep

30、oxy composite. Im, Hyungu; Kim, Jooheon. School of Chemical Engineering and Materials Science, Chung-Ang University, Seoul, Carbon Ahead of Print. Publisher: Elsevier Ltd., CODEN: CRBNAH ISSN: 0008-6223. Journal written in English. AN 2012:1207821 CAPLUS AbstractThermally conductive graphene oxide (

31、GO)-multi-wall carbon nanotube (MWCNT)/epoxy composite materials were fabricated by epoxy wetting. The polar functionality on the GO surface allowed the permeation of the epoxy resin due to a secondary interaction between them, which allowed the fabrication of a composite contg. a high concn. of thi

32、s hybrid filler. The thermal transport properties of the composites were maximized at 50 wt.% of filler due to fixed pore vol. fraction in filtrated GO cake. When the total amt. of filler was fixed 50 wt.% while changing the amt. of MWCNTs, a max. thermal cond. was obtained with the addn. of about 0.36 wt.% of MWCNTs in the filler. Measured thermal cond. was higher than the predicted value based on the by Maxwell-Garnett (M-G) approxn. and decreased for MWCNT concns