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Online since: January 2012
Authors: Lian Zhu Tian, Yang Zou, Lian Qun Zhang, Yin Zhi Jiang
Synthesis and Crystal Structure of the Complex of (R,R)-N,N’-bis(salicylal)-1,2-Cyclohexanediamine with Fe3+
Yinzhi JIANG1, a, Lianzhu TIAN 1, b, Yang ZOU1, c and Lianqun ZHANG1, d
1Department of Chemistry, Zhejiang Sci-Tech University, Hangzhou 310018, P.
The results of crystal structure determination show that there exists rich H-bond.
Herein, synthesis, characterization, and crystal structure of 1was reported.
[3] Yuan Yi-Xian, Chen Yu, Wang Yi-Chan, Liang Si-Min, Chao Hui, Ji Liang-Nian: CHINESE JOURNAL OF INORGANIC CHEMISTRY. 8 (2008) 1265-1269
[4] Zhou Chun-Qiong, Zou Min, You Wen-Wei, Dang Zhong-Kun, Guo Rui-Fen, CHINESE JOURNAL OF INORGANIC CHEMISTRY. 2 (2010) 257-261
The results of crystal structure determination show that there exists rich H-bond.
Herein, synthesis, characterization, and crystal structure of 1was reported.
[3] Yuan Yi-Xian, Chen Yu, Wang Yi-Chan, Liang Si-Min, Chao Hui, Ji Liang-Nian: CHINESE JOURNAL OF INORGANIC CHEMISTRY. 8 (2008) 1265-1269
[4] Zhou Chun-Qiong, Zou Min, You Wen-Wei, Dang Zhong-Kun, Guo Rui-Fen, CHINESE JOURNAL OF INORGANIC CHEMISTRY. 2 (2010) 257-261
Online since: December 2013
Authors: Xiao Liang Wang, Zi Qiang Lei, Jian Xu, Heng Chang Ma, Zhe Zhang
It is clear that OPGS exhibits a fibrous structure with parallel aggregates and rods.
Pilar: Journal of Materials Chemistry, Vol. 15 (2005) No. 35-36, p.3650
Tong: Journal of Materials Chemistry, Vol. 22(2012) No. 6, p.2401
Amalnerkar: Materials Chemistry and Physics, Vol. 61 (1999) No. 3, p.173
Sheng: Journal of Macromolecular Science Pure and Applied Chemistry, Vol.
Pilar: Journal of Materials Chemistry, Vol. 15 (2005) No. 35-36, p.3650
Tong: Journal of Materials Chemistry, Vol. 22(2012) No. 6, p.2401
Amalnerkar: Materials Chemistry and Physics, Vol. 61 (1999) No. 3, p.173
Sheng: Journal of Macromolecular Science Pure and Applied Chemistry, Vol.
Online since: September 2013
Authors: Hong Zong Si, Yun Bo Duan, Hong Lin Zhai, Xian Chao Li, Hua Gao
In this study, all structures of 32 compounds were constructed using software Chemoffice8.0.
After optimization, all structures were calculated by MOPAC program.
All of the Structures were constructed using software Chemoffice8.0.
Rasha: Journal of Medicinal Chemistry, July12, 012
Jiang: Chemistry and Industry of Forest Products 29 (2009), 47-53
After optimization, all structures were calculated by MOPAC program.
All of the Structures were constructed using software Chemoffice8.0.
Rasha: Journal of Medicinal Chemistry, July12, 012
Jiang: Chemistry and Industry of Forest Products 29 (2009), 47-53
Online since: May 2016
Authors: Ravichandran H. Kollarigowda
gowda.ravichandran@unina.it, Ravichandran.hk@gmail.com
Keywords- Photo-polymers, photo-chemistry, Polymer synthesis, Light senstive-Biomaterials.
In this review we discuss the photopolymer chemistry and explain the changing the morphology of polymeric materials after exposing into light.
(a and b) Structures of trans and cis isomers of azobenzene.Spacefilling models are coloured by electrostatic potential (red—negative to blue—positive).
The ability to control the structure and functions of biomaterials and biomolecular processes with light is of substantial interest in the development of photo-therapies and optobioelectronic systems.
Advancements in chemistry, material science and nanotechnologies greatly improved the possibility of presenting many different signals, according to predefined spatial patterns.
In this review we discuss the photopolymer chemistry and explain the changing the morphology of polymeric materials after exposing into light.
(a and b) Structures of trans and cis isomers of azobenzene.Spacefilling models are coloured by electrostatic potential (red—negative to blue—positive).
The ability to control the structure and functions of biomaterials and biomolecular processes with light is of substantial interest in the development of photo-therapies and optobioelectronic systems.
Advancements in chemistry, material science and nanotechnologies greatly improved the possibility of presenting many different signals, according to predefined spatial patterns.
Online since: August 2013
Authors: De Zhen Chen, Yu Yan Hu, Xian Wei Li, Jian Ping Li
Quantum chemistry is widely used in the fields such as material, energy, environment, chemical industry and laser technology.
Heitler and London [6] firstly used quantum chemistry to research the structure of hydrogen molecule.
Mono-chlorobenzene was used to represent chlorinated aromatic hydrocarbons for their similar structures and properties.
Fig. 6 Potential energy profile of Fe(II) reduction mechanism at 473K Fig. 7 Potential energy profile of Fe(III) oxidation mechanism at 473K In order to verify the correctness and feasibility of the model after quantum chemistry calculation, corresponding experiments were designed.
Hong Kong: [s n] (1999), 551-556 [5] Yuyan Hu, PengfeiZahng, Dezhen Chen, et al: Hydrothermal treatment of municipal solid waste incineration fly ash for dioxin decomposition, Journal of Hazardous Materials (2011), in press [6] Andreas Karachalios: On the Making of Quantum Chemistry in Germany.
Heitler and London [6] firstly used quantum chemistry to research the structure of hydrogen molecule.
Mono-chlorobenzene was used to represent chlorinated aromatic hydrocarbons for their similar structures and properties.
Fig. 6 Potential energy profile of Fe(II) reduction mechanism at 473K Fig. 7 Potential energy profile of Fe(III) oxidation mechanism at 473K In order to verify the correctness and feasibility of the model after quantum chemistry calculation, corresponding experiments were designed.
Hong Kong: [s n] (1999), 551-556 [5] Yuyan Hu, PengfeiZahng, Dezhen Chen, et al: Hydrothermal treatment of municipal solid waste incineration fly ash for dioxin decomposition, Journal of Hazardous Materials (2011), in press [6] Andreas Karachalios: On the Making of Quantum Chemistry in Germany.
Online since: September 2013
Authors: Viktoriia Priazhnikova, Felix Telegin, Jian Hua Ran, Irina Shushina, Yulia Biba, Aleksandr Mikhaylov
Structure – Property Relationships for Dyes of Different Nature
TELEGIN Felix1,a, SHUSHINA Irina2,b, RAN Jianhua3,c, BIBA Yulia4,d, MIKHAYLOV Aleksandr5,e, PRIAZHNIKOVA Viktoriia6,f
1,2,4,5,6Engels Ave 7, Ivanovo, 153000, Russia, Ivanovo State University of Chemistry and Technology
3FangZhi Road 1, Wuhan, 430073, P.
Introduction Chemical structure and technical property relationships are of great importance for practical needs.
Journal of Molecular Structure (Theochem) 340, 73-81 (1995)
Chemistry and Chemical Technology Vol.47, No.8, P.42-47 (2004) (in Russian)
E-Textbook, Ivanovo State University of Chemistry and Technology, 167 pp. (2007).
Introduction Chemical structure and technical property relationships are of great importance for practical needs.
Journal of Molecular Structure (Theochem) 340, 73-81 (1995)
Chemistry and Chemical Technology Vol.47, No.8, P.42-47 (2004) (in Russian)
E-Textbook, Ivanovo State University of Chemistry and Technology, 167 pp. (2007).
Online since: October 2011
Authors: Li Hua Wang
Introduction
There has been considerable interest in the design and synthesis of transition metal complexes with carboxylate ligands in coordination chemistry, due to the fact that this type of complexes has potential applications in molecule-based magnets, catalysis, supramolecular chemistry and biological systems [1-4].
X-ray single crystal structure was obtained on a Bruker smart-1000 CCD Area Detector.
Crystal structure determination and refinement The block single crystal with an approximate dimension of 0.47 mm×0.46 mm×0.45 mm was selected for the structure analysis.
The structure was solved by direct methods and refined by full-matrix least-squares techniques on F2.
The two dimensional layered structure in the crystal of the complex is shown in Fig. 2.
X-ray single crystal structure was obtained on a Bruker smart-1000 CCD Area Detector.
Crystal structure determination and refinement The block single crystal with an approximate dimension of 0.47 mm×0.46 mm×0.45 mm was selected for the structure analysis.
The structure was solved by direct methods and refined by full-matrix least-squares techniques on F2.
The two dimensional layered structure in the crystal of the complex is shown in Fig. 2.
Online since: November 2013
Authors: Jing Lei Tai, Qi Feng Chen, Qing Wang, Guang Xue Chen
The structure and properties of the thiol-compounds and the polyurethane curing film were characterized by NMR, FT-IR, and TG.
Nuclear Magnetic Resonance Spectrometer (AVANCE III 400) was used to character the structure of the adhesive.
Structures of the thiol-compounds were characterized by 1H-NMR and FT-IR.
Lowe: Polymer Chemistry Vol.1 (2010), p17 [14] C.
Bowman: Polymer Chemistry Vol.49 (2010), p1540
Nuclear Magnetic Resonance Spectrometer (AVANCE III 400) was used to character the structure of the adhesive.
Structures of the thiol-compounds were characterized by 1H-NMR and FT-IR.
Lowe: Polymer Chemistry Vol.1 (2010), p17 [14] C.
Bowman: Polymer Chemistry Vol.49 (2010), p1540
Online since: August 2017
Authors: Dae Ho Yoon, Kenji Toda, Mineo Sato, Kazuyoshi Uematsu, Tadashi Ishigaki, Sun Woog Kim, Takuya Hasegawa, Mizuki Watanabe, Tatsuro Kaneko, Ayano Toda, Ryota Yamanashi, Shota Kumagai, Masaru Muto, Atsushi Itadani, Junko Koide, Masako Toda, Emiko Kawakami, Yoshiaki Kudo, Takaki Masaki
Development of Water Assisted Solid State Reaction
for the Ceramic Materials
Kenji Toda1,a*, Sun Woog Kim1, Takuya Hasegawa1, Mizuki Watanabe1, Tatsuro Kaneko1, Ayano Toda1, Ryota Yamanashi1, Shota Kumagai1,
Masaru Muto1, Atsushi Itadani1, Mineo Sato2, Kazuyoshi Uematsu2,
Tadashi Ishigaki1, Junko Koide3, Masako Toda3, Emiko Kawakami3,
Yoshiaki Kudo3, Takaki Masaki4 and Dae Ho Yoon4,b*
1Graduate School of Science and Technology, Niigata University, Niigata 950-2181, Japan
2Department of Chemistry and Chemical Engineering, Niigata University, Niigata 950-2181, Japan
3N-Luminescence Corporation, 8867-3 Ikarashi 2-nocho, Niigata 950-2101, Japan
4School of Advanced Materials Science and Engineering, Sungkyunkwan University,
Kyunggi-do 400-746, Republic of Korea
aktoda@eng.niigata-u.ac.jp, bdhyoon@skku.edu
Keywords: Solid State Reaction, Soft Chemistry, Ionic Diffusion, Water.
The standard XRD pattern of SrMoO4 obtained from the inorganic crystal structure database (ICSD) and the conventional solis state reaction sample are also included as a references.
The diffraction pattern of SrMoO4 obtained by the WASSR method in this study is well indexed to the single phase of the SrMoO4 structure.
The rod-like morphology of the conventional solid state reaction method sample reflects anisotropy of crystal structure for SrMoO4.
[10] The Chemical Society of Japan (Eds.), Handbook of Chemistry: Pure Chemistry, third ed., Maruzen Co., Ltd., Tokyo, 1984, pp. Ⅱ-172.
The standard XRD pattern of SrMoO4 obtained from the inorganic crystal structure database (ICSD) and the conventional solis state reaction sample are also included as a references.
The diffraction pattern of SrMoO4 obtained by the WASSR method in this study is well indexed to the single phase of the SrMoO4 structure.
The rod-like morphology of the conventional solid state reaction method sample reflects anisotropy of crystal structure for SrMoO4.
[10] The Chemical Society of Japan (Eds.), Handbook of Chemistry: Pure Chemistry, third ed., Maruzen Co., Ltd., Tokyo, 1984, pp. Ⅱ-172.
Online since: February 2012
Authors: Jyun Yu Chen, Hong Wen Wang, Wen Jie Lan, Jia You Liou, Ygin Chieh Chen
A heterogeneous structured photo electrode using CDS -modified TiO2 nanotube arrays (TNA) was fabricated.
FESEM, EDS, XRD and UV-Visible were employed to characterize the structures and properties of CDS -modified TNA heterogeneous structure.
Peng:Journal Physical Chemistry C, Vol. 113(2009) p.16021
Sato: Journal Materials Chemistry, Vol. 11 (2001) p.3343
Guo:Journal Physical Chemistry C, Vol. 111(2007) p.13437
FESEM, EDS, XRD and UV-Visible were employed to characterize the structures and properties of CDS -modified TNA heterogeneous structure.
Peng:Journal Physical Chemistry C, Vol. 113(2009) p.16021
Sato: Journal Materials Chemistry, Vol. 11 (2001) p.3343
Guo:Journal Physical Chemistry C, Vol. 111(2007) p.13437