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Online since: September 2013
Authors: Jin Hui Lin, Hui Li, Miao Deng, Shan Hua Chen, Yan Wang
XRD result confirms the formation of a pure pervoskite structure for the synthesized powders.
All diffraction peaks can be rapidly asserted to the NBT structure as reported in JCPDS file No.36-0340.
The result confirms the formation of a pure pervoskite structure for the synthesized powders.
Journal of Physics and Chemistry of Solids.
Chemistry of Materials.
All diffraction peaks can be rapidly asserted to the NBT structure as reported in JCPDS file No.36-0340.
The result confirms the formation of a pure pervoskite structure for the synthesized powders.
Journal of Physics and Chemistry of Solids.
Chemistry of Materials.
Online since: January 2014
Authors: Yu Feng Li
China
2New Materials and Function Coordination Chemistry Lab, Qingdao
University of Science & Technology, Qingdao, 266042, P.
Results and discussions The title complex crystal structure is shown in Fig.1.
The crystal data and structure refinement is shown in Table 1.
Crystal data and structure refinement for the title complex.
Oberley, Biochemical and Inorganic Copper Chemistry, Vol. 1, Adenine, New York, (1986), p. 139 [4] P.M.
Results and discussions The title complex crystal structure is shown in Fig.1.
The crystal data and structure refinement is shown in Table 1.
Crystal data and structure refinement for the title complex.
Oberley, Biochemical and Inorganic Copper Chemistry, Vol. 1, Adenine, New York, (1986), p. 139 [4] P.M.
Online since: January 2016
Authors: Supphadate Sujinnapram, Sasimonton Moungsrijun
Zhu, Network Structured SnO2/ZnO Heterojunction Nanocatalyst with High Photocatalytic Activity, Inorganic Chemistry, 48 (2009) 1819-1825
Su, Hierarchically Assembled Porous ZnO Nanoparticles: Synthesis, Surface Energy, and Photocatalytic Activity, Chemistry of Materials, 19 (2007) 5680-5686
Huang, Preparation and photocatalytic activity of high-efficiency visible-light-responsive photocatalyst SnSx/TiO2, Journal of Solid State Chemistry, 182 (2009) 807-812
Kong, Effect of annealing temperature on the structure and optical properties of In-doped ZnO thin films, Journal of Alloys and Compounds, 484 (2009) 575-579
Li, Photocatalytic degradation of methyl orange with W-doped TiO2 synthesized by a hydrothermal method, Materials Chemistry and Physics, 112 (2008) 47-51
Su, Hierarchically Assembled Porous ZnO Nanoparticles: Synthesis, Surface Energy, and Photocatalytic Activity, Chemistry of Materials, 19 (2007) 5680-5686
Huang, Preparation and photocatalytic activity of high-efficiency visible-light-responsive photocatalyst SnSx/TiO2, Journal of Solid State Chemistry, 182 (2009) 807-812
Kong, Effect of annealing temperature on the structure and optical properties of In-doped ZnO thin films, Journal of Alloys and Compounds, 484 (2009) 575-579
Li, Photocatalytic degradation of methyl orange with W-doped TiO2 synthesized by a hydrothermal method, Materials Chemistry and Physics, 112 (2008) 47-51
Online since: January 2015
Authors: M.A. Vysotskaya, Аlex Korotkov
In the majority these practices are directed on studying of the processes happening at a stage of preparation and in structure of end products – a bituminous emulsion.
When developing and studying bituminous emulsions the superficial phenomena proceeding at formation of its structure are key.
Process of wetting of a firm body by liquid from the point of view of colloidal chemistry speaks as result of action of forces of a superficial tension of this liquid.
Technical manual (2010) AkzoNobel Surface Chemistry AB, Sweden, 28р
[9] Technology of production of emulsions (2011) AkzoNobel Surface Chemistry AB, Sweden, 28 р
When developing and studying bituminous emulsions the superficial phenomena proceeding at formation of its structure are key.
Process of wetting of a firm body by liquid from the point of view of colloidal chemistry speaks as result of action of forces of a superficial tension of this liquid.
Technical manual (2010) AkzoNobel Surface Chemistry AB, Sweden, 28р
[9] Technology of production of emulsions (2011) AkzoNobel Surface Chemistry AB, Sweden, 28 р
Online since: November 2011
Authors: Wen Quan Cui, Ying Hua Liang, Yan Fei Liu, Jin Shan Hu
This change of morphology may be related to the lattice structure of K4Nb6O17.
Osterloh: Chemistry of Materials.
Justin Youngblood: Chemistry of Materials.
Osterloh: Journal of Solid State Chemistry.
Vol. 244(2006), p. 230 [10] Gaoke Zhang, Fangsheng He, Xi Zou, Jie Gong and Hao Zhang: Journal of Physics and Chemistry of Solids.
Osterloh: Chemistry of Materials.
Justin Youngblood: Chemistry of Materials.
Osterloh: Journal of Solid State Chemistry.
Vol. 244(2006), p. 230 [10] Gaoke Zhang, Fangsheng He, Xi Zou, Jie Gong and Hao Zhang: Journal of Physics and Chemistry of Solids.
Online since: December 2014
Authors: Ren Zhang Wang, Fu Ying Li, Yu Niu
Fig.1 XRD pattern of MnFe2O4
Fig.2 The effect of pH on the catalytic activities
3.3 The different structure organics degradation
In our experiment, two types organics degradation was exhibited in Fig.3.
Industrial & Engineering Chemistry Research 2012;51:725-31
Preparation and photocatalytic property of anatase TiO_2/MnFe_2O_4 core-shell structure nanoparticles [J].
The Journal of Physical Chemistry C 2011;115:6478-83
Chemistry Letters 2003;32:364-5
Industrial & Engineering Chemistry Research 2012;51:725-31
Preparation and photocatalytic property of anatase TiO_2/MnFe_2O_4 core-shell structure nanoparticles [J].
The Journal of Physical Chemistry C 2011;115:6478-83
Chemistry Letters 2003;32:364-5
Online since: June 2014
Authors: Ze Jun Chen, La Yun Deng, Hong Chen, You Hua Fan
Results and Discussion
Fig. 1 XRD Patterns of the As-prepared CuO Powder
The crystalline structure of the as-prepared CuO surface was characterized using an X-ray diffraction as shown in Fig. 1.
The main five diffraction peaks were identified to match up to the (110), () and (111), () and (020) planes of the monoclinic CuO structure in sequence compared with the PDF card (JCPDS 45-0937).
Most studies on natural and artificial superhydrophobic surfaces showed that the rough surface structure and low-surface-energy materials were crucial for a superhydrophobic surface [11,12].
Wenzel, Resistance of solid surfaces to wetting by water, Industrial & Engineering Chemistry 28 (1936) 988-994
Jiang, Construction of superhydrophobic hydromagnesite films on the Mg alloy, Materials Chemistry and Physics 129 (2011) 154.
The main five diffraction peaks were identified to match up to the (110), () and (111), () and (020) planes of the monoclinic CuO structure in sequence compared with the PDF card (JCPDS 45-0937).
Most studies on natural and artificial superhydrophobic surfaces showed that the rough surface structure and low-surface-energy materials were crucial for a superhydrophobic surface [11,12].
Wenzel, Resistance of solid surfaces to wetting by water, Industrial & Engineering Chemistry 28 (1936) 988-994
Jiang, Construction of superhydrophobic hydromagnesite films on the Mg alloy, Materials Chemistry and Physics 129 (2011) 154.
Online since: March 2023
Authors: Hai Ling Jiang
It has a three-dimensional complex network structure.
Hydrophilic/hydrophobic composite shape-shifting structures.
The Journal of Physical Chemistry B, 2007, 111(7): 1729-1737.
Physical chemistry chemical physics: PCCP, 2018. 20, 20695.
Frontiers in chemistry, 2020, 8, 115.
Hydrophilic/hydrophobic composite shape-shifting structures.
The Journal of Physical Chemistry B, 2007, 111(7): 1729-1737.
Physical chemistry chemical physics: PCCP, 2018. 20, 20695.
Frontiers in chemistry, 2020, 8, 115.
Online since: September 2013
Authors: Hong Yan Zhou
Synthesis and Crystal Structure of (1E,2E)-1,2-di(-3-nitrobenzylidene) hydrazine under Micromave Irradiation
Zhou Hong-yan
School of Chemistry and Environmental Engineering,Hubei Institute for Nationalities, Enshi 445000, China
Email: fengfu04971118@163.com
Keywords: Hydrazine, Microwave, Crystal Structure
Abstract.
Its structure was determined IR, 1H NMR, MS, elemental analysis and X-ray diffraction.
The crystal structure was determined by X-ray diffraction as part of our ongoing structural studies to provide a basis for the consideration of stereochemical structure-activity relationships.
The molecular structure is stabilized by weak π-π stacking interactions (Fig. 2).
Molecular structure Fig. 2.
Its structure was determined IR, 1H NMR, MS, elemental analysis and X-ray diffraction.
The crystal structure was determined by X-ray diffraction as part of our ongoing structural studies to provide a basis for the consideration of stereochemical structure-activity relationships.
The molecular structure is stabilized by weak π-π stacking interactions (Fig. 2).
Molecular structure Fig. 2.
Online since: February 2011
Authors: Xian Jun Lu, Wei Mo, Shuai Zhang, Gui Fang Wang, Shao Jian Ma, Jin Lin Yang
The porous structure of Al-PILM is characterized as parallel plate slit or “house-of-cards” wedge-shaped pore which is formed by novel meso-microporous delaminated structure and fragments.
The porous structure of clays was determined from the adsorption-desorption isotherm of N2 (77K) on a SSA-4300 equipment.
Na-M appears as corn flake like crystals with fluffy appearance revealing its extremely fine platy structure.
The porous structure of Al-PILM is characterized as parallel plate slit or “house-of-cards” wedge-shaped pore which is formed by novel meso-microporous delaminated structure and fragments.
Davies: Journal of Materials Chemistry Vol. 34(1993),P. 381-387 [3] G.W.Brindley, R.E.Sempels: Clay Minerals Vol. 12(1977).
The porous structure of clays was determined from the adsorption-desorption isotherm of N2 (77K) on a SSA-4300 equipment.
Na-M appears as corn flake like crystals with fluffy appearance revealing its extremely fine platy structure.
The porous structure of Al-PILM is characterized as parallel plate slit or “house-of-cards” wedge-shaped pore which is formed by novel meso-microporous delaminated structure and fragments.
Davies: Journal of Materials Chemistry Vol. 34(1993),P. 381-387 [3] G.W.Brindley, R.E.Sempels: Clay Minerals Vol. 12(1977).