Dr. Qiang Wang

Associate Professor

Office: M-527

Phone: +86-10-82649090

Email:  qwang@aphy.iphy.ac.cn

 Education：

Sept 1989 - July 1993, BS Degree in Material Engineering, Hebei University of Technology

Sept 1995 - July 1997, MS Degree in Material Engineering, Harbin Institute of Technology

Sept 1997 - July 2000, PhD Degree in Condensed Matter Physics, Institute of Physics, CAS

  

Work Experience： 

July 2000 - July 2002, Postdoctoral researcher in Tsinghua University

  

Research Interest： 

* Water science; Structure and properties of aqueous solutions

* Crystallization and cold-crystallization processes

* Glass transition of aqueous solutions 

  

Publications: 

1.Q. Wang,# and Z. X. Cao, Definition and quantification of hydration water in aqueous solutions. 

Acta Phys. Sin., 68 (2019) 015101 (Review article).

2.Q. Wang, # X. Huang, W. Guo, and Z. X. Cao, Synergy of orientational relaxation of bound water and 

confined water in ice cold-crystallization, Phys. Chem. Chem. Phys., DOI: 10.1039/c9cp01600g, (2019)

3.W. Guo, L S. Zhao, X. Gao, Z. X. Cao, and Q. Wang#. Accurate quantification of hydration number for 

polyethylene glycol molecules. Chin. Phys. B 27 (2018) 055101.

4.T. X. Yu, L. S. Zhao, Q. Wang, and Z. X. Cao#, Glass transition behavior of ternary 

disaccharide-ethylene glycol-water solutions. Chem. Phys. Lett. 677 (2017) 172-177.

5.L. S. Zhao, L. Q. Pan, A. L. Ji, Z. X. Cao, and Q. Wang# Recrystallization of freezable bound water in 

aqueous solutions of medium concentration. Chin. Phys. B 25 (2016) 075101.

6.Q. Wang #, L S. Zhao, C. X. Li, and Z. X. Cao, The decisive role of free water in determining homogenous 

ice nucleation behavior of aqueous solutions. Sci. Rep. 6 (2016) 26831.

7.L. S. Zhao, L. Q. Pan, Z. X. Cao, and Q. Wang,# Mutual Effects of Glycerol and Inorganic Salts on Their 

Hydration Abilities. J. Phys. Chem. B 120 (2016) 13112-13117.

8.L. S. Zhao, Z. X. Cao, and Q. Wang,# Glass transition of aqueous solutions involving annealing-induced 

ice recrystallization resolves liquid-liquid transition puzzle of water. Sci. Rep. 5 (2015) 15714.

9.X. Gao,# Q. Wang, G. Sun, C. X. Li, and L. Hu, Mechanism of the typical relaxation process at low 

frequency based on dielectric measurements of water absorbed in porous titanium dioxide. 

EPL 13 (2016) 47007.

10.X. Gao,# Q. Wang, G. Sun, C. X. Li, and L. Hu, Liquid-solid transition of water confined in nanoporous 

titanium dioxide. Mod. Phys. Lett. B 30 (2016) 1650250.

11.L. S. Zhao, L. Q. Pan, Z. X. Cao, and Q. Wang,# Confinement-induced vitrification of aqueous sodium 

chloride solutions. Chem. Phys. Lett. 647 (2016) 170.

12.X. F. Huang, L. Q. Pan, C. X. Li, Q. Wang, # G. Sun, and K. Q. Lu, Vibrational dynamics of water 

confined in mesoporous silica under low temperature, Acta Phys. Sin., 61 (2012) 136801.

13.Q. Wang, X. F. Huang, C. X. Li, L. Q. Pan, Z. H. Wu, T. D. Hu, Z. Jiang, Y. Y. Huang, Z. X. Cao#, 

G. Sun, and K. Q. Lu, Coordination variation of hydrated Cu2+/Br- ions traversing the interfacial 

water in mesopores, AIP ADVANCE, 2 (2012) 022107.

14.X. F. Huang, J. L. Hu, L. Q. Pan, C. X. Li, G. Sun, K. Q. Lu, and Q. Wang#, A weakened 

structure-breaking effect of Na+ and Cl- on water inside partially filled mesoporous silica, Chem. 

Phys. Lett. 533 (2012) 40-44.

15.X. X. Liu, Q. Wang#, X. F. Huang, S. h. Yang, C. X. Li, X. J. Niu, Q. F. Shi, G. Sun, and K. Q. 

Lu, Liquid-solid transition of confined water in silica-based mesopores, J. Phys. Chem. B, 

114 (2010) 4145-4150.

16.X. F. Huang, Q. Wang#, X. X. Liu, S. H. Yang, C. X. Li, G. Sun, L. Qq. Pan, and K. Q. Lu,  

Vibrational dynamics of water within mesoporous materials at different hydration levels during 

adsorption and desorption processes. J. Phys. Chem. C 113 (2009) 18768-18771.

17.Q. Wang#, C. X. Li, Z. H. Wu, L. W. Wang, X. J. Niu, W. S. Yan, Y. N. Xie, S. Q. Wei, and K. Q. Lu, 

Temperature effect of the local structure in liquid Sb studied with x-ray absorption spectroscopy, 

J. Chem. Phys. 128 (2008) 224501.

18.L. W. Wang#, Q. Wang, C. X. Li, X. J. Niu, G. Sun, and K. Q. Lu, Layering in water adsorption and 

desorption on porous Vycor observed by dielectric measurements, Phys. Rev. B 76 (2007) 155437.

19.Q. Wang#, C. X. Li, X. J. Niu, R. Shen, K. Q. Lu, S. Q. Wei, T. Liu, Y. N. Xie, and T. D. Hu, 

Structure of liquid krypton under atmospheric pressure: An EXAFS and reverse Monte Carlo study, 

Phys. Rev. B 72 (2005) 092202.

20.R. Tan, Q. Wang#, L. W. Wang, C. X. Li, K. Q. Lu, S. Z. Peng, and L Hu, Surface tension and 

density of Bismuth Germanate melts as a function of composition and temperature; J. Am. Ceram. Soc., 

90 (2007) 2837.

21.L. W. Wang#, Q. Wang, and K. Q. Lu, Melting of superheated crystals initiated on vacancies; 

Phil. Mag. Lett., 87 (2007) 19.

22.X. M. Shi, Q. Wang#, X. J. Niu, C. X. Li, and K. Q. Lu, An examination of surface tension of 

binary lithium borate melts as a function of composition and temperature; J. Am. Ceram. Soc., 

89 (2006) 3222.

23.X. M. Shi, Q. Wang#, C. X. Li, F. P. Wang, and K. Q. Lu, Densities of Li2O-B2O3 melts, J. Crystal. 

Growth, 290 (2006) 637.

24.L. W. Wang#, Q. Wang, and K. Q. Lu, Density of liquid GaSb measured by an improved Archimedean method, 

J. Crystal. Growth, 293 (2006) 14.

25.Q. Wang#, C. X. Li, X. J. Niu, R. Shen, K. Q. Lu, S. Q. Wei, Z. H. Wu, T. Liu, Y. N. Xie, and T. D. Hu, 

Structure of liquid krypton under atmospheric pressure: An EXAFS and reverse Monte Carlo study, 

Phys. Rev. B 72 (2005) 092202.

26.L. W. Wang#, Q. Wang, A. P. Xian, and K. Q. Lu, Precise measurement of the densities of liquid Bi, 

Sn, Pb and Sb; J. Phys.-Condens. Mat., 15 (2003) 777.

27.Q. Wang#, Y. X. Li, and X. C. Li, Grain refinement of Al–7Si alloys and the efficiency assessment 

by recognition of cooling curves, Metall. Mater. Trans. A, 34 (2003) 1175.

28.K. Q. Lu#, Q. Wang, C. X. Li, Y. R. Wang, and X. M. Chen, The structures, electronic states and 

properties in liquid Ga-Sb and In-Sb systems, J. Non-Crystal. Solids, 312 (2002) 34.

29.Q. Wang#, X. M. Chen, and K. Q. Lu, Concentration and temperature dependence of the electrical 

resistivity of liquid gallium-antimony alloys, J. Phys.-Condens. Mat., 13 (2001) 8445.

30.Q. Wang#, K. Q. Lu, and Y. X. Li, Anomalous temperature dependence of the electrical resistivity 

of molten Sb, Chin. Sci. Bull., 46 (2001) 1431.

31.Q. Wang#, X. M. Chen, and K. Q. Lu, Electrical resistivity and absolute thermopower of liquid 

GaSb and InSb alloys, J. Phys.-Condens. Mat., 12 (2000) 5201.

32.Q. Wang#, X. M. Chen, C. X. Li, and K. Q. Lu, Electrical resistivity of molten indium-antimony 

alloys, J. Appl. Phys., 87 (2000) 4623.

33.X. M. Chen#, Q. Wang, and K. Q. Lu, Temperature and time dependence of the density of molten 

indium antimonide measured by an improved Archimedean method, J. Phys.-Condens. Mat., 

111 (1999) 10335-10341.

34.X. M. Chen#, Q. Wang, X. Wu, and K. Q. Lu, Densities and surface tensions of Lithium Niobate 

melts, J. Crystal. Growth, 204 (1999) 163.