Influences of Temperature on Proton Conductivity in the Hydrogen-Bond Molecular Systems with Damping

Chin. Phys. Lett.

2007, Vol. 24

Issue (6): 1452-1455 DOI:

Original Articles

Influences of Temperature on Proton Conductivity in the Hydrogen-Bond Molecular Systems with Damping

PANG Xiao-Feng^1,2;YU Jia-Feng¹

¹Institute of Life Science and Technology, University of Electronic Science and Technology, Chengdu 610054²International Centre for Materials Physics, Chinese Academy of Sciences, Shenyang 110015

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PANG Xiao-Feng, YU Jia-Feng 2007 Chin. Phys. Lett. 24 1452-1455

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Abstract Influences of temperature of medium on proton conductivity in hydrogen-bonded systems exposed in an electric-field are numerically studied by the fourth-order Runge--Kutta method with our model. The results obtained show that the proton soliton is very robust against thermal perturbation and damping of medium, and is thermally stable in the temperature range T≤ 273K. From the simulation we find out that the mobility (or velocity) of proton conduction in ice crystal is a nonmonotonic function of temperature in the temperature range 170--273K: i.e., it increases initially, reaches a maximum at about 191K, subsequently decreases to a minimum at about 211K, and then increases again. This changed rule of mobility is qualitatively consistent with its experimental data in ice in the same temperature range. This result provides an evidence for existence of solitons in the hydrogen-bonded systems.

Keywords: 03.65.-w 33.20.Kf 66.30.Dn 82.39.Jn

Received: 06 November 2006 Published: 17 May 2007

PACS:	03.65.-w	(Quantum mechanics)
	33.20.Kf	(Visible spectra)
	66.30.Dn	(Theory of diffusion and ionic conduction in solids)
	82.39.Jn	(Charge (electron, proton) transfer in biological systems)

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