Solid State Physics View of Liquid State Chemistry II. Electrical Capacitance of Pure and Impure Water

More than 80 years of theories and experiments on water suggested to us, described in our first water-physics report, that pure water's "abnormally" high electrical conductivity is due to transport of positive and negative quasi-protons, p+ and p-, between the neutral proton traps V (H20) in the ext...

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Bibliographic Details
Published inJournal of semiconductors Vol. 35; no. 2; pp. 1 - 19
Main Author 揭斌斌 萨支唐
Format Journal Article
LanguageEnglish
Published 01.02.2014
Subjects
Charging
Electric charge
Electric potential
Electrical resistivity
Liquids
Resistivity
Semiconductors
Solid state physics
化学
固态
液态
物理视图
电容
电荷控制
纯水
高导电性
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Summary:More than 80 years of theories and experiments on water suggested to us, described in our first water-physics report, that pure water's "abnormally" high electrical conductivity is due to transport of positive and negative quasi-protons, p+ and p-, between the neutral proton traps V (H20) in the extended water, [(H20)N]+, converting it respectively to positively and negatively charged proton traps, V+ = (H30)1+ and V- = (HO)1-. In this second report, we present the theoretical charge control capacitances of pure and impure water as a function of the DC electric potential applied to water.
Bibliography:11-5781/TN
More than 80 years of theories and experiments on water suggested to us, described in our first water-physics report, that pure water's "abnormally" high electrical conductivity is due to transport of positive and negative quasi-protons, p+ and p-, between the neutral proton traps V (H20) in the extended water, [(H20)N]+, converting it respectively to positively and negatively charged proton traps, V+ = (H30)1+ and V- = (HO)1-. In this second report, we present the theoretical charge control capacitances of pure and impure water as a function of the DC electric potential applied to water.
solid state physics; liquid state chemistry; pure and impure water; positive and negative quasi-protons;proton vacancies; water capacitance
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1674-4926
DOI:10.1088/1674-4926/35/2/021001