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Measurement of lithium ion transference numbers of electrolytes for lithium-ion batteries. A comparative study with five various methods.; Messung von Lithium-Ionen Ueberfuehrungszahlen an Elektrolyten fuer Lithium-Ionen Batterien. Eine vergleichende Studie mit fuenf verschiedenen Methoden

Abstract

Transference numbers are decisive transport properties to characterize electrolytes. They state the fraction of a certain species at charge transport and are defined by the ratio of current Ii that is transported by the ionic species i to the total current I. They are very important for lithium-ion batteries, because they give information about the real lithium transport and the efficiency of the battery. If the transference number has a too small value, for example, the lithium cannot be ''delivered'' fast enough in the discharge process. This can lead to precipitation of the salt at the anode and to depletion of the electrolyte at the cathode. Currently only a few adequate measurement methods for non-aqueous lithium electrolytes exist. The aim of this work was the installation of measurement devices and the comparison of different methods of transference numbers for electrolytes in lithium-ion batteries. The advantages and disadvantages for every method should be analyzed and transference numbers of new electrolyte be measured. In this work a detailed comparison of different methods with electrochemical and spectroscopic factors was presented for the first time. The galvanostatic polarization, the potentiostatic polarization, the emf method, the determination by NMR and the determination by conductivity measurements  More>>
Authors:
Publication Date:
Mar 30, 2011
Product Type:
Thesis/Dissertation
Report Number:
ETDE-DE-2812
Resource Relation:
Other Information: TH: Diss. (Dr.rer.nat.)
Subject:
25 ENERGY STORAGE; COMPARATIVE EVALUATIONS; LITHIUM COMPOUNDS; ELECTROLYTES; ELECTRIC BATTERIES; MEASURING METHODS; ELECTRIC CONDUCTIVITY; ELECTROMOTIVE FORCE; POLARIZATION; NUCLEAR MAGNETIC RESONANCE; BORATES; OXALATES; FLUOROBORATES; ELECTROCHEMISTRY
OSTI ID:
22060693
Research Organizations:
Regensburg Univ. (Germany). Naturwissenschaftliche Fakultaet 4 - Chemie und Pharmazie
Country of Origin:
Germany
Language:
German
Other Identifying Numbers:
TRN: DE13G2640
Availability:
Commercial reproduction prohibited. Available from ETDE as OSTI ID: 22060693;
Submitting Site:
DE
Size:
204 page(s)
Announcement Date:
Mar 07, 2013

Citation Formats

Zugmann, Sandra. Measurement of lithium ion transference numbers of electrolytes for lithium-ion batteries. A comparative study with five various methods.; Messung von Lithium-Ionen Ueberfuehrungszahlen an Elektrolyten fuer Lithium-Ionen Batterien. Eine vergleichende Studie mit fuenf verschiedenen Methoden. Germany: N. p., 2011. Web.
Zugmann, Sandra. Measurement of lithium ion transference numbers of electrolytes for lithium-ion batteries. A comparative study with five various methods.; Messung von Lithium-Ionen Ueberfuehrungszahlen an Elektrolyten fuer Lithium-Ionen Batterien. Eine vergleichende Studie mit fuenf verschiedenen Methoden. Germany.
Zugmann, Sandra. 2011. "Measurement of lithium ion transference numbers of electrolytes for lithium-ion batteries. A comparative study with five various methods.; Messung von Lithium-Ionen Ueberfuehrungszahlen an Elektrolyten fuer Lithium-Ionen Batterien. Eine vergleichende Studie mit fuenf verschiedenen Methoden." Germany.
@misc{etde_22060693,
title = {Measurement of lithium ion transference numbers of electrolytes for lithium-ion batteries. A comparative study with five various methods.; Messung von Lithium-Ionen Ueberfuehrungszahlen an Elektrolyten fuer Lithium-Ionen Batterien. Eine vergleichende Studie mit fuenf verschiedenen Methoden}
author = {Zugmann, Sandra}
abstractNote = {Transference numbers are decisive transport properties to characterize electrolytes. They state the fraction of a certain species at charge transport and are defined by the ratio of current Ii that is transported by the ionic species i to the total current I. They are very important for lithium-ion batteries, because they give information about the real lithium transport and the efficiency of the battery. If the transference number has a too small value, for example, the lithium cannot be ''delivered'' fast enough in the discharge process. This can lead to precipitation of the salt at the anode and to depletion of the electrolyte at the cathode. Currently only a few adequate measurement methods for non-aqueous lithium electrolytes exist. The aim of this work was the installation of measurement devices and the comparison of different methods of transference numbers for electrolytes in lithium-ion batteries. The advantages and disadvantages for every method should be analyzed and transference numbers of new electrolyte be measured. In this work a detailed comparison of different methods with electrochemical and spectroscopic factors was presented for the first time. The galvanostatic polarization, the potentiostatic polarization, the emf method, the determination by NMR and the determination by conductivity measurements were tested for their practical application and used for different lithium salts in several solvents. The results show clearly that the assumptions made for every method affect the measured transference number a lot. They can have different values depending on the used method and the concentration dependence can even have contrary tendencies for methods with electrochemical or spectroscopic aspects. The influence of ion pairs is the determining factor at the measurements. For a full characterization of electrolytes a complete set of transport parameters is necessary, including diffusion coefficients, conductivity, transference number and ideally activity coefficients. The new electrolyte lithium difluoromono(oxalato)borate LiDFOB in EC/DEC (3/7) was for example fully determined at 25 C in this work. In comparison with other salts (LiPF6 und LiBF4) it proves to be an appropriate electrolyte for lithium-ion batteries. It generates no HF by hydrolysis that avoids the use of environment friendly and cost-effective manganese spinels, and it much better soluble as lithium bis(oxalato)borate LiBOB. In addition LiDFOB protects aluminum from corrosion and is more thermal stable as the standard salt LiPF6.}
place = {Germany}
year = {2011}
month = {Mar}
}