IONIC CHARGE TRANSPORT IN MOLECULAR MATERIALS: POLYMER ELECTROLYTES

ABSTRACTWe developed a method to predict the charge transport (CT) type (hole or electron) in molecular materials that uses molecular orbital calculations. The hole-and-electron-mobility ratios of molecular materials were calculated based on molecular structural reorganization energies in a charge hopping process. The CT types predicted from the calculated mobility ratios agreed with those experimentally obtained in seven of the eight model molecules.

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Charge Transport Properties of a Partially Reduced V2O5 Xerogel Intercalated with a Polymer Electrolyte

MRS Proceedings ◽

10.1557/proc-393-131 ◽

1995 ◽

Vol 393 ◽

Author(s):

Joyce Albritton Thomas ◽

Grant M. Kloster ◽

D. Shriver ◽

C. R. Kannewurf

Keyword(s):

Charge Transport ◽

Transport Properties ◽

Polymer Electrolyte ◽

Variable Temperature ◽

Sol Gel ◽

Electronic Conductivity ◽

Charge Carriers ◽

Electronic Charge ◽

Ionic Charge ◽

Intimate Contact

ABSTRACTRecently, there has been considerable interest in advanced materials and processing techniques for practical applications. V2O5 xerogels have generated much attention because they are layered materials that undergo reversible redox intercalation with lithium. The sol-gel process has been used to intercalate V2O5 xerogels with the polymer electrolyte, oxymethylene linked poly(ethylene oxide) - lithium triflate [(a-PEO)n(LiCF3SO3)]. The resulting nanocomposite is a mixed ionic-electronic conductor in which the ionic charge carriers in the polymer electrolyte are in intimate contact with the electronic charge carriers in the V205 xerogel. Variable-temperature electronic conductivity and thermoelectric power measurements have been performed to examine the charge transport properties.

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Development of new hole-transporting amorphous molecular materials for organic electroluminescent devices and their charge-transport properties

10.1117/12.416890 ◽

2001 ◽

Cited By ~ 5

Author(s):

Yasuhiko Shirota ◽

Kenji Okumoto

Keyword(s):

Charge Transport ◽

Transport Properties ◽

Molecular Materials ◽

Electroluminescent Devices ◽

Hole Transporting ◽

Organic Electroluminescent

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Self-dissociation and protonic charge transport in water and

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1958.0208 ◽

1958 ◽

Vol 247 (1251) ◽

pp. 505-533 ◽

Cited By ~ 404

Keyword(s):

Aqueous Solutions ◽

Charge Transport ◽

Proton Transport ◽

Reaction Rates ◽

Transport Processes ◽

Electronic Charge ◽

Kinetic Properties ◽

Theoretical Treatment ◽

Relaxation Techniques ◽

Ionic Charge

A comprehensive survey on experimental techniques, results and theoretical interpretations concerning the self-dissociation and protonic charge transport in water and ice is given. Recent investigations of fast protolytic reactions in pure water and aqueous solutions by means of relaxation techniques complete our knowledge about state and kinetic properties of the proton in this medium. In comparison here with our experience regarding the same properties in ice crystals are far less complete, as usual techniques of aqueous solutions are not applicable. Direct measurements of individual properties of ‘excess’ and ‘defect’ protons in ice (mobilities, concentrations, reaction rates) are presented. The proton transport in hydrogen-bonded media is completely different from normal ionic migration and corresponds more to electronic transport processes in semi-conductors. Generally the proton transport through hydrogen bonds includes two processes: (1) The formation (or rearrangement) of (H-bond) structure with orientation, favourable for a proton transition, and (2) the charge transfer within the H bond. The first step is rate determining in water, whereas the second one is decisive for the charge transport in ice. The requirements for a theoretical treatment therefore are (1) for water: a theory of ‘structural diffusion’ of the H-bonded hydration complex of H 3 O + , and (2) for ice: a (quantum-mechanical) theory of the protonic motion within the potential well of the H bond. The mechanism of structural diffusion provides an explanation of the anomalous H 3 O + and OH - mobility and their recombination rate in water. The difference between protonic and normal ionic charge transport occurs most obviously in the absolute values of mobilities in ice. The proton mobility in ice differs by many orders of magnitude from that of normal ions, but only by a factor of about 50 from electronic mobilities in some metals and semi-conductors. Further arguments, demonstrating the analogy between protonic and electronic charge transport are given. The reaction kinetics of protolytic systems and the fast proton transport in H-bonded systems are of certain importance with respect to biological problems.

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Ionic Hopping Transport in Chitosan-Based Polymer Electrolytes

Materials Science Forum ◽

10.4028/www.scientific.net/msf.517.237 ◽

2006 ◽

Vol 517 ◽

pp. 237-241 ◽

Cited By ~ 2

Author(s):

A.S.A. Khiar ◽

S.R. Majid ◽

N.H. Idris ◽

M.F. Hassan ◽

R. Puteh ◽

...

Keyword(s):

Ionic Conductivity ◽

Charge Transport ◽

Polymer Electrolytes ◽

Electric Modulus ◽

Dissipation Factor ◽

Electrical Modulus ◽

Hopping Transport ◽

Hopping Mechanism ◽

Linear Behavior ◽

Tan Δ

Measurement of the ionic conductivity for the CA-NH4CF3SO3-DMC system was carried out at frequencies of 50 Hz to1 MHz and also at temperatures of 298 K to 313 K. The plot of log σ versus 1000/T shows a linear behavior suggesting that the samples obey the Arrhenius relationship. The electrical relaxation of the system was analyzed using the complex electric modulus M* of the sample with the highest ionic conductivity at various temperatures. The analysis of electrical modulus and dissipation factor (tan δ) shows that charge transport occurs through a hopping mechanism.

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Amorphous molecular materials: charge transport in the glassy state of N,N′-di(biphenylyl)-N,N′-diphenyl-[1,1′-biphenyl]-4,4′-diamines

Synthetic Metals ◽

10.1016/s0379-6779(99)00421-x ◽

2000 ◽

Vol 111-112 ◽

pp. 473-476 ◽

Cited By ~ 23

Author(s):

Kenji Okumoto ◽

Kenjiro Wayaku ◽

Tetsuya Noda ◽

Hiroshi Kageyama ◽

Yasuhiko Shirota

Keyword(s):

Charge Transport ◽

Glassy State ◽

Molecular Materials

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Interfacing Electronic and Ionic Charge Transport in Bioelectronics

ChemElectroChem ◽

10.1002/celc.201500555 ◽

2016 ◽

Vol 3 (5) ◽

pp. 686-688 ◽

Cited By ~ 36

Author(s):

David C. Martin ◽

George G. Malliaras

Keyword(s):

Charge Transport ◽

Ionic Charge

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How to calculate charge mobility in molecular materials from surface hopping non-adiabatic molecular dynamics – beyond the hopping/band paradigm

Physical Chemistry Chemical Physics ◽

10.1039/c9cp04770k ◽

2019 ◽

Vol 21 (48) ◽

pp. 26368-26386 ◽

Cited By ~ 5

Author(s):

Antoine Carof ◽

Samuele Giannini ◽

Jochen Blumberger

Keyword(s):

Molecular Dynamics ◽

Charge Transfer ◽

Charge Transport ◽

Organic Semiconductors ◽

High Mobility ◽

Molecular Materials ◽

Surface Hopping ◽

Charge Mobility

We present an efficient surface hopping approach tailored to study charge transport in high mobility organic semiconductors and discuss key improvements with regard to decoherence, trivial crossings and spurious charge transfer.

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