Journal articles: 'Electric field effectsFerromagnetismIonic transport'

1

Ferry, David K. "High electric field transport in GaAs0.51Sb0.49." Semiconductor Science and Technology 36, no. 4 (2021): 045024. http://dx.doi.org/10.1088/1361-6641/abeb50.

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Zucchetti, C., A. Marchionni, M. Bollani, F. Ciccacci, M. Finazzi, and F. Bottegoni. "Electric field modulation of spin transport." APL Materials 10, no. 1 (2022): 011102. http://dx.doi.org/10.1063/5.0073180.

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3

Sahoo, Sangeeta, Takis Kontos, Jürg Furer, et al. "Electric field control of spin transport." Nature Physics 1, no. 2 (2005): 99–102. http://dx.doi.org/10.1038/nphys149.

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Mollee, T. R., Y. G. Anissimov, and M. S. Roberts. "Periodic electric field enhanced transport through membranes." Journal of Membrane Science 278, no. 1-2 (2006): 290–300. http://dx.doi.org/10.1016/j.memsci.2004.10.049.

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van der Hilst, J. B. C., J. A. van Hulst, N. N. Gribov, J. Caro, and S. Radelaar. "High electric field transport in bismuth nanoconstrictions." Physica B: Condensed Matter 218, no. 1-4 (1996): 109–12. http://dx.doi.org/10.1016/0921-4526(95)00571-4.

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6

Kick, M., H. Maaßberg, M. Anton, et al. "Electric field and transport in W7-AS." Plasma Physics and Controlled Fusion 41, no. 3A (1999): A549—A559. http://dx.doi.org/10.1088/0741-3335/41/3a/048.

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7

Hu, G. Y., and R. F. O'Connell. "A theory of high electric field transport." Physica A: Statistical Mechanics and its Applications 149, no. 1-2 (1988): 1–25. http://dx.doi.org/10.1016/0378-4371(88)90206-3.

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8

Kleinertand, P., and V. V. Bryksin. "Electric-field-induced hopping transport in superlattices." physica status solidi (b) 241, no. 1 (2004): 54–60. http://dx.doi.org/10.1002/pssb.200303626.

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9

Kubota, Tetsuyuki, and Sanae‐I Itoh. "Transport matrix and electric field formation in stochastic magnetic field." Physics of Plasmas 2, no. 9 (1995): 3368–73. http://dx.doi.org/10.1063/1.871171.

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10

Zhao, Yongsheng, Fengyun Yan, Xue Liu, Hongfeng Ma, Zhenyu Zhang, and Aisheng Jiao. "Thermal Transport Properties of Diamond Phonons by Electric Field." Nanomaterials 12, no. 19 (2022): 3399. http://dx.doi.org/10.3390/nano12193399.

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For the preparation of diamond heat sinks with ultra-high thermal conductivity by Chemical Vapor Deposition (CVD) technology, the influence of diamond growth direction and electric field on thermal conductivity is worth exploring. In this work, the phonon and thermal transport properties of diamond in three crystal orientation groups (<100>, <110>, and <111>) were investigated using first-principles calculations by electric field. The results show that the response of the diamond in the three-crystal orientation groups presented an obvious anisotropy under positive and negative electric fields. The electric field can break the symmetry of the diamond lattice, causing the electron density around the C atoms to be segregated with the direction of the electric field. Then the phonon spectrum and the thermodynamic properties of diamond were changed. At the same time, due to the coupling relationship between electrons and phonons, the electric field can affect the phonon group velocity, phonon mean free path, phonon–phonon interaction strength and phonon lifetime of the diamond. In the crystal orientation [111], when the electric field strength is ±0.004 a.u., the thermal conductivity is 2654 and 1283 , respectively. The main reason for the change in the thermal conductivity of the diamond lattice caused by the electric field is that the electric field has an acceleration effect on the extranuclear electrons of the C atoms in the diamond. Due to the coupling relationship between the electrons and the phonons, the thermodynamic and phonon properties of the diamond change.

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11

Talwalkar, N., A. Das, and J. Vasi. "Dispersive transport of carriers under nonuniform electric field." Journal of Applied Physics 78, no. 7 (1995): 4487–89. http://dx.doi.org/10.1063/1.359859.

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Kontturi, Anna-Kaisa, Ky�sti Kontturi, and Pasi Niinikoski. "Transport of lignosulphonates under an external electric field." Journal of the Chemical Society, Faraday Transactions 87, no. 11 (1991): 1779. http://dx.doi.org/10.1039/ft9918701779.

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Bryksin, V. V., and P. Kleinert. "High-electric-field quantum transport for semiconductor superlattices." Journal of Physics A: Mathematical and General 32, no. 15 (1999): 2731–43. http://dx.doi.org/10.1088/0305-4470/32/15/003.

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14

Kemery, Paula J., Jack K. Steehler, and Paul W. Bohn. "Electric Field Mediated Transport in Nanometer Diameter Channels." Langmuir 14, no. 10 (1998): 2884–89. http://dx.doi.org/10.1021/la980147s.

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Li, Ling, Steven Van Winckel, Jan Genoe, and Paul Heremans. "Electric field-dependent charge transport in organic semiconductors." Applied Physics Letters 95, no. 15 (2009): 153301. http://dx.doi.org/10.1063/1.3246160.

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Zhongtian, Wang, and Wang Long. "Asymmetry of Neoclassical Transport by Dipole Electric Field." Plasma Science and Technology 6, no. 5 (2004): 2437–39. http://dx.doi.org/10.1088/1009-0630/6/5/001.

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17

Couturier, G., B. Jean, J. F. Lambert, J. C. Launay, and P. Joffre. "Low and high electric field transport in CdIn2Te4." Journal of Applied Physics 73, no. 4 (1993): 1813–18. http://dx.doi.org/10.1063/1.353191.

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18

Buenfeld, Nick R., Gareth K. Glass, Alaa M. Hassanein, and Jian-Zhong Zhang. "Chloride Transport in Concrete Subjected to Electric Field." Journal of Materials in Civil Engineering 10, no. 4 (1998): 220–28. http://dx.doi.org/10.1061/(asce)0899-1561(1998)10:4(220).

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19

Miah, M. Idrish. "Electric-field effects in optically generated spin transport." Physics Letters A 373, no. 23-24 (2009): 2097–100. http://dx.doi.org/10.1016/j.physleta.2009.04.021.

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20

Li, Dan, Wenheng Jing, Shuaiqiang Li, Hao Shen, and Weihong Xing. "Electric Field-Controlled Ion Transport In TiO2 Nanochannel." ACS Applied Materials & Interfaces 7, no. 21 (2015): 11294–300. http://dx.doi.org/10.1021/acsami.5b01505.

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21

Grodzinsky, A. J., and A. M. Weiss. "Electric Field Control of Membrane Transport and Separations." Separation and Purification Methods 14, no. 1 (1985): 1–40. http://dx.doi.org/10.1080/03602548508068410.

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22

Hill, Reghan J. "Electric-field-enhanced transport in polyacrylamide hydrogel nanocomposites." Journal of Colloid and Interface Science 316, no. 2 (2007): 635–44. http://dx.doi.org/10.1016/j.jcis.2007.09.020.

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23

Abou El-Ela, F. M., and A. Z. Mohamed. "Electron Transport Characteristics of Wurtzite GaN." ISRN Condensed Matter Physics 2013 (September 9, 2013): 1–6. http://dx.doi.org/10.1155/2013/654752.

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A three-valley Monte Carlo simulation approach was used to investigate electron transport in wurtzite GaN such as the drift velocity, the drift mobility, the average electron energy, energy relaxation time, and momentum relaxation time at high electric fields. The simulation accounted for polar optical phonon, acoustic phonon, piezoelectric, intervalley scattering, and Ridley charged impurity scattering model. For the steady-state transport, the drift velocity against electric field showed a negative differential resistance of a peak value of 2.9×105 m/s at a critical electric field strength 180×105 V/m. The electron drift velocity relaxes to the saturation value of 1.5×105 m/s at very high electric fields. The electron velocities against time over wide range of electric fields are reported.

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24

Zhou, Ke, and Zhiping Xu. "Field-enhanced selectivity in nanoconfined ionic transport." Nanoscale 12, no. 11 (2020): 6512–21. http://dx.doi.org/10.1039/c9nr10731b.

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25

CHIEN, L. H., A. SERGEEV, N. VAGIDOV, and V. MITIN. "HOT-ELECTRON TRANSPORT IN QUANTUM-DOT PHOTODETECTORS." International Journal of High Speed Electronics and Systems 18, no. 04 (2008): 1013–22. http://dx.doi.org/10.1142/s0129156408005965.

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Employing Monte-Carlo simulations we investigate effects of an electric field on electron kinetics and transport in quantum-dot structures with potential barriers created around dots via intentional or unintentional doping. Results of our simulations demonstrate that the photoelectron capture is substantially enhanced in strong electric fields and this process has an exponential character. Detailed analysis shows that effects of the electric field on electron capture in the structures with barriers are not sensitive to the redistribution of electrons between valleys and these effects are not related to an increase of drift velocity. Most data find adequate explanation in the model of hot-electron transport in the potential relief of quantum dots. Electron kinetics controllable by potential barriers and an electric field may provide significant improvements in the photoconductive gain, detectivity, and responsivity of photodetectors.

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26

Tu, Shuang Z., Chao Jiang, Thomas R. Junk, and Tingjun Yang. "A numerical solver for investigating the space charge effect on the electric field in liquid argon time projection chambers." Journal of Instrumentation 18, no. 06 (2023): P06022. http://dx.doi.org/10.1088/1748-0221/18/06/p06022.

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Abstract This paper reports the development of a numerical solver aimed to simulate the interaction between the space charge (i.e. ions) distribution and the electric field in liquid argon time projection chamber (LArTPC) detectors. The ion transport equation is solved by a time-accurate, cell-centered finite volume method and the electric potential equation by a continuous finite element method. The electric potential equation updates the electric field which provides the drift velocity to the ion transport equation. The ion transport equation updates the space charge density distribution which appears as the source term in the electric potential equation. The interaction between the space charge distribution and the electric field is numerically simulated within each physical time step. The convective velocity in the ion transport equation can include the background flow velocity in addition to the electric drift velocity. The numerical solver has been parallelized using the Message Passing Interface (MPI) library. Numerical tests show and verify the capability and accuracy of the current numerical solver. It is planned that the developed numerical solver, together with a Computational Fluid Dynamics (CFD) package which provides the flow velocity field, can be used to investigate the space charge effect on the electric field in large-scale particle detectors.

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27

LEI, X. L., N. J. M. HORING, and H. L. CUI. "TEMPORAL DEVELOPMENT OF NONLINEAR BLOCH ELECTRON MINIBAND TRANSPORT." Modern Physics Letters B 06, no. 16n17 (1992): 1075–82. http://dx.doi.org/10.1142/s0217984992001927.

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We present a balance-equation calculation of the transient response of Bloch electron transport in a superlattice miniband to an external time-dependent electric field parallel to the growth axis. Upon turning on a step electric field having strength within the range of negative differential mobility in the steady-state velocity-field curve, the drift velocity exhibits very pronounced overshoot. Immediately after the drift velocity reaches its maximum, the instantaneous inverse effective mass may fall within the range of negative values in consequence of the driving field. The rise of the electron temperature, however, is much slower, such that the behavior of the velocity response to an impulsive electric field is markedly dependent on the duration of the impulse.

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28

Feneberg, W., and M. A. Hellberg. "Transport in an Ergodic Magnetic Field with Ambipolar Electric Field Effects." Contributions to Plasma Physics 28, no. 4-5 (1988): 329–32. http://dx.doi.org/10.1002/ctpp.2150280409.

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29

Sano, Nobuyuki, and Akira Yoshii. "Quantum Kinetic Transport under High Electric Fields." VLSI Design 6, no. 1-4 (1998): 3–7. http://dx.doi.org/10.1155/1998/38125.

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Quantum kinetic transport under high electric fields is investigated with emphasis on the intracollisional field effect (ICFE) in low-dimensional structures. It is shown that the ICFE in GaAs one-dimensional quantum wires is already significant under moderate electric field strengths (≥ a few hundreds V/cm). This is a marked contrast to the cases in bulk, where the ICFE is expected to be significant under extremely strong electric fields (≥ MV/cm). Employing the Monte Carlo method including the ICFE, the electron drift velocity in quantum wires is shown to be much smaller than that expected from earlier investigations.

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30

Basenko, V. R., A. N. Tsvetkov, T. I. Petrov, A. R. Ibragimova, and R. N. Rahmaev. "Development of an electric drive system of modular design for small vessels." Power engineering: research, equipment, technology 26, no. 6 (2025): 69–80. https://doi.org/10.30724/1998-9903-2024-26-6-69-80.

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RELEVANCE. The transition to an electric mode of transport is becoming more and more relevant due to the development of technologies in the field of electric motors and energy storage devices. One of the tasks set for specialists in the field of electric transport today is the transition of water transport from internal combustion engines to a fully electric drive. This article provides a calculation of an electric drive system of a modular design for small vessels. THE PURPOSE. The goal is to develop an electric drive system for small vessels, which will allow the use of an electric motor and energy storage devices in water transport. METHODS. The design of the electric drive system is based on the model-based design method. RESULTS. As a result, a block diagram of the installation for a small vessel was obtained. CONCLUSION. The creation of electric drive systems of modular design is poorly developed in the domestic mechanical engineering due to the lack of a developed electric transport infrastructure; the creation of domestic developments in this area is of a strategic nature for industry and energy.

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31

Sudorgin, S. A., and N. G. Lebedev. "Temperature dependence of carbon nanoparticles transport characteristics." Вестник Пермского университета. Физика, no. 3 (2020): 24–30. http://dx.doi.org/10.17072/1994-3598-2020-3-24-30.

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Technique for calculating the temperature dependences of transport characteristics of different carbon nanoparticles: single-walled nanotubes, graphene, bilayer graphene in a constant external electric field is proposed. Formulas for conductivity and the diffusion coefficient of electrons in carbon nanostructures obtained analytically and analyzed numerically. Conductivity in single-walled and bilayer carbon nanostructures decreases with increasing temperature. The electrical conductivity of carbon nanoparticles depends nonlinearly on the amplitude of the external constant electric field for various temperatures. With increasing temperature, the coefficient of conductivity decreases. The diffusion coefficient of electrons is independent of temperature for both single-layer and bilayer nanoparticles. A nonlinear dependence of the electron diffusion coefficient on the strength of an external constant electric field is shown. Physical justification of the obtained dependences is propose.

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32

Mikhailov, Valery, Milana Abdullaeva, and Maria Ostapova. "MODEL OF PROFESSIONAL COMPETENCIES OF SPECIALISTS CARRYING OUT CARGO TRANSPORTATION BY RAILWAY ELECTRIC TRANSPORT." Psychological and pedagogical problems of human and social security 2024, no. 2 (2024): 50–57. http://dx.doi.org/10.61260/2074-1618-2024-2-50-57.

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A methodology for developing the professional competence of specialists involved in the transportation of goods on railway electric transport is presented. The need to develop a training ground for practical training in the field of fire safety and emergency protection on railway electric transport is substantiated. Recommendations are given for conducting scientific and technical research and development work in the field of safety and emergency protection, development and implementation of fire safety measures when transporting goods by electric railway transport. A multi-level model of professional competencies of a specialist in railway electric transport is presented and justified, guaranteeing the adequacy of the choice of actions and actions of specialists, including the implementation and transmission of best practices.

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33

NEBEL, C. E., and R. A. STREET. "HIGH FIELD TRANSPORT IN a-Si:H." International Journal of Modern Physics B 07, no. 05 (1993): 1207–58. http://dx.doi.org/10.1142/s0217979293002304.

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Electric field dependent DC-dark and transient photoconductivity data measured over a broad temperature (10 K ≤T≤300 K ) and field regime (102 V/cm ≤F≤6×105 V/cm ) in phosphorus and boron doped and intrinsic amorphous hydrogenated silicon (a-Si:H) are described. The data demonstrate the strong influence of the electric field on carrier propagation. Enhancements over 6 orders of magnitude in conductivity (σ) are achieved for fields greater than 105 V/cm , which changes a-Si:H films from highly insulating to very conductive at low temperatures. The field dependence is described empirically by a power law a~Fy with y in the range 10≤y≤17. The enhancement and y depend on doping level with significant differences between electron and hole currents. These results are confirmed by transient photoconductivity experiments on intrinsic a-Si:H from which the carrier mobility (μ D ) and the μτ-product are deduced. The drift mobility is enhanced by many orders of magnitude up to values of μ D >10−2 cm 2/ Vs and is identified as parameter which dominates high field transport. The increase in mobility is comparable to the increase in conductivity and shows a time- and thickness dependence indicative of dispersive transport. The data is interpreted introducing a field-enhanced nearest neighbor hopping model which is governed by ballistic capture and field induced re-emission.

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34

Omura, Yasuhisa. "Model-Based Theoretical Prediction of the Electric Field Dependence of the Diffusion Coefficients of Various Semiconductor Wires." Jordan Journal of Electrical Engineering 11, no. 1 (2024): 1. http://dx.doi.org/10.5455/jjee.204-1711432905.

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This paper investigates how the diffusion coefficients of various semiconductor wires - namely Si, Ge, and 4H-SiC - are modulated by an external electric field assuming steady-state transport. This theoretical investigation consists of two steps. In the first step, we derive a model-based theoretical expression of the diffusion coefficient based on the continuity equation. Since this consideration is too simplified, in the second step, we perform Monte Carlo simulations to investigate how the electric field alters the electron occupation fraction of energy band valleys; for this, quantum mechanical scattering events during transport are calculated. Using these calculations, the electric field dependence of the diffusion coefficients of Ge and 4H-SiC wires with various cross-sectional areas is investigated because the conduction process of such materials is strongly ruled by the multi-valley transport of electrons. The obtained results reveal that the diffusion coefficient of Ge wires is constant when the electric field rises at 200 K and 400 K; but it rebounds under very high electric fields above 400 K due to the increase in the intrinsic carrier concentration. On the other hand, it is shown that the diffusion coefficient of 4H-SiC wires increases as the electric field rises in a low electric field range regardless of temperature, but it drops under high electric fields. Thus, it is considered that the theoretical models assumed for various semiconductor wires are useful in estimating the steady-state transport characteristics of scaled devices in a practical range of temperatures around room temperature.

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35

Ding, Xin‐Lei, Zeng‐Qiang Wu, Zhong‐Qiu Li, and Xing‐Hua Xia. "Electric Field Driven Surface Ion Transport in Hydrophobic Nanopores †." Chinese Journal of Chemistry 39, no. 6 (2021): 1511–16. http://dx.doi.org/10.1002/cjoc.202000730.

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36

Bryksin, V. V., and P. Kleinert. "High-electric-field quantum transport theory for semiconductor superlattices." Journal of Physics A: Mathematical and General 33, no. 2 (1999): 233–46. http://dx.doi.org/10.1088/0305-4470/33/2/301.

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37

Rodrigues, Clóves G., Áurea R. Vasconcellos, Roberto Luzzi, and Valder N. Freire. "Nonlinear transport properties of III-nitrides in electric field." Journal of Applied Physics 98, no. 4 (2005): 043702. http://dx.doi.org/10.1063/1.1999024.

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38

Kuz’min, Yu I. "Electric field induced by vortex transport in percolation superconductors." Physics of the Solid State 58, no. 10 (2016): 1945–51. http://dx.doi.org/10.1134/s1063783416100218.

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39

Seyidov, MirHasan Yu, Rauf A. Suleymanov, Ertan Balaban, and Yasin Şale. "Imprint electric field controlled electronic transport in TlGaSe2 crystals." Journal of Applied Physics 114, no. 9 (2013): 093706. http://dx.doi.org/10.1063/1.4819396.

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40

Cherniak, O., and V. I. Zasenko. "Particle trapping effects on transport in random electric field." Journal of Physics: Conference Series 1197 (March 2019): 012003. http://dx.doi.org/10.1088/1742-6596/1197/1/012003.

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41

Drukker, Karen, Simon W. de Leeuw, and Sharon Hammes-Schiffer. "Proton transport along water chains in an electric field." Journal of Chemical Physics 108, no. 16 (1998): 6799–808. http://dx.doi.org/10.1063/1.476095.

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42

Hu, G. Y., and R. F. O’Connell. "Generalized quantum Langevin equations for high-electric-field transport." Physical Review B 39, no. 17 (1989): 12717–22. http://dx.doi.org/10.1103/physrevb.39.12717.

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43

Prigodin, V. N., F. C. Hsu, Y. M. Kim, J. H. Park, O. Waldmann, and A. J. Epstein. "Electric Field Control of Charge Transport in Doped Polymers." Synthetic Metals 153, no. 1-3 (2005): 157–60. http://dx.doi.org/10.1016/j.synthmet.2005.07.180.

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44

Kawahara, T., T. Suzuki, K. Shimura, T. Terashima та Y. Bando. "Electric field effects on transport properties in YBa2Cu3O7−δ". Physica C: Superconductivity 235-240 (грудень 1994): 3363–64. http://dx.doi.org/10.1016/0921-4534(94)91208-4.

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45

Fukuyama, A., Y. Fuji, K. Itoh, and S. I. Itoh. "Transport modelling including radial electric field and plasma rotation." Plasma Physics and Controlled Fusion 36, no. 7A (1994): A159—A164. http://dx.doi.org/10.1088/0741-3335/36/7a/021.

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46

Semichaevsky, Andrey V., Harley T. Johnson, Khiam-How Low, Dibyadeep Paul, Abhijit Chandra, and Ashraf Bastawros. "Focused Electric Field-Induced Ion Transport: Experiments and Modeling." Electrochemical and Solid-State Letters 13, no. 12 (2010): D100. http://dx.doi.org/10.1149/1.3496405.

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47

Humble, Paul H., John N. Harb, H. Dennis Tolley, Adam T. Woolley, Paul B. Farnsworth, and Milton L. Lee. "Influence of transport properties in electric field gradient focusing." Journal of Chromatography A 1160, no. 1-2 (2007): 311–19. http://dx.doi.org/10.1016/j.chroma.2007.04.013.

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48

van Ancum, G. K., M. A. J. Verhoeven, D. H. A. Blank та H. Rogalla. "Electric-field activated variable-range hopping transport inPrBa2Cu3O7−δ". Physical Review B 52, № 8 (1995): 5598–602. http://dx.doi.org/10.1103/physrevb.52.5598.

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49

Sanchez, T. Gonzalez, J. E. Velazquez Perez, P. M. Gutierrez Conde, and D. Pardo Collantes. "Electron transport in InP under high electric field conditions." Semiconductor Science and Technology 7, no. 1 (1992): 31–36. http://dx.doi.org/10.1088/0268-1242/7/1/006.

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50

Nebel, C. E., R. A. Street, N. M. Johnson, and J. Kocka. "High-electric-field transport ina-Si:H. I. Transient photoconductivity." Physical Review B 46, no. 11 (1992): 6789–802. http://dx.doi.org/10.1103/physrevb.46.6789.

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Journal articles on the topic 'Electric field effectsFerromagnetismIonic transport'

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