Quantum transport and the Wigner distribution function for Bloch electrons in spatially homogeneous electric and magnetic fields

The theory of Bloch electron dynamics for carriers in homogeneous electric and magnetic fields of arbitrary time dependence is developed in the framework of the Liouville equation. The Wigner distribution function (WDF) is determined from the single-particle density matrix in the ballistic regime, i...

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Veröffentlicht in:	Physical review. B 2017-10, Vol.96 (14), Article 144303
Hauptverfasser:	Iafrate, G. J., Sokolov, V. N., Krieger, J. B.
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Schlagworte:	Boltzmann transport equation Collision dynamics Distribution functions Electric fields Electrons Free electrons Liouville equations Lorentz force Magnetic fields Methodology Momentum Particle density (concentration) Quantum transport Representations Time dependence Transformations (mathematics) Transport equations Wigner distribution
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description	The theory of Bloch electron dynamics for carriers in homogeneous electric and magnetic fields of arbitrary time dependence is developed in the framework of the Liouville equation. The Wigner distribution function (WDF) is determined from the single-particle density matrix in the ballistic regime, i.e., collision effects are excluded. In the theory, the single-particle transport equation is established with the electric field described in the vector potential gauge, and the magnetic field is treated in the symmetric gauge. No specific assumptions are made concerning the form of the initial distribution in momentum or configuration space. The general approach is to employ the accelerated Bloch state representation (ABR) as a basis so that the dependence upon the electric field, including multiband Zener tunneling, is treated exactly. Further, in the formulation of the WDF, we transform to a new set of variables so that the final WDF is gauge invariant and is expressed explicitly in terms of the position, kinetic momentum, and time. The methodology for developing the WDF is illustrated by deriving the exact WDF equation for free electrons in homogeneous electric and magnetic fields resulting in the same form as given by the collisionless Boltzmann transport equation (BTE). The methodology is then extended to the case of electrons described by an effective Hamiltonian corresponding to an arbitrary energy band function; the exact WDF equation results for the effective Hamiltonian case are shown to approximate the free electron results when taken to second order in the magnetic field. As a corollary, in these cases, it is shown that if the WDF is a wave packet, then the time rate of change of the electron quasimomentum is given by the Lorentz force. In treating the problem of Bloch electrons in a periodic potential in the presence of homogeneous electric and magnetic fields, the methodology for deriving the WDF reveals a multiband character due to the inherent nature of the Bloch states. The K0 representation of the Bloch envelope functions is employed to express the multiband WDF in a useful form. In examining the single-band WDF, it is found that the collisionless WDF equation matches the equivalent BTE to first order in the magnetic field. These results are necessarily extended to second order in the magnetic field by employing a unitary transformation that diagonalizes the Hamiltonian using the ABR to second order. The unitary transformation process include
doi_str_mv	10.1103/PhysRevB.96.144303
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J. ; Sokolov, V. N. ; Krieger, J. B.</creator><creatorcontrib>Iafrate, G. J. ; Sokolov, V. N. ; Krieger, J. B.</creatorcontrib><description>The theory of Bloch electron dynamics for carriers in homogeneous electric and magnetic fields of arbitrary time dependence is developed in the framework of the Liouville equation. The Wigner distribution function (WDF) is determined from the single-particle density matrix in the ballistic regime, i.e., collision effects are excluded. In the theory, the single-particle transport equation is established with the electric field described in the vector potential gauge, and the magnetic field is treated in the symmetric gauge. No specific assumptions are made concerning the form of the initial distribution in momentum or configuration space. The general approach is to employ the accelerated Bloch state representation (ABR) as a basis so that the dependence upon the electric field, including multiband Zener tunneling, is treated exactly. Further, in the formulation of the WDF, we transform to a new set of variables so that the final WDF is gauge invariant and is expressed explicitly in terms of the position, kinetic momentum, and time. The methodology for developing the WDF is illustrated by deriving the exact WDF equation for free electrons in homogeneous electric and magnetic fields resulting in the same form as given by the collisionless Boltzmann transport equation (BTE). The methodology is then extended to the case of electrons described by an effective Hamiltonian corresponding to an arbitrary energy band function; the exact WDF equation results for the effective Hamiltonian case are shown to approximate the free electron results when taken to second order in the magnetic field. As a corollary, in these cases, it is shown that if the WDF is a wave packet, then the time rate of change of the electron quasimomentum is given by the Lorentz force. In treating the problem of Bloch electrons in a periodic potential in the presence of homogeneous electric and magnetic fields, the methodology for deriving the WDF reveals a multiband character due to the inherent nature of the Bloch states. The K0 representation of the Bloch envelope functions is employed to express the multiband WDF in a useful form. In examining the single-band WDF, it is found that the collisionless WDF equation matches the equivalent BTE to first order in the magnetic field. These results are necessarily extended to second order in the magnetic field by employing a unitary transformation that diagonalizes the Hamiltonian using the ABR to second order. 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B</title><description>The theory of Bloch electron dynamics for carriers in homogeneous electric and magnetic fields of arbitrary time dependence is developed in the framework of the Liouville equation. The Wigner distribution function (WDF) is determined from the single-particle density matrix in the ballistic regime, i.e., collision effects are excluded. In the theory, the single-particle transport equation is established with the electric field described in the vector potential gauge, and the magnetic field is treated in the symmetric gauge. No specific assumptions are made concerning the form of the initial distribution in momentum or configuration space. The general approach is to employ the accelerated Bloch state representation (ABR) as a basis so that the dependence upon the electric field, including multiband Zener tunneling, is treated exactly. Further, in the formulation of the WDF, we transform to a new set of variables so that the final WDF is gauge invariant and is expressed explicitly in terms of the position, kinetic momentum, and time. The methodology for developing the WDF is illustrated by deriving the exact WDF equation for free electrons in homogeneous electric and magnetic fields resulting in the same form as given by the collisionless Boltzmann transport equation (BTE). The methodology is then extended to the case of electrons described by an effective Hamiltonian corresponding to an arbitrary energy band function; the exact WDF equation results for the effective Hamiltonian case are shown to approximate the free electron results when taken to second order in the magnetic field. As a corollary, in these cases, it is shown that if the WDF is a wave packet, then the time rate of change of the electron quasimomentum is given by the Lorentz force. In treating the problem of Bloch electrons in a periodic potential in the presence of homogeneous electric and magnetic fields, the methodology for deriving the WDF reveals a multiband character due to the inherent nature of the Bloch states. The K0 representation of the Bloch envelope functions is employed to express the multiband WDF in a useful form. In examining the single-band WDF, it is found that the collisionless WDF equation matches the equivalent BTE to first order in the magnetic field. These results are necessarily extended to second order in the magnetic field by employing a unitary transformation that diagonalizes the Hamiltonian using the ABR to second order. The unitary transformation process includes a discussion of the multiband WDF transport analysis and the identification of the combined Zener-magnetic-field induced tunneling.</description><subject>Boltzmann transport equation</subject><subject>Collision dynamics</subject><subject>Distribution functions</subject><subject>Electric fields</subject><subject>Electrons</subject><subject>Free electrons</subject><subject>Liouville equations</subject><subject>Lorentz force</subject><subject>Magnetic fields</subject><subject>Methodology</subject><subject>Momentum</subject><subject>Particle density (concentration)</subject><subject>Quantum transport</subject><subject>Representations</subject><subject>Time dependence</subject><subject>Transformations (mathematics)</subject><subject>Transport equations</subject><subject>Wigner distribution</subject><issn>2469-9950</issn><issn>2469-9969</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><recordid>eNo9kEtLxDAUhYMoOOj8AVcB1x3zbCdLZ_AFAz5QXIY0TacZ2qQmqTA7f7rVjsKFey4cvss5AFxgtMAY0aunZh9fzOdqIfIFZowiegRmhOUiEyIXx_-ao1Mwj3GHEMI5EgUSM_D1PCiXhg6moFzsfUhQuQqmxsB3u3UmwMrGFGw5JOsdrAenJ-EDXLVeN9C0RqfgXYTWwdirZFXb7mHjO781zvghHixW_6I7NWLTeNTWtFU8Bye1aqOZH_YZeLu9eV3fZ5vHu4f19SbTpOApI4xSjo0wxTiYIIoEKzUpeY5LVnOuheJGqULoStUoX-qC54jQMeQSmbpk9AxcTtw--I_BxCR3fghufCkJJhQXfMn46CKTSwcfYzC17IPtVNhLjORP2fKvbClyOZVNvwH9yHaN</recordid><startdate>20171009</startdate><enddate>20171009</enddate><creator>Iafrate, G. J.</creator><creator>Sokolov, V. N.</creator><creator>Krieger, J. B.</creator><general>American Physical Society</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7SR</scope><scope>7U5</scope><scope>8BQ</scope><scope>8FD</scope><scope>H8D</scope><scope>JG9</scope><scope>L7M</scope></search><sort><creationdate>20171009</creationdate><title>Quantum transport and the Wigner distribution function for Bloch electrons in spatially homogeneous electric and magnetic fields</title><author>Iafrate, G. J. ; Sokolov, V. N. ; Krieger, J. B.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c275t-243351e9e79e71203094bc2b561b4f55c9a5eaa79cdaf068c75602397080efb43</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2017</creationdate><topic>Boltzmann transport equation</topic><topic>Collision dynamics</topic><topic>Distribution functions</topic><topic>Electric fields</topic><topic>Electrons</topic><topic>Free electrons</topic><topic>Liouville equations</topic><topic>Lorentz force</topic><topic>Magnetic fields</topic><topic>Methodology</topic><topic>Momentum</topic><topic>Particle density (concentration)</topic><topic>Quantum transport</topic><topic>Representations</topic><topic>Time dependence</topic><topic>Transformations (mathematics)</topic><topic>Transport equations</topic><topic>Wigner distribution</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Iafrate, G. J.</creatorcontrib><creatorcontrib>Sokolov, V. N.</creatorcontrib><creatorcontrib>Krieger, J. B.</creatorcontrib><collection>CrossRef</collection><collection>Engineered Materials Abstracts</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Aerospace Database</collection><collection>Materials Research Database</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>Physical review. B</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Iafrate, G. J.</au><au>Sokolov, V. N.</au><au>Krieger, J. B.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Quantum transport and the Wigner distribution function for Bloch electrons in spatially homogeneous electric and magnetic fields</atitle><jtitle>Physical review. B</jtitle><date>2017-10-09</date><risdate>2017</risdate><volume>96</volume><issue>14</issue><artnum>144303</artnum><issn>2469-9950</issn><eissn>2469-9969</eissn><abstract>The theory of Bloch electron dynamics for carriers in homogeneous electric and magnetic fields of arbitrary time dependence is developed in the framework of the Liouville equation. The Wigner distribution function (WDF) is determined from the single-particle density matrix in the ballistic regime, i.e., collision effects are excluded. In the theory, the single-particle transport equation is established with the electric field described in the vector potential gauge, and the magnetic field is treated in the symmetric gauge. No specific assumptions are made concerning the form of the initial distribution in momentum or configuration space. The general approach is to employ the accelerated Bloch state representation (ABR) as a basis so that the dependence upon the electric field, including multiband Zener tunneling, is treated exactly. Further, in the formulation of the WDF, we transform to a new set of variables so that the final WDF is gauge invariant and is expressed explicitly in terms of the position, kinetic momentum, and time. The methodology for developing the WDF is illustrated by deriving the exact WDF equation for free electrons in homogeneous electric and magnetic fields resulting in the same form as given by the collisionless Boltzmann transport equation (BTE). The methodology is then extended to the case of electrons described by an effective Hamiltonian corresponding to an arbitrary energy band function; the exact WDF equation results for the effective Hamiltonian case are shown to approximate the free electron results when taken to second order in the magnetic field. As a corollary, in these cases, it is shown that if the WDF is a wave packet, then the time rate of change of the electron quasimomentum is given by the Lorentz force. In treating the problem of Bloch electrons in a periodic potential in the presence of homogeneous electric and magnetic fields, the methodology for deriving the WDF reveals a multiband character due to the inherent nature of the Bloch states. The K0 representation of the Bloch envelope functions is employed to express the multiband WDF in a useful form. In examining the single-band WDF, it is found that the collisionless WDF equation matches the equivalent BTE to first order in the magnetic field. These results are necessarily extended to second order in the magnetic field by employing a unitary transformation that diagonalizes the Hamiltonian using the ABR to second order. The unitary transformation process includes a discussion of the multiband WDF transport analysis and the identification of the combined Zener-magnetic-field induced tunneling.</abstract><cop>College Park</cop><pub>American Physical Society</pub><doi>10.1103/PhysRevB.96.144303</doi></addata></record>
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subjects	Boltzmann transport equation Collision dynamics Distribution functions Electric fields Electrons Free electrons Liouville equations Lorentz force Magnetic fields Methodology Momentum Particle density (concentration) Quantum transport Representations Time dependence Transformations (mathematics) Transport equations Wigner distribution
title	Quantum transport and the Wigner distribution function for Bloch electrons in spatially homogeneous electric and magnetic fields
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