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Journal articles on the topic 'Quantum magnetic field'

Author: Grafiati
Published: 4 June 2021
Last updated: 15 February 2022

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1

Lukiyanets, B., and D. Matulka. "Effect of magnetic field on quantum capacitance of the nanoobject." Mathematical Modeling and Computing 2, no. 2 (2015): 176–82. http://dx.doi.org/10.23939/mmc2015.02.176.

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2

Lührmann, Jonas. "Mean-field quantum dynamics with magnetic fields." Journal of Mathematical Physics 53, no. 2 (2012): 022105. http://dx.doi.org/10.1063/1.3687024.

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3

MacDonald, AH, Hiroshi Akera, and MR Norman. "Quantum Mechanics and Superconductivity in a Magnetic Field." Australian Journal of Physics 46, no. 3 (1993): 333. http://dx.doi.org/10.1071/ph930333.

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The influence of a magnetic field on superconductivity is usually described either phenomenologically, using Ginzburg-Landau theory, or semiclassically, using Gor'kov theory. In this article we discuss the influence of magnetic fields on the mean-field theory of the superconducting instability from a completely quantum-mechanical point of view. The suppression of superconductivity by an external magnetic field is seen in this more physically accurate picture to be due to the impossibility, in quantum mechanics, of precisely specifying both the centre-of-mass state of a pair and the individual
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4

Logunov, S. E., A. Yu Koshkin, and V. V. Davydov. "Quantum autonomous magnetic field sensor." Journal of Physics: Conference Series 1124 (December 2018): 041025. http://dx.doi.org/10.1088/1742-6596/1124/4/041025.

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5

ZORA, ANNA, CONSTANTINOS SIMSERIDES, and GEORGIOS TRIBERIS. "NEAR FIELD SPECTROSCOPY OF QUANTUM DOTS UNDER MAGNETIC FIELD." International Journal of Modern Physics B 18, no. 27n29 (2004): 3717–21. http://dx.doi.org/10.1142/s0217979204027347.

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We present the basic steps for the study of the linear near field absorption spectra of semiconductor quantum dots under magnetic field of variable orientation. We show that the application of the magnetic field alone is sufficient to induce -increasing the spot illuminated by the near field probe- interesting features to the absorption spectra.
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6

Treumann, R. A., W. Baumjohann, and W. D. Gonzalez. "Collisionless reconnection: magnetic field line interaction." Annales Geophysicae 30, no. 10 (2012): 1515–28. http://dx.doi.org/10.5194/angeo-30-1515-2012.

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Abstract. Magnetic field lines are quantum objects carrying one quantum Φ0 = 2πh/e of magnetic flux and have finite radius λm. Here we argue that they possess a very specific dynamical interaction. Parallel field lines reject each other. When confined to a certain area they form two-dimensional lattices of hexagonal structure. We estimate the filling factor of such an area. Anti-parallel field lines, on the other hand, attract each other. We identify the physical mechanism as being due to the action of the gauge potential field, which we determine quantum mechanically for two parallel and two
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7

Ulrich, J., R. Zobl, K. Unterrainer, G. Strasser, and E. Gornik. "Magnetic-field-enhanced quantum-cascade emission." Applied Physics Letters 76, no. 1 (2000): 19–21. http://dx.doi.org/10.1063/1.125642.

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8

Das, Debarchan, Daniel Gnida, Piotr Wiśniewski, and Dariusz Kaczorowski. "Magnetic field-driven quantum criticality in antiferromagnetic CePtIn4." Proceedings of the National Academy of Sciences 116, no. 41 (2019): 20333–38. http://dx.doi.org/10.1073/pnas.1910293116.

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Physics of the quantum critical point is one of the most perplexing topics in current condensed-matter physics. Its conclusive understanding is forestalled by the scarcity of experimental systems displaying novel aspects of quantum criticality. We present comprehensive experimental evidence of a magnetic field-tuned tricritical point separating paramagnetic, antiferromagnetic, and metamagnetic phases in the compound CePtIn4. Analyzing field variations of its magnetic susceptibility, magnetoresistance, and specific heat at very low temperatures, we trace modifications of the antiferromagnetic s
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9

Shi, Hao, Jie Ma, Xiaofeng Li, Jie Liu, Chao Li, and Shougang Zhang. "A Quantum-Based Microwave Magnetic Field Sensor." Sensors 18, no. 10 (2018): 3288. http://dx.doi.org/10.3390/s18103288.

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In this paper, a quantum-based method for measuring the microwave magnetic field in free space is presented by exploring atomic Rabi resonance in the clock transition of 133Cs. A compact cesium glass cell serving as the microwave magnetic field sensing head was used to measure the spatial distribution of microwave radiation from an open-ended waveguide antenna. The measured microwave magnetic field was not restricted by other microwave devices. The longitudinal distribution of the magnetic field was measured. The experimental results measured by the sensor were in agreement with the simulation
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10

Nefedev, Konstantin, Vitalii Kapitan, and Yuriy Shevchenko. "Magnetic Nanoparticles Arrays for Quantum Calculations." Advanced Materials Research 718-720 (July 2013): 102–6. http://dx.doi.org/10.4028/www.scientific.net/amr.718-720.102.

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In frames of a quantum computer implementation, the ordered array of magnetic dipoles nanoparticles is considered. The phase space calculated for system of dipoles, which interact through long-range magnetostatic field. The behavior of nanoarchitectures in an external magnetic field is studied. The degeneracy of the equilibrium magnetic states depending on the value of an external magnetic field and the spin excess of configurations are determined. The presence of degeneration is a classical analog of quantum superposition, and distribution of probability of magnetic state is a classical repre
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11

SHAPIR, Y., and X. R. WANG. "LOCALIZED ELECTRONS IN A MAGNETIC FIELD." Modern Physics Letters B 04, no. 21 (1990): 1301–19. http://dx.doi.org/10.1142/s0217984990001641.

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We briefly review recent developments on the response of localized electrons to an external magnetic field. They originate from subtle interference effects between forward-scattered paths which, in the localized regime, make the dominant contribution to the transition amplitude. On a lattice the correlations between the paths produce self-similar (quasiperiodic) spatial interference patterns for commensurate (incommensurate) ratios of the applied magnetic flux per plaquette with the flux quantum. If localization is due to strong disorder (as in lightly doped semiconductors), this is augmented
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12

Lukiyanets, B. A., and D. V. Matulka. "Quantum Capacitance of Nanoplates in Magnetic Field." International Journal of Nanoscience 15, no. 01n02 (2016): 1650009. http://dx.doi.org/10.1142/s0219581x16500095.

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We study the quantum capacitance [Formula: see text] in the objects with completely discrete structure of electron states as a result of both dimensional quantization and applied magnetic field. The capacitance is analyzed in such objects as nanoplates of metal, semiconductor and semimetal. Factors which define the form of the dependence of [Formula: see text] on the position of the Fermi level or potential bias, and magnetic field, are analyzed.
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13

Liñares, Jesús, Xesús Prieto-Blanco, Gabriel M. Carral, and María C. Nistal. "Quantum Photonic Simulation of Spin-Magnetic Field Coupling and Atom-Optical Field Interaction." Applied Sciences 10, no. 24 (2020): 8850. http://dx.doi.org/10.3390/app10248850.

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In this work, we present the physical simulation of the dynamical and topological properties of atom-field quantum interacting systems by means of integrated quantum photonic devices. In particular, we simulate mechanical systems used, for example, for quantum processing and requiring a very complex technology such as a spin-1/2 particle interacting with an external classical time-dependent magnetic field and a two-level atom under the action of an external classical time-dependent electric (optical) field (light-matter interaction). The photonic device consists of integrated optical waveguide
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14

Espinosa, O., J. Gamboa, S. Lepe, and F. Méndez. "Nonrelativistic fermions in magnetic fields: a quantum field theory approach." Physics Letters B 520, no. 3-4 (2001): 421–26. http://dx.doi.org/10.1016/s0370-2693(01)01141-8.

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15

Lozovik, Yu E., and N. E. Kaputkina. "Quantum “Crystallization” in Two-Electron Quantum Dot in Magnetic Field." Physica Scripta 57, no. 4 (1998): 538–41. http://dx.doi.org/10.1088/0031-8949/57/4/012.

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16

Gvozdikov, Vladimir M., and Mariya V. Gvozdikova. "Quantum oscillations in superconductors in magnetic field." Physica B: Condensed Matter 284-288 (July 2000): 1894–95. http://dx.doi.org/10.1016/s0921-4526(99)02979-8.

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17

Blanter, Ya M., N. E. Kaputkina, and Yu E. Lozovik. "Two-electron quantum dots in magnetic field." Physica Scripta 54, no. 5 (1996): 539–41. http://dx.doi.org/10.1088/0031-8949/54/5/016.

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18

PÉRÉ-LAPERNE, N., L. A. DE VAULCHIER, Y. GULDNER, C. SIRTORI, and V. BERGER. "QUANTUM CASCADE NANOSTRUCTURES UNDER HIGH MAGNETIC FIELD." International Journal of Modern Physics B 23, no. 12n13 (2009): 2861–66. http://dx.doi.org/10.1142/s0217979209062463.

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Magneto-transport measurements have been performed on two quantum cascade structures, a laser and a detector. These experiments lead to determine the different scattering processes involved in these devices. In the lasers we find both an interface roughness mechanism and LO-phonon scattering of hot carriers in the upper state's Landau levels. In detectors we discover that an inelastic mechanism increase the dark current whereas an elastic one limits the detectivity.
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19

Adamowski, J., and B. Spisak. "Two-Electron Quantum Dots in Magnetic Field." Acta Physica Polonica A 92, no. 4 (1997): 695–98. http://dx.doi.org/10.12693/aphyspola.92.695.

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20

Konemann, Jens, Franz-Josef Ahlers, Eckart Pesel, Klaus Pierz, and Hans Werner Schumacher. "Magnetic Field Reversible Serial Quantum Hall Arrays." IEEE Transactions on Instrumentation and Measurement 60, no. 7 (2011): 2512–16. http://dx.doi.org/10.1109/tim.2010.2099390.

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21

Kulakovskii, V. D., M. Bayer, M. Michel, A. Forchel, T. Gutbrod, and F. Faller. "Quantum dot multiexcitons in a magnetic field." Journal of Experimental and Theoretical Physics Letters 66, no. 4 (1997): 285–90. http://dx.doi.org/10.1134/1.567469.

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22

Li, Feng, Xin-Qi Li, Wei-Min Zhang, and S. A. Gurvitz. "Magnetic field switching in parallel quantum dots." EPL (Europhysics Letters) 88, no. 3 (2009): 37001. http://dx.doi.org/10.1209/0295-5075/88/37001.

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23

Massa, Corrado. "Galactic Magnetic Field and Cosmic Quantum Mechanics." Annalen der Physik 500, no. 5 (1988): 391–92. http://dx.doi.org/10.1002/andp.19885000512.

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24

Kashurnikov, V. A., N. V. Prokof’ev, B. V. Svistunov, and M. Troyer. "Quantum spin chains in a magnetic field." Physical Review B 59, no. 2 (1999): 1162–67. http://dx.doi.org/10.1103/physrevb.59.1162.

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25

Kossarev, Vladimir V., and Nikolaj A. Red'ko. "Anderson localization in quantum high magnetic field." Czechoslovak Journal of Physics 46, S5 (1996): 2435–36. http://dx.doi.org/10.1007/bf02570204.

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26

Dodonov, V. V., and O. V. Manko. "Quantum damped oscillator in a magnetic field." Physica A: Statistical Mechanics and its Applications 130, no. 1-2 (1985): 353–66. http://dx.doi.org/10.1016/0378-4371(85)90111-6.

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27

Wharam, D. A., T. Heinzel, S. Manus, et al. "High magnetic field investigations of quantum dots." Superlattices and Microstructures 15, no. 1 (1994): 37. http://dx.doi.org/10.1006/spmi.1994.1008.

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28

Zhou, Yun Qing, Jian Ming Yao, Ling Min Kong, and Rui Wang. "Pumping Currents from Applying a Microwave Field and a Magnetic Field to a Quantum Dot." Advanced Materials Research 181-182 (January 2011): 993–97. http://dx.doi.org/10.4028/www.scientific.net/amr.181-182.993.

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The evolution operator approach is applied to studying photon-electron pumping effects on a quantum dot connected to two magnetic leads in the presence of both via-dot and over-dot tunneling channels. It is found that a microwave field applied to the quantum dot may give rise to charge and spin pumping at zero bias voltage for asymmetric magnetic junctions.
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29

SMIRNOV, D., O. DRACHENKO, J. LEOTIN, et al. "INTERSUBBAND MAGNETOPHONON RESONANCES IN QUANTUM CASCADE STRUCTURES." International Journal of Modern Physics B 16, no. 20n22 (2002): 2952–55. http://dx.doi.org/10.1142/s0217979202013274.

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We report on magnetotransport measurements of GaAs/GaAlAs quantum cascade structures in magnetic fields up to 62 T parallel to the current. We observe novel quantum oscillations series in tunneling current that are periodic in reciprocal magnetic field and have field positions independent of the applied bias. These oscillations are explained as intersubband magnetophonon resonance due to electron relaxation by emission of optical or acoustic phonons.
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30

Nikuni, Tetsuro, and Hiroyuki Shiba. "Quantum Fluctuations and Magnetic Structures of CsCuCl3in High Magnetic Field." Journal of the Physical Society of Japan 62, no. 9 (1993): 3268–76. http://dx.doi.org/10.1143/jpsj.62.3268.

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31

Stirner, T., S. Ahmed, and W. E. Hagston. "Anisotropic magnetic field effects in diluted magnetic semiconductor quantum wells." Journal of Crystal Growth 159, no. 1-4 (1996): 1027–31. http://dx.doi.org/10.1016/0022-0248(95)00658-3.

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32

Piorek, T., P. Harrison, T. Stirner, and W. E. Hagston. "Magnetic field induced transitions in diluted magnetic semiconductor quantum wells." Journal of Crystal Growth 159, no. 1-4 (1996): 1037–40. http://dx.doi.org/10.1016/0022-0248(95)00693-1.

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33

CHOI, TAESEUNG, JUNGJAI LEE, and CHANG-MO RYU. "MULTI-ANYONS IN THE MAGNETIC FIELD." Modern Physics Letters B 13, no. 26 (1999): 925–32. http://dx.doi.org/10.1142/s0217984999001135.

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We consider the external magnetic field effects on the two types of anyons with fractional statistical parameter p/q with coprimes p and q, one with a fractional charge e/q and the other with a fractional flux p ϕ0/q by exact ground state wave function. We also study the geometry in which a two-dimensional strip of anyons contains an island of anyons with different statistical parameters in their equilibrium. The equilibrium inside an island is shown to be periodic with respect to the magnetic flux through the island. The period for the fractional charge anyon equals to the integer multiple of
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34

Hu, Zheng, Yu-Chen Wang, and Xi-Wen Hou. "Thermal quantum correlations in a two-qubit Heisenberg XYZ model with different magnetic fields." International Journal of Quantum Information 13, no. 06 (2015): 1550046. http://dx.doi.org/10.1142/s021974991550046x.

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Two kinds of thermal quantum correlations, measured respectively by quantum discord (QD) and the generalized negativity (GN), are studied for various magnetic fields, couplings, and temperatures in a two-qubit Heisenberg XYZ model. It is shown that QD and GN can exhibit a similar behavior in some regions of magnetic field, coupling, and temperature, while they behave in a contrary manner in other regions. For example, QD may increase with suitable magnetic fields, couplings, and temperature when GN decreases. QD is more robust against temperature than GN, and can reveal a kink at a suitable co
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35

Yuan, Ya-Li, and Xi-Wen Hou. "Thermal geometric discords in a two-qutrit system." International Journal of Quantum Information 14, no. 03 (2016): 1650016. http://dx.doi.org/10.1142/s0219749916500167.

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The investigation of quantum discord has mostly focused on two-qubit systems due to the complicated minimization involved in quantum discord for high-dimensional states. In this work, three geometric discords are studied for the thermal state in a two-qutrit system with various couplings, external magnetic fields, and temperatures as well, where the entanglement measured in terms of the generalized negativity is calculated for reference. It is shown that three geometric discords are more robust against temperature and magnetic field than the entanglement negativity. However, all four quantitie
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36

MATERDEY, TOMAS B., and CHARLES E. SEYLER. "THE QUANTUM WIGNER FUNCTION IN A MAGNETIC FIELD." International Journal of Modern Physics B 17, no. 25 (2003): 4555–92. http://dx.doi.org/10.1142/s0217979203022957.

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The Wigner function is shown related to the quantum dielectric function derived from the quantum Vlasov equation (QVE), with and without a magnetic field, using a standard method in plasma physics with linear perturbations and a self-consistent mean field interaction via Poisson's equation. A finite-limit-of-integration Wigner function, with oscillatory behavior and negative values for free particles, is proposed. In the classical regimes, where the problem size is huge compared to the particle wavelength, these limits go to infinity, and for free particles, the Wigner function becomes a posit
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37

ANDREEV, AL A., YA M. BLANTER, and YU E. LOZOVIK. "EXCITATION SPECTRUM OF QUANTUM DOT IN STRONG MAGNETIC FIELD." International Journal of Modern Physics B 09, no. 15 (1995): 1843–67. http://dx.doi.org/10.1142/s0217979295000756.

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Microscopic theory of collective excitations of a quantum dot in a strong magnetic field is proposed. A complete analysis of diagrams in the perturbation theory over the Coulomb interaction is performed. The spectrum of low-lying excitations is calculated for the case of a parabolic quantum dot. It is shown to consist of three terms: single-particle drift, magnetoplasma and exciton ones, with the exciton term dominating the magnetoplasma one. In the framework of the semi-classical approach, the case of a non-parabolic quantum dot is also discussed. The experimental manifestations of the effect
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38

GULEVICH, D. R., and F. V. KUSMARTSEV. "MAGNETIC RELAXATION OF SUPERCONDUCTING QUANTUM DOT AND TUNNELING OF ELECTRON IN A MAGNETIC FIELD." International Journal of Modern Physics B 23, no. 20n21 (2009): 4422–47. http://dx.doi.org/10.1142/s0217979209063572.

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Quantum tunneling of vortices had been found to be an important novel phenomena for description of low temperature creep in high temperature superconductors (HTSCs). We speculate that quantum tunneling may be also exhibited in mesoscopic superconductors due to vortices trapped by the Bean-Livingston barrier. The London approximation and method of images is used to estimate the shape of the potential well in superconducting HTSC quantum dot. To calculate the escape rate we use the instanton technique. We model the vortex by a quantum particle tunneling from a two-dimensional ground state under
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39

Nazmitdinov, R. G., and A. V. Chizhov. "Quantum entanglement in a two-electron quantum dot in magnetic field." Optics and Spectroscopy 112, no. 3 (2012): 319–22. http://dx.doi.org/10.1134/s0030400x12030149.

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40

Geiler, V. A., and I. Yu Popov. "A quantum loop in magnetic field and a quantum interference rectifier." Technical Physics Letters 27, no. 6 (2001): 444–46. http://dx.doi.org/10.1134/1.1383819.

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41

Shirvani, H., and S. Jafari. "Quantum regime of a plasma-wave-pumped free-electron laser in the presence of an axial magnetic field." Journal of Synchrotron Radiation 25, no. 2 (2018): 316–22. http://dx.doi.org/10.1107/s1600577517018124.

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The quantum regime of a plasma-whistler-wave-pumped free-electron laser (FEL) in the presence of an axial-guide magnetic field is presented. By quantizing both the plasma whistler field and axial magnetic field, anN-particle three-dimensional Hamiltonian of quantum-FEL (QFEL) has been derived. Employing Heisenberg evolution equations and introducing a new collective operator which controls the vertical motion of electrons, a quantum dispersion relation of the plasma whistler wiggler has been obtained analytically. Numerical results indicate that, by increasing the intrinsic quantum momentum sp
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42

Shigeta, Yasuteru. "Quantal cumulant dynamics III: A quantum confinement under a magnetic field." Chemical Physics Letters 461, no. 4-6 (2008): 310–15. http://dx.doi.org/10.1016/j.cplett.2008.06.075.

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43

Elizalde, E., F. C. Santos, and A. C. Tort. "Confined quantum fields under the influence of a uniform magnetic field." Journal of Physics A: Mathematical and General 35, no. 34 (2002): 7403–14. http://dx.doi.org/10.1088/0305-4470/35/34/311.

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44

Miransky, Vladimir A., and Igor A. Shovkovy. "Quantum field theory in a magnetic field: From quantum chromodynamics to graphene and Dirac semimetals." Physics Reports 576 (April 2015): 1–209. http://dx.doi.org/10.1016/j.physrep.2015.02.003.

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45

DUARTE, C. A., G. M. GUSEV, T. E. LAMAS, A. K. BAKAROV, and J. C. PORTAL. "VALLEY SPLITTING AND g-FACTOR IN AlAs QUANTUM WELLS." International Journal of Modern Physics B 23, no. 12n13 (2009): 2948–54. http://dx.doi.org/10.1142/s0217979209062608.

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Here we present the results of magneto resistance measurements in tilted magnetic field and compare them with calculations. The comparison between calculated and measured spectra for the case of perpendicular fields enable us to estimate the dependence of the valley splitting as a function of the magnetic field and the total Landé g -factor (which is assumed to be independent of the magnetic field). Since both the exchange contribution to the Zeeman splitting as well as the valley splitting are properties associated with the 2D quantum confinement, they depend only on the perpendicular compone
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46

YA. GERLOVIN, I., I. V. IGNATIEV, S. YU. VERBIN, B. PAL, and Y. MASUMOTO. "SPIN RELAXATION IN MAGNETIC FIELD FOR InP QUANTUM DOTS." International Journal of Nanoscience 06, no. 03n04 (2007): 257–60. http://dx.doi.org/10.1142/s0219581x07004663.

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47

Maleyev, S. V., and V. P. Plakhty. "Quantum criticality of antiferromagnets in inclined magnetic field." Journal of Magnetism and Magnetic Materials 272-276 (May 2004): 330–31. http://dx.doi.org/10.1016/j.jmmm.2003.12.680.

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48

Bouchard, Louis-S., and Warren S. Warren. "Multiple-quantum vector field imaging by magnetic resonance." Journal of Magnetic Resonance 177, no. 1 (2005): 9–21. http://dx.doi.org/10.1016/j.jmr.2005.06.019.

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49

Kohgi, M., K. Iwasa, J. M. Mignot, A. Hiess, A. Ochiai, and H. Aoki. "Quantum spin excitations in Yb4As3 under magnetic field." Physica B: Condensed Matter 359-361 (April 2005): 1436–38. http://dx.doi.org/10.1016/j.physb.2005.01.442.

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50

Ivanov, A. I., and O. R. Lobanova. "Magnetic field effects on circular cylinder quantum dots." Physica E: Low-dimensional Systems and Nanostructures 23, no. 1-2 (2004): 61–64. http://dx.doi.org/10.1016/j.physe.2004.01.010.

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