Your search keyword '"Dery H"' showing total 33 results

1. Experimental Demonstration of xor Operation in Graphene Magnetologic Gates at Room Temperature

Author

Wen, H, Dery, H, Amamou, W, Zhu, T, Lin, Z, Shi, J, Žutić, I, Krivorotov, I, Sham, LJ, and Kawakami, RK

Subjects

cond-mat.mes-hall, Physical Sciences, Engineering

Abstract

We report the experimental demonstration of a magnetologic gate built on graphene at room temperature. This magnetologic gate consists of three ferromagnetic electrodes contacting a single-layer graphene spin channel and relies on spin injection and spin transport in the graphene. We utilize electrical bias tuning of spin injection to balance the inputs and achieve "exclusive or" (xor) logic operation. Furthermore, a simulation of the device performance shows that substantial improvement towards spintronic applications can be achieved by optimizing the device parameters such as the device dimensions. This advance holds promise as a basic building block for spin-based information processing.

Published

2016

2. Spin extraction theory and its relevance to spintronics

Author

Dery, H and Sham, L J

Abstract

Extraction of electrons from a semiconductor to a ferromagnet as well as the case of injection in the reverse direction may be formulated as a scattering theory. However, the presence of bound states at the interface arising out of doping on the semiconductor side must be taken into account in the scattering theory. Inclusion of the interface states yields an explanation of a recent result of spin-imaging measurement which contradicts the current understanding of spin extraction. The importance of an extraction theory to spintronics is illustrated by an application to a spin switch.

Published

2007

3. Spintronics for electrical measurement of light polarization

Author

Dery, H, Cywinski, L, and Sham, L J

Abstract

The helicity of a circularly polarized light beam may be determined by the spin direction of photoexcited electrons in a III-V semiconductor. We present a theoretical demonstration on how the direction of the ensuing electron spin polarization may be determined by electrical means of two ferromagnet/semiconductor Schottky barriers. The proposed scheme allows for the time-resolved detection of spin accumulation in small structures and may have a device application. (c) 2006 American Institute of Physics.

Published

2006

4. Electric readout of magnetization dynamics in a ferromagnet-semiconductor system

Author

Cywinski, L, Dery, H, and Sham, L J

Abstract

We apply an analysis of time-dependent spin-polarized current in a semiconductor channel at room temperature to establish how the magnetization configuration and dynamics of three ferromagnetic terminals, two of them biased and third connected to a capacitor, affect the currents and voltages. In a steady state, the voltage on the capacitor is related to spin accumulation in the channel. When the magnetization of one of the terminals is rotated, a transient current is triggered. This effect can be used for electrical detection of magnetization reversal dynamics of an electrode or for dynamical readout of the alignment of two magnetic contacts.

Published

2006

5. Spin transference and magnetoresistance amplification in a transistor

Author

Dery, H, Cywinski, L, and Sham, L J

Abstract

A current problem in semiconductor spin-based electronics is the difficulty of experimentally expressing the effect of spin-polarized current in electrical circuit measurements. We present a theoretical solution with the principle of transference of the spin-diffusion effects in the semiconductor channel of a system with three magnetic terminals. A notable result of technological consequences is the room-temperature amplification of the magnetoresistive effect, integrable with electronics circuits, demonstrated by computation of current dependence on magnetization configuration in such a system with currently achievable parameters.

Published

2006

6. Lateral diffusive spin transport in layered structures

Author

Dery, H, Cywinski, L, and Sham, L J

Subjects

spintronics

Abstract

A one-dimensional (1D) theory of lateral spin-polarized transport is derived from the two-dimensional flow in the vertical cross section of a stack of ferromagnetic and paramagnetic layers. This takes into account the influence of the lead on the lateral current underneath, in contrast to the conventional 1D modeling by the collinear configuration of lead/channel/lead. Our theory is convenient and appropriate for the current in-plane configuration of an all-metallic spintronics structure as well as for the planar structure of a semiconductor with ferromagnetic contacts. For both systems we predict the optimal contact width for maximal magnetoresistance and propose an electrical measurement of the spin-diffusion length for a wide range of materials.

Published

2006

7. Spin-based logic in semiconductors for reconfigurable large-scale circuits

Author

Dery, H., Dalal, P., Cywiński, Ł., and Sham, L. J.

Subjects

Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Author(s): H. Dery (corresponding author) [1]; P. Dalal [1]; Ł. Cywiński [1]; L. J. Sham [1] Research in semiconductor spintronics aims to extend the scope of conventional electronics by using [...]

Published

2007

8. Temperature dependence of the coupling between n-type δ-doping region and quantum dot assemblies.

Author

Fekete, D., Dery, H., Rudra, A., and Kapon, E.

Subjects

*QUANTUM dots, *ELECTRON scattering, *HOT carriers, *QUANTUM electronics, *TEMPERATURE, *PHOTOLUMINESCENCE, *PHONONS

Abstract

We present experimental evidence that at room temperature the main coupling mechanism between an n-type δ-doping region and an adjacent plane of dots is energy-conserving electron-electron scattering, in which a hot electron in the δ-doping region transfers energy to a deeply confined electron in that region and relaxes to the quantum dot. We demonstrate that at room temperature the increased capture cross section due to electron-electron scattering considerably enhances the injection into the quantum dots with a certain size and thus reduces the phonon bottleneck in quantum dot assemblies for the quantum dots that interact with the δ-doping region. We identify different temperature-dependent injection schemes by comparing the photoluminescence of dilute and dense assemblies with the corresponding photoluminescence of similar structures including n-type δ-doping regions adjacent to the dots’ plane. [ABSTRACT FROM AUTHOR]

Published

2006

9. On the nature of quantum dash structures.

Author

Dery, H., Benisty, E., Epstein, A., Alizon, R., Mikhelashvili, V., Eisenstein, G., Schwertberger, R., Gold, D., Reithmaier, J. P., and Forchel, A.

Subjects

*NANOWIRES, *QUANTUM dots, *SEMICONDUCTOR lasers, *OPTOELECTRONIC devices, *ELECTRONIC amplifiers, *PHYSICS

Abstract

We describe a theoretical model for the linear optical gain properties of a quantum wire assembly and compare it to the well known case of a quantum dot assembly. We also present a technique to analyze the gain of an optical amplifier using bias dependent room temperature amplified spontaneous emission spectra. Employing this procedure in conjunction with the theoretical gain model, we demonstrate that InAs/InP quantum dash structures have quantum-wire-like characteristics. The procedure was used to extract the net gain coefficient, the differential gain, and the relative current component contributing to radiative recombination. © 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2004

10. Temperature dependence of the coupling between n-type delta-doping region and quantum dot assemblies

Author

Fekete, D., Dery, H., Rudra, A., and Kapon, E.

Subjects

Photoluminescence -- Analysis, Gallium arsenide -- Optical properties, Gallium arsenide -- Properties, Electrons -- Scattering, Electrons -- Research, Physics

Abstract

An experiment was conducted to study the temperature dependence of the coupling between n-type delta-doping regions. It was demonstrated that at room temperature the main coupling mechanism between an n-type delta-doping region and an adjacent plane of dots is energy-conserving electron-electron scattering, in which a hot electron in the delta-doping region transfers energy to a deeply confined electron in that region and relaxes to the quantum dot.

Published

2006

11. Semiconductor quantum dots devices: Recent advances and application prospects.

Author

Reithmaier, J. P., Somers, A., Kaiser, W., Deubert, S., Gerschütz, F., Forchel, A., Parillaud, O., Krakowski, M., Alizon, R., Hadass, D., Bilenca, A., Dery, H., Mikhelashvili, V., Eisenstein, G., Gioannini, M., Montrosset, I., Berg, T. W., van der Poel, M., Mørk, J., and Tromborg, B.

Published

2006

12. Gain and noise saturation of wide-band InAs-InP quantum dash optical amplifiers: model and experiments.

Author

Hadass, D., Bilenca, A., Alizon, R., Dery, H., Mikhelashvili, V., Eisenstein, G., Schwertberger, R., Somers, A., Reithmaier, J.P., Forchel, A., Calligaro, M., Bansropun, S., and Krakowski, M.

Abstract

We present a theoretical model for gain and noise saturation in quantum dash (QDash) semiconductor optical amplifiers. The model is based on the density matrix formalism and addresses static saturation spectra. The calculations are confirmed by a series of experiments which highlight the unique properties of these amplifiers. We demonstrate a high gain, a wide bandwidth, and high saturation power. The saturation spectrum is shown to be asymmetric, emphasizing saturation at short wavelength. The asymmetry stems from the high energy tail of the density of state function in those quantum wire (QWire) like gain media as well as from the interactions with the wetting layer. [ABSTRACT FROM PUBLISHER]

Published

2005

13. Measurement of Conduction and Valence Bands g-Factors in a Transition Metal Dichalcogenide Monolayer.

Author

Robert, C., Dery, H., Ren, L., Van Tuan, D., Courtade, E., Yang, M., Urbaszek, B., Lagarde, D., Watanabe, K., Taniguchi, T., Amand, T., and Marie, X.

Subjects

*VALENCE bands, *CONDUCTION bands, *TRANSITION metals, *MAGNETIC field measurements, *DEGREES of freedom, *MONOMOLECULAR films

Abstract

The electron valley and spin degree of freedom in monolayer transition-metal dichalcogenides can be manipulated in optical and transport measurements performed in magnetic fields. The key parameter for determining the Zeeman splitting, namely, the separate contribution of the electron and hole g factor, is inaccessible in most measurements. Here we present an original method that gives access to the respective contribution of the conduction and valence band to the measured Zeeman splitting. It exploits the optical selection rules of exciton complexes, in particular the ones involving intervalley phonons, avoiding strong renormalization effects that compromise single particle g-factor determination in transport experiments. These studies yield a direct determination of single band g factors. We measure gc1=0.86±0.1, gc2=3.84±0.1 for the bottom (top) conduction bands and gv=6.1±0.1 for the valence band of monolayer WSe2. These measurements are helpful for quantitative interpretation of optical and transport measurements performed in magnetic fields. In addition, the measured g factors are valuable input parameters for optimizing band structure calculations of these 2D materials. ! [ABSTRACT FROM AUTHOR]

Published

2021

14. Spectrally resolved dynamics of inhomogeneously broadened gain in InAs/InP 1550 nm quantum-dash lasers.

Author

Hadass, D., Alizon, R., Dery, H., Mikhelashvili, V., Eisenstein, G., Schwertberger, R., Somers, A., Reithmaier, J. P., Forchel, A., Calligaro, M., Bansropun, S., and Krakowski, M.

Subjects

INDIUM, ARSENIC, LASERS, OPTOELECTRONIC devices, LIGHT amplifiers, LIGHT sources

Abstract

We report spectrally resolved dynamical properties of 1550 nm quantum-dash lasers. The dynamics are governed by the inhomogeneous broadening of the gain medium and by wavelength-dependent carrier capture and escape rates. [ABSTRACT FROM AUTHOR]

Published

2004

15. Cross-gain modulation in inhomogeneously broadened gain spectra of InP-Based 1550 nm quantum dash optical amplifiers: Small-signal bandwidth dependence on wavelength detuning.

Author

Alizon, R., Bilenca, A., Dery, H., Mikhelashvili, V., Eisenstein, G., Schwertberger, R., Gold, D., Reithmaier, J. P., and Forchel, A.

Subjects

OPTICAL amplifiers, LASERS, ELECTRONIC modulation, BANDWIDTHS

Abstract

Dynamical properties of cross-gain modulation (XGM) within the inhomogeneously broadened gain spectrum of an InP quantum dash optical amplifier operating at 1550 nm are examined. The small-signal XGM modulation bandwidth increases with the carrier escape time, which is achieved at long probe wavelengths. The nature of the XGM dynamics is confirmed by spectrally resolved optical modulation response measurements in quantum dash lasers. [ABSTRACT FROM AUTHOR]

Published

2003

16. Optical Spin Injection and Spin Lifetime in Ge Heterostructures.

Author

Pezzoli, F., Bottegoni, F., Trivedi, D., Ciccacci, F., Giorgioni, A., Li, P., Cecchi, S., Grilli, E., Song, Y., Guzzi, M., Dery, H., and Isella, G.

Subjects

*ROTATIONAL motion, *GERMANIUM, *HETEROSTRUCTURES, *QUANTUM wells, *CHARGE exchange, *BRILLOUIN zones, *DYNAMICS

Abstract

We demonstrate optical orientation in Ge/SiGe quantum wells and study their spin properties. The ultrafast electron transfer from the center of the Brillouin zone to its edge allows us to achieve high spin polarizations and to resolve the spin dynamics of holes and electrons. The circular polarization degree of the direct gap photoluminescence exceeds the theoretical bulk limit, yielding ∼37% and ∼85% for transitions with heavy and light holes states, respectively. The spin lifetime of holes at the top of the valence band is estimated to be ∼0.5 ps and it is governed by transitions between light and heavy hole states. Electrons at the bottom of the conduction band, on the other hand, have a spin lifetime that exceeds 5 ns below 150 K. Theoretical analysis of the spin relaxation indicates that phonon-induced intervalley scattering dictates the spin lifetime of electrons. [ABSTRACT FROM AUTHOR]

Published

2012

17. Playing with your ears: Audio-motor skill learning is sensitive to the lateral relationship between trained hand and ear.

Author

Dery H, Buaron B, Mazinter R, Lavi S, and Mukamel R

Abstract

A salient feature of motor and sensory circuits in the brain is their contralateral hemispheric bias-a feature that might play a role in integration and learning of sensorimotor skills. In the current behavioral study, we examined whether the lateral configuration between sound-producing hand and feedback-receiving ear affects performance and learning of an audio-motor skill. Right-handed participants (n = 117) trained to play a piano sequence using their right or left hand while auditory feedback was presented monaurally, either to the right or left ear. Participants receiving auditory feedback to the contralateral ear during training performed better than participants receiving ipsilateral feedback (with respect to the training hand). Furthermore, in the Left-Hand training groups, the contralateral training advantage persisted in a generalization task. Our results demonstrate that audio-motor learning is sensitive to the lateral configuration between motor and sensory circuits and suggest that integration of neural activity across hemispheres facilitates such learning., Competing Interests: The authors declare no competing interests., (© 2023 The Author(s).)

Published

2023

18. Six-Body and Eight-Body Exciton States in Monolayer WSe_{2}.

Author

Van Tuan D, Shi SF, Xu X, Crooker SA, and Dery H

Abstract

In the archetypal monolayer semiconductor WSe_{2}, the distinct ordering of spin-polarized valleys (low-energy pockets) in the conduction band allows for studies of not only simple neutral excitons and charged excitons (i.e., trions), but also more complex many-body states that are predicted at higher electron densities. We discuss magneto-optical measurements of electron-rich WSe_{2} monolayers and interpret the spectral lines that emerge at high electron doping as optical transitions of six-body exciton states ("hexcitons") and eight-body exciton states ("oxcitons"). These many-body states emerge when a photoexcited electron-hole pair interacts simultaneously with multiple Fermi seas, each having distinguishable spin and valley quantum numbers. In addition, we explain the relations between dark trions and satellite optical transitions of hexcitons in the photoluminescence spectrum.

Published

2022

19. Spin/valley pumping of resident electrons in WSe 2 and WS 2 monolayers.

Author

Robert C, Park S, Cadiz F, Lombez L, Ren L, Tornatzky H, Rowe A, Paget D, Sirotti F, Yang M, Van Tuan D, Taniguchi T, Urbaszek B, Watanabe K, Amand T, Dery H, and Marie X

Abstract

Monolayers of transition metal dichalcogenides are ideal materials to control both spin and valley degrees of freedom either electrically or optically. Nevertheless, optical excitation mostly generates excitons species with inherently short lifetime and spin/valley relaxation time. Here we demonstrate a very efficient spin/valley optical pumping of resident electrons in n-doped WSe 2 and WS 2 monolayers. We observe that, using a continuous wave laser and appropriate doping and excitation densities, negative trion doublet lines exhibit circular polarization of opposite sign and the photoluminescence intensity of the triplet trion is more than four times larger with circular excitation than with linear excitation. We interpret our results as a consequence of a large dynamic polarization of resident electrons using circular light., (© 2021. The Author(s).)

Published

2021

20. Intrinsic donor-bound excitons in ultraclean monolayer semiconductors.

Author

Rivera P, He M, Kim B, Liu S, Rubio-Verdú C, Moon H, Mennel L, Rhodes DA, Yu H, Taniguchi T, Watanabe K, Yan J, Mandrus DG, Dery H, Pasupathy A, Englund D, Hone J, Yao W, and Xu X

Abstract

The monolayer transition metal dichalcogenides are an emergent semiconductor platform exhibiting rich excitonic physics with coupled spin-valley degree of freedom and optical addressability. Here, we report a new series of low energy excitonic emission lines in the photoluminescence spectrum of ultraclean monolayer WSe 2 . These excitonic satellites are composed of three major peaks with energy separations matching known phonons, and appear only with electron doping. They possess homogenous spatial and spectral distribution, strong power saturation, and anomalously long population (>6 µs) and polarization lifetimes (>100 ns). Resonant excitation of the free inter- and intravalley bright trions leads to opposite optical orientation of the satellites, while excitation of the free dark trion resonance suppresses the satellites' photoluminescence. Defect-controlled crystal synthesis and scanning tunneling microscopy measurements provide corroboration that these features are dark excitons bound to dilute donors, along with associated phonon replicas. Our work opens opportunities to engineer homogenous single emitters and explore collective quantum optical phenomena using intrinsic donor-bound excitons in ultraclean 2D semiconductors.

Published

2021

21. Valley phonons and exciton complexes in a monolayer semiconductor.

Author

He M, Rivera P, Van Tuan D, Wilson NP, Yang M, Taniguchi T, Watanabe K, Yan J, Mandrus DG, Yu H, Dery H, Yao W, and Xu X

Abstract

The coupling between spin, charge, and lattice degrees of freedom plays an important role in a wide range of fundamental phenomena. Monolayer semiconducting transitional metal dichalcogenides have emerged as an outstanding platform for studying these coupling effects. Here, we report the observation of multiple valley phonons - phonons with momentum vectors pointing to the corners of the hexagonal Brillouin zone - and the resulting exciton complexes in the monolayer semiconductor WSe 2 . We find that these valley phonons lead to efficient intervalley scattering of quasi particles in both exciton formation and relaxation. This leads to a series of photoluminescence peaks as valley phonon replicas of dark trions. Using identified valley phonons, we also uncover an intervalley exciton near charge neutrality. Our work not only identifies a number of previously unknown 2D excitonic species, but also shows that monolayer WSe 2 is a prime candidate for studying interactions between spin, pseudospin, and zone-edge phonons.

Published

2020

22. Virtual Trions in the Photoluminescence of Monolayer Transition-Metal Dichalcogenides.

Author

Van Tuan D, Jones AM, Yang M, Xu X, and Dery H

Abstract

Photoluminescence experiments from monolayer transition-metal dichalcogenides often show that the binding energy of trions is conspicuously similar to the energy of optical phonons. This enigmatic coincidence calls into question whether phonons are involved in the radiative recombination process. We address this problem, unraveling an intriguing optical transition mechanism. Its initial state is a localized charge (electron or hole) and delocalized exciton. The final state is the localized charge, phonon, and photon. In between, the intermediate state of the system is a virtual trion formed when the localized charge captures the exciton through emission of the phonon. We analyze the difference between radiative recombinations that involve real and virtual trions (i.e., with and without a phonon), providing useful ways to distinguish between the two in experiment.

Published

2019

23. Dynamical screening in monolayer transition-metal dichalcogenides and its manifestations in the exciton spectrum.

Author

Scharf B, Van Tuan D, Žutić I, and Dery H

Abstract

Monolayer transition-metal dichalcogenides (ML-TMDs) offer exciting opportunities to test the manifestations of many-body interactions through changes in the charge density. The two-dimensional character and reduced screening in ML-TMDs lead to the formation of neutral and charged excitons with binding energies orders of magnitude larger than those in conventional bulk semiconductors. Tuning the charge density by a gate voltage leads to profound changes in the optical spectra of excitons in ML-TMDs. On the one hand, the increased screening at large charge densities should result in a blueshift of the exciton spectral lines due to reduction in the binding energy. On the other hand, exchange and correlation effects that shrink the band-gap energy at elevated charge densities (band-gap renormalization) should result in a redshift of the exciton spectral lines. While these competing effects can be captured through various approximations that model long-wavelength charge excitations in the Bethe-Salpeter equation, we show that a novel coupling between excitons and shortwave charge excitations is essential to resolve several experimental puzzles. Unlike ubiquitous and well-studied plasmons, driven by collective oscillations of the background charge density in the long-wavelength limit, we discuss the emergence of shortwave plasmons that originate from the short-range Coulomb interaction through which electrons transition between the [Formula: see text] and [Formula: see text] valleys. The shortwave plasmons have a finite energy-gap because of the removal of spin-degeneracy in both the valence- and conduction-band valleys (a consequence of breaking of inversion symmetry in combination with strong spin-orbit coupling in ML-TMDs). We study the coupling between the shortwave plasmons and the neutral exciton through the self-energy of the latter. We then elucidate how this coupling as well as the spin ordering in the conduction band give rise to an experimentally observed optical sideband in electron-doped W-based MLs, conspicuously absent in electron-doped Mo-based MLs or any hole-doped ML-TMDs. While the focus of this review is on the optical manifestations of many-body effects in ML-TMDs, a systematic description of the dynamical screening and its various approximations allow one to revisit other phenomena, such as nonequilibrium transport or superconducting pairing, where the use of the Bethe-Salpeter equation or the emergence of shortwave plasmons can play an important role.

Published

2019

24. A two-dimensional spin field-effect switch.

Author

Yan W, Txoperena O, Llopis R, Dery H, Hueso LE, and Casanova F

Abstract

Future development in spintronic devices will require an advanced control of spin currents, for example by an electric field. Here we demonstrate an approach that differs from previous proposals such as the Datta and Das modulator, and that is based on a van de Waals heterostructure of atomically thin graphene and semiconducting MoS 2 . Our device combines the superior spin transport properties of graphene with the strong spin-orbit coupling of MoS 2 and allows switching of the spin current in the graphene channel between ON and OFF states by tuning the spin absorption into the MoS 2 with a gate electrode. Our proposal holds potential for technologically relevant applications such as search engines or pattern recognition circuits, and opens possibilities towards electrical injection of spins into transition metal dichalcogenides and alike materials.

Published

2016

25. Donor-driven spin relaxation in multivalley semiconductors.

Author

Song Y, Chalaev O, and Dery H

Subjects

Models, Theoretical, Semiconductors, Silicon chemistry

Abstract

The observed dependence of spin relaxation on the identity of the donor atom in n-type silicon has remained without explanation for decades and poses a long-standing open question with important consequences for modern spintronics. Taking into account the multivalley nature of the conduction band in silicon and germanium, we show that the spin-flip amplitude is dominated by short-range scattering off the central-cell potential of impurities after which the electron is transferred to a valley on a different axis in k space. Through symmetry arguments, we show that this spin-flip process can strongly affect the spin relaxation in all multivalley materials in which time-reversal cannot connect distinct valleys. From the physical insights gained from the theory, we provide guidelines to significantly enhance the spin lifetime in semiconductor spintronics devices.

Published

2014

26. Impurity-assisted tunneling magnetoresistance under a weak magnetic field.

Author

Txoperena O, Song Y, Qing L, Gobbi M, Hueso LE, Dery H, and Casanova F

Abstract

Injection of spins into semiconductors is essential for the integration of the spin functionality into conventional electronics. Insulating layers are often inserted between ferromagnetic metals and semiconductors for obtaining an efficient spin injection, and it is therefore crucial to distinguish between signatures of electrical spin injection and impurity-driven effects in the tunnel barrier. Here we demonstrate an impurity-assisted tunneling magnetoresistance effect in nonmagnetic-insulator-nonmagnetic and ferromagnetic-insulator-nonmagnetic tunnel barriers. In both cases, the effect reflects on-off switching of the tunneling current through impurity channels by the external magnetic field. The reported effect is universal for any impurity-assisted tunneling process and provides an alternative interpretation to a widely used technique that employs the same ferromagnetic electrode to inject and detect spin accumulation.

Published

2014

27. Magnetic-field-modulated resonant tunneling in ferromagnetic-insulator-nonmagnetic junctions.

Author

Song Y and Dery H

Abstract

We present a theory for resonance-tunneling magnetoresistance (MR) in ferromagnetic-insulator-nonmagnetic junctions. The theory sheds light on many of the recent electrical spin injection experiments, suggesting that this MR effect rather than spin accumulation in the nonmagnetic channel corresponds to the electrically detected signal. We quantify the dependence of the tunnel current on the magnetic field by quantum rate equations derived from the Anderson impurity model, with the important addition of impurity spin interactions. Considering the on-site Coulomb correlation, the MR effect is caused by competition between the field, spin interactions, and coupling to the magnetic lead. By extending the theory, we present a basis for operation of novel nanometer-size memories.

Published

2014

28. Anisotropy-driven spin relaxation in germanium.

Author

Li P, Li J, Qing L, Dery H, and Appelbaum I

Abstract

A unique spin depolarization mechanism, induced by the presence of g-factor anisotropy and intervalley scattering, is revealed by spin-transport measurements on long-distance germanium devices in a magnetic field longitudinal to the initial spin orientation. The confluence of electron-phonon scattering (leading to Elliott-Yafet spin flips) and this previously unobserved physics enables the extraction of spin lifetime solely from spin-valve measurements, without spin precession, and in a regime of substantial electric-field-generated carrier heating. We find spin lifetimes in Ge up to several hundreds of nanoseconds at low temperature, far beyond any other available experimental results.

Published

2013

29. Transport theory of monolayer transition-metal dichalcogenides through symmetry.

Author

Song Y and Dery H

Abstract

We present a theory that elucidates the major momentum and spin relaxation processes for electrons, holes, and hot excitons in monolayer transition-metal dichalcogenides. We expand on spin flips induced by flexural phonons and show that the spin relaxation is ultrafast for electrons in free-standing membranes while being mitigated in supported membranes. This behavior due to interaction with flexural phonons is universal in two-dimensional membranes that respect mirror symmetry, and it leads to a counterintuitive inverse relation between mobility and spin relaxation.

Published

2013

30. Field-induced negative differential spin lifetime in silicon.

Author

Li J, Qing L, Dery H, and Appelbaum I

Abstract

We show that the electric-field-induced thermal asymmetry between the electron and lattice systems in pure silicon substantially impacts the identity of the dominant spin relaxation mechanism. Comparison of empirical results from long-distance spin transport devices with detailed Monte Carlo simulations confirms a strong spin depolarization beyond what is expected from the standard Elliott-Yafet theory even at low temperatures. The enhanced spin-flip mechanism is attributed to phonon emission processes during which electrons are scattered between conduction band valleys that reside on different crystal axes. This leads to anomalous behavior, where (beyond a critical field) reduction of the transit time between spin-injector and spin-detector is accompanied by a counterintuitive reduction in spin polarization and an apparent negative spin lifetime.

Published

2012

31. Proximity effects of a symmetry-breaking interface on spins of photoexcited electrons.

Author

Qing L, Song Y, and Dery H

Abstract

We study reflection of optically spin-oriented hot electrons as a means to probe the semiconductor crystal symmetry and its intimate relation with the spin-orbit coupling. The symmetry breaking by reflection manifests itself by tipping the net-spin vector of the photoexcited electrons out of the light propagation direction. The tipping angle and the pointing direction of the net-spin vector are set by the crystal-induced spin precession, momentum alignment, and spin-momentum correlation of the initial photoexcited electron population. We examine nonmagnetic semiconductor heterostructures and semiconductor-ferromagnet systems and show the unique signatures of these effects.

Published

2011

32. Spin-orbit symmetries of conduction electrons in silicon.

Author

Li P and Dery H

Abstract

We derive a spin-dependent Hamiltonian that captures the symmetry of the zone edge states in silicon. We present analytical expressions of the spin-dependent states and of spin relaxation due to electron-phonon interactions in the multivalley conduction band. We find excellent agreement with experimental results. Similar to the usage of the Kane Hamiltonian in direct band-gap semiconductors, the new Hamiltonian can be used to study spin properties of electrons in silicon.

Published

2011

33. Theory of spin-dependent phonon-assisted optical transitions in silicon.

Author

Li P and Dery H

Abstract

Silicon is an ideal material choice for spintronics devices due to its relatively long spin relaxation time and mature technology. To date, however, there are no parameter-free methods to accurately determine the degree of spin polarization of electrons in silicon. This missing link is established with a theory that provides concise relations between the degrees of spin polarization and measured circular polarization for each of the dominant phonon-assisted optical transitions. The phonon symmetries play a key role in elucidating recent spin injection experiments in silicon.

Published

2010