Your search keyword '"GREEN'S functions"' showing total 25,217 results

1. Interface defect state induced spin injection in organic magnetic tunnel junctions.

Author

Soujanya, Pamulapati and Deb, Debajit

Subjects

*SPIN transfer torque, *MAGNETIC tunnelling, *SPINTRONICS, *TUNNEL magnetoresistance, *GREEN'S functions

Abstract

This article analytically explores defect assisted spin injection in organic magnetic tunnel junctions (MTJs) [x/rubrene/Co, x = La 2 O 3 , LaMnO 3 , La 0.7 Ca 0.3 MnO 3 (LCMO), La 0.7 Sr 0.3 MnO 3 (LSMO)] employing nonequilibrium Green's function (NEGF). Spin precession at ferromagnet (FM)/organic semiconductor (OSC) interface defect states have been considered while modeling the MTJ devices. Variations in voltage dependent parallel (R P) and antiparallel (R A P ) resistances have been attributed to modified spin dependent scattering at modified spin resolved density of states of magnetic electrodes. Moreover, change in distribution of defect state depths at a spin injection interface has also been observed to modify R P /R A P , and hence, tunnel magnetoresistance (TMR) across the devices. Localization of defect state distribution due to a high spin split band may have resulted in large TMR for La 2 O 3 devices. Nonlinear spin transfer torque (STT) in devices other than LSMO indicates compensation of spin damping, resulting in a high TMR response across the devices. Hence, the localization of defect state distribution and the choice of magnetic electrodes with high spin split bands may be exercised to realize spintronic devices for low power spin memory applications. [ABSTRACT FROM AUTHOR]

Published

2024

2. Topological valley magnons and tunable thermal rectification in staggered Kagome ferromagnets.

Author

Xing, Yuheng, Qiu, Wenjuan, Zhang, Chunwei, Xu, Ning, and Zhang, Haiyang

Subjects

*EXCHANGE interactions (Magnetism), *GREEN'S functions, *HALL effect, *DEGREES of freedom, *HEAT transfer

Abstract

Owing to charge free property, magnon is highly promising to achieve dissipationless transport without Joule heating and, thus, potentially applicable to energy efficient devices. In this paper, using the non-equilibrium Green's function, we present the bulk-boundary correspondence for magnonic Kagome lattices by studying the edge magnons transport. With staggered exchange interaction and Dzyaloshinskii–Moriya interaction in the Kagome lattices, one can observe valley contrasting magnon Hall effect, which endows magnon transport with the valley degree of freedom and adds a new dimension to regulate magnon excitation. In particular, we demonstrate that the valley splitting in the Kagome lattice enables a tunable single edge chiral transport. Thermal rectification is a direction-dependent asymmetric heat transfer phenomenon; here, we report the tunable thermal rectification by asymmetric nonlinear effect, and it is, indeed, regulated by the Dzyaloshinskii–Moriya interaction direction (D → − D) and the exchange of J 1 and J 2 (J 1 ↔ J 2). Moreover, we show that the topological edge state mainly localizes around edges and leaks into the bulk with oscillatory decay. These give full play to spin and valley degrees of freedom and provide various avenues for information encoding and manipulation based on valley related magnonic flux. [ABSTRACT FROM AUTHOR]

Published

2024

3. Current-driven mechanical motion of double stranded DNA results in structural instabilities and chiral-induced-spin-selectivity of electron transport.

Author

Davis, Nicholas S., Lawn, Julian A., Preston, Riley J., and Kosov, Daniel S.

Subjects

*GREEN'S functions, *DEGREES of freedom, *ELECTRON transport, *SPIN polarization, *RANDOM variables

Abstract

Chiral-induced-spin-selectivity of electron transport and its interplay with DNA's mechanical motion are explored in a double stranded DNA helix with spin–orbit-coupling. The mechanical degree of freedom is treated as a stochastic classical variable experiencing fluctuations and dissipation induced by the environment as well as force exerted by nonequilibrium, current-carrying electrons. Electronic degrees of freedom are described quantum mechanically using nonequilibrium Green's functions. Nonequilibrium Green's functions are computed along the trajectory for the classical variable taking into account dynamical, velocity dependent corrections. This mixed quantum-classical approach enables calculations of time-dependent spin-resolved currents. We showed that the electronic force may significantly modify the classical potential, which, at sufficient voltage, creates a bistable potential with a considerable effect on electronic transport. The DNA's mechanical motion has a profound effect on spin transport; it results in chiral-induced spin selectivity, increasing spin polarization of the current by 9% and also resulting in temperature-dependent current voltage characteristics. We demonstrate that the current noise measurement provides an accessible experimental means to monitor the emergence of mechanical instability in DNA motion. The spin resolved current noise also provides important dynamical information about the interplay between vibrational and spin degrees of freedom in DNA. [ABSTRACT FROM AUTHOR]

Published

2024

4. Magnetic resonance of spin current and its accompanying heating or cooling.

Author

Tang, Yuxin, Zhang, Lin, Jiang, Feng, Yan, Yonghong, and Zhu, Yanyan

Subjects

*GREEN'S functions, *MAGNETIC resonance, *TRANSPORT theory, *MAGNETIC fields, *SPINTRONICS

Abstract

Motivated by the booming development of spintronics based on quantum dot systems, we employed the standard nonequilibrium Green's function theory to derive the transport formula and the heat generation formula of a quantum dot coupled to a substrate and study the relation between spin current and its accompanying heating or cooling. Our results demonstrate that (i) a thermal bias combined with Zeeman splitting can generate steady spin current in a limited dot level range, while a rotating magnetic field can generate time-average spin current in a global range and pure spin current can induce more heat generation than non-pure spin current; (ii) magnetic resonance of spin current can also effectively enhance heat generation; (iii) appropriate environmental temperature in conjunction with a thermal bias makes cooling, while increasing the frequency of the rotating magnetic can easily give rise to the transition from cooling to heating; and (iv) enhancing the coupling between quantum dots and substrates can effectively reduce heat generation while maintaining the fundamental properties of pure spin current. [ABSTRACT FROM AUTHOR]

Published

2024

5. An implicit solution for Asay foil trajectories generated by separable, sustained-production ejecta source models.

Author

Tregillis, I. L. and Koskelo, Aaron

Subjects

*GREEN'S functions, *NUMERICAL calculations, *GENERATING functions, *VELOCITY, *INTEGRALS

Abstract

We present a simple implicit solution for the time-dependent trajectory of a thin Asay foil ejecta diagnostic for the general case where the impinging ejecta cloud is generated by a source function characterized by an arbitrary (sustained) time dependence and a time-independent (stationary) particle velocity distribution. In the limit that the source function time dependence becomes a delta function, this solution—which is amenable to rapid numerical calculations of arbitrary accuracy—exactly recovers a previously published solution for the special case of instantaneous ejecta production. We also derive simple expressions for the free-surface arrival (catch-up) time as well as the true ejecta areal mass accumulation on the accelerating foil and place bounds on the level of error incurred when applying instant-production mass solutions to a sustained-production trajectory. We demonstrate these solutions with example calculations for hypothetical source functions spanning a wide range of ejecta production durations, velocity distributions, and temporal behaviors. These calculations demonstrate how the foil trajectory is often insensitive to the temporal dependence of the source function, instead being dominated by the velocity distribution. We quantify this insensitivity using a "compatibility score" metric. Under certain conditions, one may capitalize upon this insensitivity to obtain a good approximation of the second integral of the velocity distribution from the observed foil trajectory. [ABSTRACT FROM AUTHOR]

Published

2024

6. Theoretical prediction of chalcogen-based Janus monolayers for self-powered optoelectronic devices.

Author

Sun, Yuxuan, Sun, Naizhang, Zhou, Wenlin, and Ye, Han

Subjects

*PHOTOCONDUCTIVITY, *GREEN'S functions, *DENSITY functional theory, *BREWSTER'S angle, *OPTOELECTRONIC devices

Abstract

Exploring potential two-dimensional monolayers with large photogalvanic effect (PGE) has been of great importance for developing self-powered optoelectronic devices. In this paper, we systematically investigate the generation of PGE photocurrent in chalcogen-based Janus XYZ monolayers (X/Y/Z = S, Se, Te; X ≠ Y ≠ Z) based on non-equilibrium Green's function formalism with density functional theory. The optimized Janus SSeTe, SeSTe, and TeSeS monolayers in the rectangular phase are shown stable and, respectively, possess 1.54, 1.49, and 1.74 eV indirect bandgaps. Illuminated by linearly polarized light, the PGE photocurrent without bias voltage can be collected in both armchair and zigzag directions. Unlike common Janus 2D materials with C3v symmetry, the photocurrent peak values of Janus XYZ monolayers do not come up with certain polarization angles, while the relations can be fitted by Iph = α sin(2θ) + β cos(2θ) + γ at each photon energy. Meanwhile, the maximum photoresponses of Janus SSeTe, SeSTe, and TeSeS monolayers are 2.02, 3.33, and 4.42 a20/photon, respectively. The relatively large PGE photocurrents and complicated polarization relations result from the lower symmetry of Janus XYZ monolayers. Moreover, the specific polarization angles for maximum photoresponses at each photon energy and the ratio between two transport directions are demonstrated, reflecting the anisotropy. Our results theoretically predict a potential Janus monolayer family for self-powered optoelectronic applications. [ABSTRACT FROM AUTHOR]

Published

2024

7. Giant tunneling resistance and robust switching behavior in ferroelectric tunnel junctions of WS2/Ga2O3 heterostructures: The influence of metal–semiconductor contacts.

Author

Wei, Dong, Guo, Gaofu, Yu, Heng, Li, Yi, Ma, Yaqiang, Tang, Yanan, Feng, Zhen, and Dai, Xianqi

Subjects

*GREEN'S functions, *FERROELECTRIC materials, *ELECTRON tunneling, *POTENTIAL barrier, *DENSITY functional theory, *TUNNEL junctions (Materials science)

Abstract

The ferroelectric tunneling junctions (FTJs) are widely recognized as one of the non-volatile memories with significant potential. Ferroelectricity usually fades away as materials are thinned down below a critical value, and this problem is particularly acute in the case of shrinking device sizes, thus attracting attention to two-dimensional ferroelectric materials (2DFEMs). In this work, we designed 2D ferroelectric Ga2O3-based FTJs with out-of-plane polarization, and the influence of metal–semiconductor contact in the electrode region on the system is considered. Here, using density functional theory combined with the non-equilibrium Green's function approach to quantum transport calculations, we demonstrate robust ferroelectric polarization-controlled switching behavior between metallic and semiconducting states in Ga2O3/WS2 ferroelectric heterostructures. The potential barrier of the metal–semiconductor contact in the electrode region is lower than that of the intrinsic material, thereby resulting in an increased probability of electron tunneling. Our results reveal the crucial role of 2DFEMs in the construction of FTJs and highlight the significant impact of electrode contact types on performance. This provides a promising approach for developing high-density ferroelectric memories based on 2D ferroelectric semiconductor heterostructures. [ABSTRACT FROM AUTHOR]

Published

2024

8. A meshless stochastic method for Poisson–Nernst–Planck equations.

Author

Monteiro, Henrique B. N. and Tartakovsky, Daniel M.

Subjects

*NUMERICAL solutions to partial differential equations, *FAST multipole method, *GREEN'S functions, *PROBABILITY density function, *PARTIAL differential equations, *FOKKER-Planck equation

Abstract

A plethora of biological, physical, and chemical phenomena involve transport of charged particles (ions). Its continuum-scale description relies on the Poisson–Nernst–Planck (PNP) system, which encapsulates the conservation of mass and charge. The numerical solution of these coupled partial differential equations is challenging and suffers from both the curse of dimensionality and difficulty in efficiently parallelizing. We present a novel particle-based framework to solve the full PNP system by simulating a drift–diffusion process with time- and space-varying drift. We leverage Green's functions, kernel-independent fast multipole methods, and kernel density estimation to solve the PNP system in a meshless manner, capable of handling discontinuous initial states. The method is embarrassingly parallel, and the computational cost scales linearly with the number of particles and dimension. We use a series of numerical experiments to demonstrate both the method's convergence with respect to the number of particles and computational cost vis-à-vis a traditional partial differential equation solver. [ABSTRACT FROM AUTHOR]

Published

2024

9. Purcell effect for high-Q plasmon lattice modes in the coupled dipole approximation.

Author

Vurgaftman, I. and Tsoi, S.

Subjects

*GREEN'S functions, *NANOPARTICLES, *RESONANCE, *PLASMONICS, *ANGLES

Abstract

We present a semi-analytical treatment of the spontaneous emission enhancement for collective lattice resonances of a linear 1D array of metallic nanoparticles in order to improve the physical understanding of these resonances, previously explored numerically. The treatment is based on the coupled-dipole approximation and Green's function formalism. We calculate the Purcell factor of the surface lattice resonance for localized emitters as a function of emitter position and compare it to the resonant enhancement for a localized plasmonic resonance of an isolated single nanoparticle. We find that the Purcell factor for a single emitter (or an incoherent ensemble of emitters) near the nanoparticle is typically smaller for the surface lattice resonance, although it can be higher for emitters nearly halfway between the particles. Nevertheless, in agreement with previous models, the lattice resonances display stronger emission in certain regions as well as a much narrower range of emission angles, which can lead to improved collection efficiency. Finally, we show that the "slow-propagating" modes of square 2D lattices of nanoparticles are capable of significantly stronger Purcell-enhanced emission. [ABSTRACT FROM AUTHOR]

Published

2024

10. Efficient, nonparametric removal of noise and recovery of probability distributions from time series using nonlinear-correlation functions: Photon and photon-counting noise.

Author

Dhar, Mainak and Berg, Mark A.

Subjects

*TIME series analysis, *DISTRIBUTION (Probability theory), *PHOTON counting, *GREEN'S functions, *PHOTONS, *NOISE

Abstract

A preceding paper [M. Dhar, J. A. Dickinson, and M. A. Berg, J. Chem. Phys. 159, 054110 (2023)] shows how to remove additive noise from an experimental time series, allowing both the equilibrium distribution of the system and its Green's function to be recovered. The approach is based on nonlinear-correlation functions and is fully nonparametric: no initial model of the system or of the noise is needed. However, single-molecule spectroscopy often produces time series with either photon or photon-counting noise. Unlike additive noise, photon noise is signal-size correlated and quantized. Photon counting adds the potential for bias. This paper extends noise-corrected-correlation methods to these cases and tests them on synthetic datasets. Neither signal-size correlation nor quantization is a significant complication. Analysis of the sampling error yields guidelines for the data quality needed to recover the properties of a system with a given complexity. We show that bias in photon-counting data can be corrected, even at the high count rates needed to optimize the time resolution. Using all these results, we discuss the factors that limit the time resolution of single-molecule spectroscopy and the conditions that would be needed to push measurements into the submicrosecond region. [ABSTRACT FROM AUTHOR]

Published

2024

11. Strain engineering of electronic structure and thermoelectric properties of quasi-hexagonal fullerene monolayer.

Author

Wang, Ruipeng, Li, Haipeng, Shakoori, Muhammad Asif, Cheng, Xuechao, Hu, Yuxiao, and Wang, Leyang

Subjects

*THERMOELECTRIC materials, *ELECTRONIC structure, *MONOMOLECULAR films, *CARBON-based materials, *FULLERENES, *GREEN'S functions, *STRUCTURAL engineering

Abstract

As a newly synthesized two-dimensional (2D) carbon material, monolayer quasi-hexagonal phase fullerene (qHP C60) has an excellent electronic structure and low thermal conductivity. qHP C60 attracted significant attention from scientists because it has potential applications in thermoelectric materials. Thermoelectric properties of 2D materials significantly depend on the transport of carriers (such as electrons and phonons), and strain engineering is an essential method for modulating the transport of electrons and phonons in 2D materials. However, the strain engineering method for the modulation of the thermoelectric properties of monolayer qHP C60 has not been reported yet. In the present paper, the first-principles combined with the non-equilibrium Green's function method are used to investigate the ballistic transport properties of electrons and phonons in monolayer qHP C60. The effects of temperature, chemical potential, and biaxial tensile strain on the thermoelectric transport parameters (including conductivity, Seebeck coefficient, power factor, and thermal conductivity) as well as the figure of merit (ZT) of monolayer qHP C60 are presented, compared, discussed, and analyzed. We found that monolayer qHP C60 exhibits anisotropic characteristics in electron and phonon transport properties, showcasing outstanding thermoelectric properties. The distinctive quasi-hexagonal phase fullerene network structure offers a novel platform for exploring innovative 2D thermoelectric materials in research. This study provides crucial theoretical insights to guide the designing and implementation of 2D thermoelectric materials based on fullerenes. [ABSTRACT FROM AUTHOR]

Published

2024

12. Thermoelectric response in zigzag chains: Impact of irradiation-induced conformational changes.

Author

Ganguly, Sudin, Mondal, Kallol, and Maiti, Santanu K.

Subjects

*GREEN'S functions, *COUPLING schemes, *THERMOELECTRIC materials, *IRRADIATION, *FERMI energy, *ENERGY conversion

Abstract

This study explores the enhancement of thermoelectric response in a zigzag chain through irradiation with arbitrarily polarized light. The irradiation induces changes in hopping strengths, creating an asymmetric transmission profile around the Fermi energy, which is a crucial factor for achieving a higher figure of merit (FOM). Specific light configurations result in an FOM exceeding unity. We employ the Floquet–Bloch ansatz and minimal coupling scheme to model the irradiation effect, with transport properties evaluated using Green's function technique within the Landauer–Büttiker formalism. The investigation covers electrical conductance, thermopower, and thermal conductance due to electrons and phonons. Our research deepens understanding and opens avenues for tailoring nanostructures to fine-tune thermoelectric properties, advancing highly efficient energy conversion devices exploiting irradiation effects. [ABSTRACT FROM AUTHOR]

Published

2024

13. Carrier transport simulation methods for electronic devices with coexistence of quantum transport and diffusive transport.

Author

Tian, Liang, Sha, Wei E. I., Xie, Hao, Liu, Dongxue, Sun, Tian-Ge, Xia, Yin-Shui, and Chen, Wenchao

Subjects

*ELECTRONIC equipment, *GREEN'S functions, *ELECTRON transport, *SOLAR cells, *CONDUCTION bands, *RAILROAD tunnels, *ELECTRON energy loss spectroscopy, *CARRIER density

Abstract

In this manuscript, carrier transport simulation methods are proposed for devices with the coexistence of quantum transport and diffusive transport by combining the nonequilibrium Green's function method with the drift-diffusion transport simulation method. Current continuity between quantum transport and drift-diffusion transport is ensured by setting quantum transport current as the connection boundary condition of drift-diffusion simulation or by introducing quantum transport-induced carrier generation rates to drift-diffusion simulation. A comprehensive study of our method and the method combining the Wentzel–Kramers–Brillouin (WKB) method with the drift-diffusion transport simulation method is performed for n-type tunnel oxide passivating contact solar cell to investigate their applicable conditions and balance the accuracy and computational cost. As the oxide barrier width, barrier height, and electron effective mass increase, or the doping concentration in the electron transport layer decreases to the extent that the blocking effect of the oxide barrier on light-generated electrons becomes significant, method I is more accurate since the transmission coefficient near the conduction band edge calculated by WKB is overestimated; otherwise, method II is more suitable due to its low computational cost without the loss of accuracy. In addition, the differences between current densities, carrier densities, and Shockley–Read–Hall recombination rates simulated under the two current continuity conditions for the solar cell with different carrier mobilities are also further explored and analyzed. [ABSTRACT FROM AUTHOR]

Published

2024

14. Molecular heat transport across a time-periodic temperature gradient.

Author

Chen, Renai, Gibson, Tammie, and Craven, Galen T.

Subjects

*GREEN'S functions, *HEAT transfer, *MOLECULAR dynamics, *THERMAL conductivity, *STOCHASTIC systems

Abstract

The time-periodic modulation of a temperature gradient can alter the heat transport properties of a physical system. Oscillating thermal gradients give rise to behaviors such as modified thermal conductivity and controllable time-delayed energy storage that are not present in a system with static temperatures. Here, we examine how the heat transport properties of a molecular lattice model are affected by an oscillating temperature gradient. We use analytical analysis and molecular dynamics simulations to investigate the vibrational heat flow in a molecular lattice system consisting of a chain of particles connected to two heat baths at different temperatures, where the temperature difference between baths is oscillating in time. We derive expressions for heat currents in this system using a stochastic energetics framework and a nonequilibrium Green's function approach that is modified to treat the nonstationary average energy fluxes. We find that emergent energy storage, energy release, and thermal conductance mechanisms induced by the temperature oscillations can be controlled by varying the frequency, waveform, and amplitude of the oscillating gradient. The developed theoretical approach provides a general framework to describe how vibrational heat transmission through a molecular lattice is affected by temperature gradient oscillations. [ABSTRACT FROM AUTHOR]

Published

2024

15. Floquet non-equilibrium Green's function and Floquet quantum master equation for electronic transport: The role of electron–electron interactions and spin current with circular light.

Author

Mosallanejad, Vahid, Wang, Yu, and Dou, Wenjie

Subjects

*GREEN'S functions, *ELECTRON-electron interactions, *TRANSPORT equation, *NON-equilibrium reactions, *QUANTUM dots

Abstract

The non-equilibrium Green's function (NEGF) and quantum master equation (QME) are two main classes of approaches for electronic transport. We discuss various Floquet variances of these formalisms for transport properties of a quantum dot driven via interaction with an external periodic field. We first derived two versions of the Floquet NEGF. We also explore an ansatz of the Floquet NEGF formalism for the interacting systems. In addition, we derived two versions of Floquet QME in the weak interaction regime. With each method, we elaborate on the evaluation of the expectation values of the number and current operators. We examined these methods for transport through a two-level system that is subject to periodic driving. The numerical results of all four methods show good agreement for non-interacting systems in the weak regime. Furthermore, we have observed that circular light can introduce spin current. We expect these Floquet quantum transport methods to be useful in studying molecular junctions exposed to light. [ABSTRACT FROM AUTHOR]

Published

2024

16. A potential building block for spintronic devices: Theoretical description of electronic transport and magnetoresistance of catechol under an external magnetic field stimulus.

Author

Soto-Gómez, E. Y., Ojeda, J. H., Gil-Corrales, J. A., Gallego, Daniel, and Eramo, Giuseppe

Subjects

*CATECHOL, *MAGNETIC fields, *MAGNETORESISTANCE, *GREEN'S functions, *SPIN polarization

Abstract

Understanding the electronic transport properties of low-dimensional devices has increased dramatically in recent decades, especially for those with a promising future for application in nanotechnology. Among these nanoscopic systems are molecular systems, particularly organic molecules such as catechol, representing the small piece of a potential conductor assembled through larger biomolecules and inserted between two or more metal contacts. In this work, we present a theoretical description of the electronic transport of catechol, based on its π -conjugated aromatic system, under an external magnetic field stimulus, which is transverse to the alignment of the molecule. Thus, we analyze catechol's spintronic properties through the magnetoresistance generated by this field. We model the molecule using a tight-binding Hamiltonian and Green's functions; the transmission probability is calculated by means of the Fisher-Lee relation, and the characteristic current–voltage, spin polarization, and magnetoresistance curves based on Landauer's approach for two linking models of catechol to the metallic contacts. The results suggest a strong dependence on the spin direction of the charge carriers and the Zeeman energy (E z) on the Fermi level, generating a switch-like mechanism going from conducting to semiconducting material. This behavior opens a potential application of these catechol-based systems in future spintronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

17. Time-dependent electron transfer and energy dissipation in condensed media.

Author

Arguelles, Elvis F. and Sugino, Osamu

Subjects

*CONDENSED matter, *CHARGE exchange, *ENERGY dissipation, *ENERGY transfer, *GREEN'S functions, *SEMICLASSICAL limits

Abstract

We study a moving adsorbate interacting with a metal electrode immersed in a solvent using the time-dependent Newns–Anderson–Schmickler model Hamiltonian. We have adopted a semiclassical trajectory treatment of the adsorbate to discuss the electron and energy transfers that occur between the adsorbate and the electrode. Using Keldysh Green's function scheme, we found a non-adiabatically suppressed electron transfer caused by the motion of the adsorbate and coupling with bath phonons that model the solvent. The energy is thus dissipated into electron–hole pair excitations, which are hindered by interacting with the solvent modes and facilitated by the applied electrode potential. The average energy transfer rate is discussed in terms of the electron friction coefficient and given an analytical expression in the slow-motion limit. [ABSTRACT FROM AUTHOR]

Published

2024

18. Combined resonant tunneling and rate equation modeling of terahertz quantum cascade lasers.

Author

Chen, Zhichao, Liu, Andong, Chang, Dong, Dhillon, Sukhdeep, Razeghi, Manijeh, and Wang, Feihu

Subjects

*RATE equation model, *QUANTUM cascade lasers, *GREEN'S functions, *DENSITY matrices, *RESONANT tunneling, *INTERFACIAL roughness, *STIMULATED emission

Abstract

Terahertz (THz) quantum cascade lasers (QCLs) are technologically important laser sources for the THz range but are complex to model. An efficient extended rate equation model is developed here by incorporating the resonant tunneling mechanism from the density matrix formalism, which permits to simulate THz QCLs with thick carrier injection barriers within the semi-classical formalism. A self-consistent solution is obtained by iteratively solving the Schrödinger–Poisson equation with this transport model. Carrier–light coupling is also included to simulate the current behavior arising from stimulated emission. As a quasi-ab initio model, intermediate parameters, such as pure dephasing time and optical linewidth, are dynamically calculated in the convergence process, and the only fitting parameters are the interface roughness correlation length and height. Good agreement has been achieved by comparing the simulation results of various designs with experiments, and other models such as density matrix Monte Carlo and non-equilibrium Green's function method that, unlike here, require important computational resources. The accuracy, compatibility, and computational efficiency of our model enable many application scenarios, such as design optimization and quantitative insights into THz QCLs. Finally, the source code of the model is also provided in the supplementary material of this article for readers to repeat the results presented here, investigate, and optimize new designs. [ABSTRACT FROM AUTHOR]

Published

2024

19. Far-field thermal radiation of layered ferromagnetic topological materials.

Author

Zhang, Yong-Mei and Wang, Jian-Sheng

Subjects

*HEAT radiation & absorption, *FERROMAGNETIC materials, *GREEN'S functions, *TOPOLOGICAL insulators, *MAGNETIC films, *TOPOLOGICAL defects (Physics)

Abstract

High Chern number topological insulators can be obtained in a film of layered magnetic block system theoretically and experimentally. With nonzero Chern numbers, Chern insulators become valuable for fundamental topological physics and for improving next-generation electronic devices. We study energy and angular momentum radiation from layered topological insulators using the Dirac Fermion approach and by Green's function method. We make a connection between radiation magnitude and topological phase transitions. We find that the magnetic exchange field, intra-layer coupling, and inter-layer interaction are efficient measures to modify the energy radiation of layered topological materials. Moreover, the magnetic exchange field is indispensable for emitting angular momentum due to the need for breaking time-reversal symmetry. [ABSTRACT FROM AUTHOR]

Published

2024

20. Electric fields near undulating dielectric membranes.

Author

Pogharian, Nicholas, dos Santos, Alexandre P., Ehlen, Ali, and Olvera de la Cruz, Monica

Subjects

*ELECTRIC fields, *DIELECTRICS, *GREEN'S functions, *ROUGH surfaces, *BILAYER lipid membranes, *IONIC conductivity

Abstract

Dielectric interfaces are crucial to the behavior of charged membranes, from graphene to synthetic and biological lipid bilayers. Understanding electrolyte behavior near these interfaces remains a challenge, especially in the case of rough dielectric surfaces. A lack of analytical solutions consigns this problem to numerical treatments. We report an analytic method for determining electrostatic potentials near curved dielectric membranes in a two-dimensional periodic "slab" geometry using a periodic summation of Green's functions. This method is amenable to simulating arbitrary groups of charges near surfaces with two-dimensional deformations. We concentrate on one-dimensional undulations. We show that increasing membrane undulation increases the asymmetry of interfacial charge distributions due to preferential ionic repulsion from troughs. In the limit of thick membranes, we recover results mimicking those for electrolytes near a single interface. Our work demonstrates that rough surfaces generate charge patterns in electrolytes of charged molecules or mixed-valence ions. [ABSTRACT FROM AUTHOR]

Published

2024

21. Ballistic performance and overshoot effects in gallenene nanoribbon field-effect transistors.

Author

Poljak, Mirko, Matić, Mislav, Prevarić, Ivan, and Japec, Karolina

Subjects

*FIELD-effect transistors, *GREEN'S functions, *QUANTUM confinement effects, *AB-initio calculations, *NANOSTRUCTURED materials, *NANOSATELLITES

Abstract

Gallenene is a novel metallic 2D material that can provide a semiconducting counterpart if patterned into quasi-one-dimensional (quasi-1D) nanostructures, i.e., gallenene nanoribbons (GaNRs). We investigate semiconducting GaNRs as a potential channel material for future ultrascaled field-effect transistors (FETs) by employing quantum transport simulations based on Green's functions and tight-binding Hamiltonians with the orbital resolution calibrated on ab initio calculations. The impact of GaNR width downscaling from ∼6 nm down to ∼0.2 nm on the electronic, transport, and ballistic device properties is investigated for the FET channel length of 15 nm. We report current enhancement and injection velocity overshoot effects for sub-1.2 nm-wide nFETs and pFETs, with a maximum current increase of 53% in the 1.2 nm-wide GaNR pFET in comparison to the widest device. In addition, promising current-driving capabilities of n- and p-channel GaNR FETs are observed with top ballistic currents of more than 2.2 mA/μm and injection velocities of up to 2.4 × 107 cm/s. The reported data are explained by analyzing the evolution of band structure and related parameters such as injection velocity, quantum capacitance, effective transport mass etc., with increasing quantum confinement effects in ultranarrow GaNRs. Generally, we find that quasi-1D gallenene is a promising channel material for future nanoscale FETs, especially for transistor architectures based on stacked nanosheets. [ABSTRACT FROM AUTHOR]

Published

2024

22. Investigation of negative differential resistance in metal-edge-contact MoS2 field effect transistor.

Author

Garg, Ankur, Ehteshamuddin, Mohammad, Sharma, Somit, and Dasgupta, Avirup

Subjects

*FIELD-effect transistors, *GREEN'S functions, *DENSITY functional theory, *TRANSITION metals, *ELECTRONIC equipment, *METAL oxide semiconductor field-effect transistors

Abstract

Negative differential resistance (NDR) is observed in various emerging electronic devices. As compared to the conventional silicon-based field effect transistor (FET), the NDR is widely investigated in two-dimensional (2D) transition metal dichalcogenide (TMD) FETs. In this work, we study the NDR effect for the TMD-based metal-edge-contact MoS 2 double-gate FET with 10 nm channel length. The multiscale atomistic simulation is demonstrated for the lateral heterostructure of a metal–semiconductor–metal FET by density functional theory, maximally localized Wannier function tight-binding Hamiltonian, and non-equilibrium Green's function methods. The quantum transport model in the given lateral heterostructure resulted in NDR in a double-gate FET. Here, we focus on the NDR by the systematic study of the transmission spectrum of the metal-edge-contact MoS 2 channel FET and finally compare it with zero NDR ideal highly doped FET. The peak-to-valley ratio in the NDR response can be modulated with the change in the gate-to-source voltage and can be used to explore various future electronic applications. [ABSTRACT FROM AUTHOR]

Published

2024

23. Band dispersion, scattering rate, and carrier mobility using the poles of Green's function for dilute nitride alloys.

Author

Seifikar, Masoud, O'Reilly, Eoin P., and Fahy, Stephen

Subjects

*GREEN'S functions, *DILUTE alloys, *CHARGE carrier mobility, *GROUP velocity, *DISPERSION relations, *TRANSPORTATION rates

Abstract

The band-anticrossing (BAC) model provides the basis for the self-consistent Green's function method that we have previously developed to calculate the density of states of GaN x As 1 − x dilute nitride alloys. In this paper, we extend this Green's function method to include the complex energy states and to find the poles of the Green's function, thereby allowing one to calculate the dispersion relation, group velocity, and the carrier decay rate in disordered dilute nitride alloys. Two different models of the N states have been studied to investigate the band structure of these materials: (1) the conventional two-band BAC model, which assumes that all N states are located at the same energy, and (2) a model which includes N states distributed over a range of energies, as expected in actual dilute nitride samples. Our results for the second model show a much shorter carrier mean-free path, and lower carrier mobility for GaN x As 1 − x , with the magnitude of the calculated mobility in good agreement with the experimental data. [ABSTRACT FROM AUTHOR]

Published

2024

24. Strain-controlled charge and spin current rectifications in spin–orbit coupled graphene nano-ribbon: A new proposition.

Author

Majhi, Joydeep and Maiti, Santanu K.

Subjects

*GREEN'S functions, *GRAPHENE, *STRAINS & stresses (Mechanics), *NUMERICAL analysis

Abstract

In this work, we investigate the possibilities of performing charge and spin current rectifications using graphene nano-ribbon in the presence of Rashba spin–orbit (SO) interaction. More specifically, we explore the specific role of mechanical strain on these two different types of current rectifications. The system is simulated by a tight-binding framework, where all the results are worked out based on the standard Green's function formalism. In order to have current rectification, an asymmetry is required, which is incorporated through uncorrelated disorder among the constituent lattice points. From our extensive numerical analysis, we find that reasonably large charge and spin current rectifications can be obtained under strained conditions, and all the physical pictures are valid for a broad range of tight-binding parameters. The rectification properties are studied mostly for zigzag graphene nano-ribbons; however, an armchair ribbon is also taken into account for a clear comparison. Our work may provide a new direction of getting strain-controlled current rectifications in similar kinds of other physical systems as well. [ABSTRACT FROM AUTHOR]

Published

2024

25. Open-boundary cluster model with a parameter-free complex absorbing potential.

Author

Imamura, Kosuke, Yasuike, Tomokazu, and Sato, Hirofumi

Subjects

*GREEN'S functions, *DENSITY of states, *VARIATIONAL principles, *SURFACE states, *ELECTRONIC structure

Abstract

In quantum chemical calculations of heterogeneous structures in solids, e.g., when an impurity is located on the surface, the conventional cluster model is insufficient to describe the electronic structure of substrates due to its finite size. The open-boundary cluster model (OCM) overcomes this problem by performing cluster calculations under the outgoing-wave boundary condition. In this method, a complex absorbing potential (CAP) is used to impose the boundary condition, but the CAP used in the previous studies required parameter optimization based on the complex variational principle. This study proposes and applies a parameter-free CAP to OCM calculations. This approach makes it possible to uniquely determine the band-specific CAP based on the surface Green's function theory. Using this CAP, we conducted OCM calculations of the tight-binding model of a one-dimensional semi-infinite chain, and we found that the calculated density of states agreed with the exact one. Surface states of the Newns–Anderson–Grimley model were also computed using the CAP, and the projected density of states on the adsorbed atom was successfully reproduced. [ABSTRACT FROM AUTHOR]

Published

2024

26. Atomistic simulation of thermoelectric properties in cove-edged graphene nanoribbons.

Author

Xie, Zhong-Xiang, Chen, Xue-Kun, Yu, Xia, Deng, Yuan-Xiang, Zhang, Yong, Zhou, Wu-Xing, and Jia, Pin-Zhen

Subjects

*NANORIBBONS, *GREEN'S functions, *GRAPHENE, *SEEBECK coefficient, *PHONONS

Abstract

We present an atomistic simulation of thermoelectric properties in cove-edged graphene nanoribbons (CGNRs) via the nonequilibrium Green's function. Different from gapless zigzag graphene nanoribbons (ZGNRs), CGNRs exhibit a noticeable bandgap. Such a bandgap can be modulated by varying three structural parameters (namely, the width N, the distance between adjacent coves m, as well as the shortest offset n) of CGNRs, which can give rise to the transition from semiconducting to semi-metallic. Due to the less dispersive phonon bands and the decrease in the number of phonon channels of CGNRs, they are found to have the lower phonon thermal conductance than ZGNRs. Modulation of CGNRs can produce over tenfold improvement of the maximum of ZT compared to ZGNRs. This improvement is due to the promotion of the Seebeck coefficient together with the degradation of the phonon thermal conductance of CGNRs compared to ZGNRs. [ABSTRACT FROM AUTHOR]

Published

2024

27. Nonreciprocity and chirality hosted by ferromagnetic helical chains: Heat generation vs spin filtering.

Author

Zhang, Lin, Tang, Yuxin, Zhai, Guangwei, Jiang, Feng, Zhu, Yanyan, and Yan, Yonghong

Subjects

*SPIN-orbit interactions, *GREEN'S functions, *CHIRALITY, *SPIN-polarized currents, *ELECTRIC potential, *HELICAL structure

Abstract

Motivated by the booming development of spintronics based on chiral helical microstructures, we employed the standard nonequilibrium Green's function theory to study nonreciprocity and chirality of the heat generation and spin filtering in ferromagnetic helical chains. Our results demonstrate that magnetization, spin–orbit interaction, and nonstep electrostatic potential distribution by bias jointly determine nonreciprocity of the heat generation, and only spin–orbit interaction determines nonreciprocity of the spin-polarized current. Chirality of the heat generation and spin-polarized current is determined by both magnetization and spin–orbit interaction, and some quantitative relationships related to chirality were discovered. However, a transverse field can break these relations and suppress heat generation significantly and modulate nonreciprocity and chirality of the spin-polarized current effectively. By further simulating the critical electrostatic potential distribution, we found with the transverse field applied, compared to the case with zero temperature, that the finite temperature less than one characteristic phonon energy can suppress nonreciprocity of the heat generation while enhancing that of the spin filtering. In terms of chirality, compared to the left-handed helical structure, the right-handed one is more advantageous for designing spin filtering diodes. [ABSTRACT FROM AUTHOR]

Published

2023

28. Ultrahigh spin filter efficiency and large spin Seebeck polarization of binuclear manganese phthalocyanine molecular junctions on nickel electrodes.

Author

Yin, Shao-Chong, Yu, Jing-Xin, Hou, Zhi-Yu, Liu, Xiu-Ying, and Li, Xiao-Dong

Subjects

*NICKEL electrodes, *SPIN polarization, *DENSITY functionals, *MANGANESE, *DENSITY functional theory, *NEUTRON transport theory, *GREEN'S functions, *HEUSLER alloys

Abstract

In this paper, we investigated the spin transport properties of binuclear manganese phthalocyanine (M n 2 P c 2) spintronic devices sandwiched between two nickel electrodes using the non-equilibrium Green's function method in combination with density functional theory. Based on the calculation results, the M n 2 P c 2 device exhibited excellent spin-filtering capabilities, demonstrating an exceptionally high spin filter efficiency (SFE). Irrespective of the parallel or antiparallel orientation of magnetization in the electrodes, we observed that when both manganese atoms were in a spin-up state, the SFE of spin-resolved currents under finite bias and the thermoelectric currents induced by temperature gradients at fixed temperatures were both close to 100%. The large spin Seebeck polarization of the M n 2 P c 2 device was also obtained at low reference temperatures. This study explores the potential for developing multifunctional spintronic single-molecule devices using Ni − M n 2 P c 2. [ABSTRACT FROM AUTHOR]

Published

2023

29. Many-body GW calculations with very large scale polarizable environments made affordable: A fully ab initio QM/QM approach.

Author

Amblard, David, Blase, Xavier, and Duchemin, Ivan

Subjects

*GREEN'S functions, *COULOMB potential, *SUSTAINABLE construction, *FULLERENES

Abstract

We present a many-body GW formalism for quantum subsystems embedded in discrete polarizable environments containing up to several hundred thousand atoms described at a fully ab initio random phase approximation level. Our approach is based on a fragment approximation in the construction of the Green's function and independent-electron susceptibilities. Further, the environing fragments susceptibility matrices are reduced to a minimal but accurate representation preserving low order polarizability tensors through a constrained minimization scheme. This approach dramatically reduces the cost associated with inverting the Dyson equation for the screened Coulomb potential W, while preserving the description of short to long-range screening effects. The efficiency and accuracy of the present scheme is exemplified in the paradigmatic cases of fullerene bulk, surface, subsurface, and slabs with varying number of layers. [ABSTRACT FROM AUTHOR]

Published

2023

30. Insights into electronic and transport properties of phosphorene nanorings in two perpendicular directions: Effects of circular and elliptical external potentials.

Author

Bazrafshan, M. Amir, Khoeini, Farhad, and Szafran, Bartlomiej

Subjects

*MORE O'Ferrall-Jencks diagrams, *GREEN'S functions, *PHOSPHORENE, *NANOSATELLITES, *BAND gaps

Abstract

In this work, we study the electronic and transport properties of phosphorene nanorings in two perpendicular directions (zigzag and armchair directions) in the presence of a zigzag metallic source and drain leads. Our results are based on the non-equilibrium Green's function method and a five-parameter tight-binding approach. We investigate how system parameters affect the electronic transport. These parameters include the radius of the rings, the width of the leads, and the external potential. Our results show that for all configurations studied, a transport energy gap exists whose size can be tuned by the width of the leads and the radius of the nanoring. The transmission function of wider leads shows more sensitivity to the variation of the inner radius due to higher electronic states that can respond to smaller changes in the scattering region. In addition, the transport along the armchair direction is more susceptible to tuning than the transport along the zigzag direction. The effects of external potentials on the conductance are more pronounced than the geometrical parameters. In particular, the circular potential of the amplitude of 0.1 eV can widen the transport gap by about ∼0.35 eV. [ABSTRACT FROM AUTHOR]

Published

2023

31. Realizing tunneling electroresistance effect in the Au/h-BN/In2Se3/Au vertical ferroelectric tunnel junction.

Author

Yang, Shuli, Kang, Lili, Zheng, Xiaohong, Jiang, Peng, and Zhao, Gaofeng

Subjects

*TUNNEL junctions (Materials science), *FERROELECTRIC materials, *GREEN'S functions, *FERROELECTRIC devices, *TUNNEL design & construction, *DENSITY functional theory, *LEAD titanate

Abstract

Two-dimensional (2D) ferroelectric tunnel junctions (FTJs) have great potential in the design of non-volatile memory devices due to the tunneling electroresistance (TER) effect and the fact that it is not constrained by critical thickness. Incorporation of 2D ferroelectric materials in realistic FTJs inevitably involves the contacts to the traditional three-dimensional (3D) metals. However, how to design the FTJs by combining the 2D ferroelectric materials with the 3D metals still needs to be studied. In this work, we design a vertical 3D FTJ by adopting the 3D metal Au as the left and right electrodes and the 2D ferroelectric material In2Se3 together with h-BN as the central scattering region. By density functional theory combined with the non-equilibrium Green's function (NEGF) method, we demonstrate that the h-BN intercalation with a large bandgap plays the role of good "insulator," which breaks the symmetry of the left and right electrodes. As a result, we obtain the TER ratio of about 170%, and it can be further improved to about 1200% if two layers of In2Se3 (2L-In2Se3) are adopted as the tunneling barrier layer. Our results provide another way for the design and application of ferroelectric memory devices based on 2D ferroelectric materials. [ABSTRACT FROM AUTHOR]

Published

2023

32. Estimations of Levinson-type inequalities using novel 3-convex Green functions with Taylor’s formula.

Author

Rasheed, Awais, Khan, Khuram Ali, Pečarić, Josip, and Pečarić, Đilda

Abstract

The goal of this study is to derive the generalized Levinson-type inequalities in the form of Taylor representation for higher order convex functions. This study uses Taylor’s formula and several novel types of 3-convex Green functions, to establish the novel identities associated with Bullen-type inequalities for higher order convex functions. Moreover, various Levinson-type inequalities are proved for positive real weights using Green functions and Taylor’s formula. [ABSTRACT FROM AUTHOR]

Published

2024

33. Electronic structure of the strongly correlated electron system plutonium hexaboride: A study from single‐particle approximations and many‐body calculations.

Author

Li, Ru‐song, Qu, Xin, Wang, Jin‐tao, Wang, Fei, and Xie, Zheng

Subjects

*GREEN'S functions, *EXCHANGE interactions (Magnetism), *FERMI level, *ELECTRONIC spectra, *ELECTRONIC structure, *SPIN-orbit interactions

Abstract

The electronic structure of the strongly correlated electron system plutonium hexaboride is studied by using single‐particle approximations and a many‐body approach. Imaginary components of impurity Green's functions show that 5fj=5/2 and 5fj=7/2 manifolds are in conducting and insulating regimes, respectively. Quasi‐particle weights and their ratio suggest that the intermediate coupling mechanism is applicable for Pu 5f electrons, and PuB6 might be in the orbital‐selective localized state. The weighted summation of occupation probabilities yields the interconfiguration fluctuation and average occupation number of 5f electrons n5f ~ 5.101. The interplay of 5f–5f correlation, spin‐orbit coupling, Hund's exchange interaction, many‐body transition of 5f configurations, and final state effects might be responsible for the quasiparticle multiplets in electronic spectrum functions. Prominent characters in the density of state, such as the coexistence of atomic multiplet peaks in the vicinity of the Fermi level and broad Hubbard bands in the high‐lying regime, suggest that PuB6 could be identified as a Racah material. Finally, the quasiparticle band structure is also presented. [ABSTRACT FROM AUTHOR]

Published

2024

34. Nonlinear mechanical response of finite-length soft composites with random dislocations.

Author

Jalilvand, Samira, Mirzaei, Moein, and Mousavi, Hamze

Subjects

*VIBRATIONAL spectra, *GREEN'S functions, *DNA structure, *NUMERICAL analysis, *RNA

Abstract

The effects of random dislocations on the vibrational properties of finite-length RNA and DNA macro-structures have been investigated by means of a harmonic Hamiltonian and the Green's function method. The RNA molecule has been modeled using a half ladder model, and three models (a fishbone model and two different strand models) have been employed to model the structure of DNA. The lengths of the finite and cyclic systems are gradually increased to more accurately approximate the structures of RNA and DNA. Springs whose behaviors are governed by Hooke's constitutive law have been used to represent the bonds between the masses, with the stiffness of the vertical springs randomly changing along the length of each model. This results in a more realistic representation of the inherent randomness of the studied structures. To investigate the effect of random dislocations on the mechanical response of the studied systems, it has been assumed that a random mass-spring ensemble has been knocked out of place by an external force. It has been found that increasing the number of building blocks along the length of the models suppresses the influence of dislocations on the vibration spectra of RNA and DNA. It was also observed that at low frequencies, the influence of dislocations becomes more pronounced. Besides, taking into account the collective mass of the sugar-phosphate backbone results in the appearance of gaps in the vibration spectra. By introducing dislocations into the models, additional dislocation-induced vibrational states appear in the DOS curves. What stands out from the results is that the responses of the studied systems to these changes are strictly nonlinear. The employed methodology can be applied to investigate the mechanical response of damaged RNA and DNA. [ABSTRACT FROM AUTHOR]

Published

2024

35. Non-equilibrium BCS-BEC crossover and unconventional FFLO superfluid in a strongly interacting driven-dissipative Fermi gas.

Author

Kawamura, Taira and Ohashi, Yoji

Subjects

BCS-BEC crossover, BOSE-Einstein condensation, MOMENTUM distributions, GREEN'S functions, CHEMICAL potential, ELECTRON gas

Abstract

We present a theoretical review of the recent progress in non-equilibrium BCS (Bardeen-Cooper-Schrieffer)-BEC (Bose-Einstein condensation) crossover physics. As a paradigmatic example, we consider a strongly interacting driven-dissipative two-component Fermi gas where the non-equilibrium steady state is tuned by adjusting the chemical potential difference between two reservoirs that are coupled with the system. As a powerful theoretical tool to deal with this system, we employ the Schwinger-Keldysh Green's function technique. We systematically evaluate the superfluid transition, as well as the single-particle properties, in the non-equilibrium BCS-BEC crossover region, by adjusting the chemical potential difference between the reservoirs and the strength of an s-wave pairing interaction associated with a Feshbach resonance. In the weak-coupling BCS side, the chemical potential difference is shown to imprint a two-step structure on the particle momentum distribution, leading to an anomalous enhancement of pseudogap, as well as the emergence of exotic Fulde-Ferrell-Larkin-Ovchinnikov-type superfluid instability. Since various non-equilibrium situations have recently been realized in ultracold Fermi gases, the theoretical understanding of non-equilibrium BCS-BEC crossover physics would become increasingly important in this research field. [ABSTRACT FROM AUTHOR]

Published

2024

36. Perturbational Analysis of Magnetic Force Theorem for Magnetic Exchange Interactions in Molecules and Solids.

Author

Seo, Dong-Kyun

Subjects

*EXCHANGE interactions (Magnetism), *GREEN'S functions, *MAGNETISM, *MAGNETIC insulators, *TRANSITION metal complexes

Abstract

There have been increasing efforts to compute magnetic exchange coupling constants for transition metal complexes and magnetic insulators using the magnetic force theorem and Green's function-based linear response methods. These were originally conceived for magnetic metals, yet it has not been clear how these methods fare conceptually with the conventional models based on electron-correlation interactions among so-called magnetic orbitals. We present a spinor-based theoretical analysis pertinent to the magnetic force theorem and linear response theory using Brillouin–Wigner perturbation method and Green's function perturbation method, and we shed light on the conceptual nature of the Lichtenstein formula in its applications for calculations of the total energy and magnetic exchange coupling constants for both molecules and solids. Derivation of the magnetic force theorem in this perturbational analysis identifies the first-order energy correction terms, which are considered as the ferromagnetic component for the magnetic exchange interactions of transition metal compounds but are not included in the Lichtenstein formula. Detailed perturbational analysis of the energy components involved in the magnetic force theorem identifies the energy components that are missing in the Lichtenstein formula but are critical in the Anderson's model for transition metal complexes and magnetic insulators where magnetic orbitals can overlap. [ABSTRACT FROM AUTHOR]

Published

2024

37. A Study on Positive Solutions to Nonlinear Fractional Differential Equations.

Author

Gou, Haide

Subjects

*NONLINEAR boundary value problems, *GREEN'S functions, *FRACTIONAL differential equations, *NONLINEAR differential equations, *FIXED point theory

Abstract

The purpose of this article concerns a type of nonlinear boundary value problem of fractional differential equations with the Caputo derivative. Using the fixed point index theory of condensing mapping in cones, the existence results of positive solutions for such a problem are obtained. [ABSTRACT FROM AUTHOR]

Published

2024

38. A factorization of the GJMS operators of special Einstein products and applications.

Author

Case, Jeffrey S. and Malchiodi, Andrea

Subjects

*GREEN'S functions, *DIFFERENTIAL operators, *OPERATOR functions, *INTEGERS, *NEW product development

Abstract

We show that the GJMS operators of a special Einstein product factor as a composition of second‐ and fourth‐order differential operators. In particular, our formula applies to the Riemannian product Hℓ×Sd−ℓ$H^{\ell } \times S^{d-\ell }$. We also show that there is an integer D=D(k,ℓ)$D = D(k,\ell)$ such that if d⩾D$d \geqslant D$, then for any special Einstein product Nℓ×Md−ℓ$N^\ell \times M^{d-\ell }$, the Green's function for the GJMS operator of order 2k$2k$ is positive. As a result, these products give new examples of closed Riemannian manifolds for which the Q2k$Q_{2k}$‐Yamabe problem is solvable. [ABSTRACT FROM AUTHOR]

Published

2024

39. Wave reflection and transmission in a piezomagnetic right-angle plane with irregular boundaries: a boundary element approach.

Author

Zhang, Xi-meng and Qi, Hui

Subjects

*BOUNDARY element methods, *MAGNETIC flux density, *GREEN'S functions, *STRESS concentration, *ANALYTICAL solutions

Abstract

This paper examines the problem of a piezomagnetic right-angle plane with irregular boundaries using the boundary element method. It considers SH waves and line source loads as external forces acting on the piezomagnetic right-angle plane. The effectiveness of the boundary element method is demonstrated through two different numerical examples. Firstly, in the absence of line source loads, the paper analyzes the dynamic characteristics in the first example by employing the image method and Graf addition theorem. Then, it introduces Green's identities and solves the Green's function in infinite three-dimensional space. In the second example, the paper investigates the dynamic characteristics when irregular boundaries are subjected to line source loads using the boundary element method. The results elucidate the influence on the dynamic stress concentration factor and magnetic field intensity concentration factor under appropriate conditions. Additionally, the analytical solutions are compared with finite element solutions to validate the accuracy of the conclusions presented in this study. [ABSTRACT FROM AUTHOR]

Published

2024

40. A real space convolution‐based approximate algorithm for phase field model involving elastic strain energy.

Author

Gao, YaQian, Chi, XueBin, Yin, JiXian, and Zhang, Jian

Subjects

*GREEN'S functions, *STRAIN energy, *FOURIER transforms, *ELASTICITY, *ALGORITHMS

Abstract

Phase field models have been employed extensively in the study of microstructure evolution in materials. Elasticity plays an important role in solid‐state phase transformation processes, and it is usually introduced into phase field models in terms of the elastic strain energy by applying Khachaturyan–Shatalov microelasticity theory. Conventionally, this energy is derived in the reciprocal space and results in full‐space Fourier transformation in practice, which becomes bottle‐neck in large‐scale and massively‐parallel applications. In this article, we propose an error‐controlled approximation algorithm for scalable and efficient calculation of the elastic strain energy in phase field models. We first derive a real‐space convolutional representation of the elastic strain energy by representing the equilibrium displacements in the Khachaturyan–Shatalov microelasticity theory using Green's function. Then we propose an error‐controlled truncation criterion to approximate the corresponding terms in the phase field model. Finally, a carefully designed parallel algorithm is presented to carry out large‐scale simulations. The accuracy and efficiency of the proposed algorithm are demonstrated by real‐world large‐scale phase field simulations. [ABSTRACT FROM AUTHOR]

Published

2024

41. The effect of fastener clip fatigue for high-speed railway on vehicle-track dynamic interaction: Numerical analysis and probabilistic evaluation.

Author

Li, Zheng, Liu, Hubing, Wang, Weidong, and Xu, Lei

Subjects

*FATIGUE cracks, *GREEN'S functions, *EQUATIONS of motion, *FINITE element method, *SERVICE life, *HIGH speed trains

Abstract

• A novel model for investigating the vehicle-induced fatigue damage of fastener clips in high-speed railway is established. • An efficient dynamic solution and an iterative method are introduced into the vehicle-track (VT) dynamic interaction. • The spatial variability of the fastener is characterized in the VT system by combining the random field expansion method. • The stochastic fatigue damage evolution of the fastener clips and its impact on the VT system have been revealed. To investigate the vehicle-induced fatigue damage evolution of fastener clips and their impact on the vehicle-track (VT) system, a numerical dynamic model is established to achieve probabilistic evaluation. The "rain flow" counting method is adopted to describe the stress cycles of the hazard area of the clips, and the S-N curve is used to predict the fatigue life of the clips. The solution of the dynamic equation of motion is obtained by the time-domain Green's function method, which is an effective method to improve computational efficiency. A versatile iterative algorithm is adopted to solve the nonlinear system considering the damaged clips. In the probabilistic evaluation framework, a novel random field method is employed to depict the spatial variability of clips' strength. The applicability of the model established in this work in aspects of expressing random damage of fasteners and evaluating the dynamic behavior of the system is demonstrated by different numerical examples. The results show that the dynamic responses of the train and track system significantly exacerbate as the number of train cycles increases, which is closely related to the variability and non-uniform damage of the fasteners. The probability of cumulative damage to the fasteners induced by the train follows a three-stage rule, and the fatigue damage of the non-uniform fastener system caused by the train is greater than that of the uniform situation. In addition, the short wave components of track irregularity will significantly exacerbate the damage to fasteners and therefore degrade the status of the railway line. As the driving speed increases, the damage to the fasteners also increases, but the impact of vehicle speed on the fastener damage is smaller than that of track irregularity, especially in the range of fatigue damage greater than 0.9. Therefore, maintaining the geometric smoothness of the track, controlling the uniformity of the mechanical properties of the fasteners, and reducing the driving speed are feasible measures to extend the service life of the fastener system, thereby ensuring the operation of high-speed trains. [ABSTRACT FROM AUTHOR]

Published

2024

42. Global solutions to the Cauchy problem of viscous shallow water equations in some classes of large data.

Author

Qi, Jie and Wang, Weike

Subjects

CAUCHY problem, GREEN'S functions, SHALLOW-water equations

Abstract

Keywords: Regularity criterion; bootstrap argument; Green's function; global existence; decay rate of solution.GraphBy Jie Qi and Weike WangReported by Author; Author [Extracted from the article]

Published

2024

43. Three-Dimensional Multiferroic Structures under Time-Harmonic Loading.

Author

Nirwal, Sonal, Pan, Ernian, Lin, Chih-Ping, and Tran, Quoc Kinh

Subjects

MECHANICAL loads, GREEN'S functions, ORDINARY differential equations, RAYLEIGH waves, IMPACT loads

Abstract

Magneto-electro-elastic (MEE) materials are a specific class of advanced smart materials that simultaneously manifest the coupling behavior under electric, magnetic, and mechanical loads. This unique combination of properties allows MEE materials to respond to mechanical, electric, and magnetic stimuli, making them versatile for various applications. This paper investigates the static and time-harmonic field solutions induced by the surface load in a three-dimensional (3D) multilayered transversally isotropic (TI) linear MEE layered solid. Green's functions corresponding to the applied uniform load (in both horizontal and vertical directions) are derived using the Fourier-Bessel series (FBS) system of vector functions. By virtue of this FBS method, two sets of first-order ordinary differential equations (i.e., N-type and LM-type) are obtained, with the expansion coefficients being Love numbers. It is noted that the LM-type system corresponds to the MEE-coupled P-, SV-, and Rayleigh waves, while the N-type corresponds to the purely elastic SH- and Love waves. By applying the continuity conditions across interfaces, the solutions for each layer of the structure (from the bottom to the top) are derived using the dual-variable and position (DVP) method. This method (i.e., DVP) is unconditionally stable when propagating solutions through different layers. Numerical examples illustrate the impact of load types, layering, and frequency on the response of the structure, as well as the accuracy and convergence of the proposed approach. The numerical results are useful in designing smart devices made of MEE solids, which are applicable to engineering fields like renewable energy. [ABSTRACT FROM AUTHOR]

Published

2024

44. Numerical solution and analysis of extended Fisher–Kolmogorov equation using an improved collocation algorithm.

Author

Shallu and Kukreja, V. K.

Subjects

*GREEN'S functions, *NUMERICAL analysis, *SPLINES, *EQUATIONS, *QUINTIC equations

Abstract

The paper investigated the approximate solution of the extended Fisher–Kolmogorov. For this, an advanced approach: the improved quintic B-spline collocation technique has been employed, which is an enhancement over the conventional B-spline collocation method. The B-spline interpolant of degree five has been refined through the posteriori corrections, leading to the development of the improved B-spline solution. This proposed technique demonstrates superior convergence compared to the standard B-spline method, as assessed both theoretically and numerically. In tackling the extended Fisher–Kolmogorov equation, the space discretization is conducted using the improved quintic B-spline collocation methodology (IQSCM), and for the temporal domain discretization, the Crank-Nicolson scheme is applied. The error bounds and convergence analysis is established using the Green's functions. Von-Neumann stability analysis is carried out to discuss the stability of the technique. A few examples are solved and are represented graphically which helps in determining the nature of the solution. Also, $ L_{2} $ L2, $ L_{\infty } $ L∞ error norms, and order of convergence are calculated to demonstrate the contribution of the new improved technique over the standard spline collocation technique. [ABSTRACT FROM AUTHOR]

Published

2024

45. Exploring the impact on contact adhesion layer properties in numerical simulations.

Author

Shamim, Reza

Subjects

*GREEN'S functions, *MATERIALS science, *CONTACT mechanics, *MODULUS of elasticity, *SUBSTRATES (Materials science)

Abstract

This paper presents a comprehensive investigation into the impact of key parameters on contact adhesion layer properties using numerical simulations, addressing fundamental questions in contact mechanics. Aiming to explore interfacial penetration and contact pressure dynamics between a wavy punch and an adhesive-coated body, the study focuses on the influence of adhesive layer thickness, elasticity modulus, and punch geometry on mechanical behavior. The study includes the application of Green's function to address deficiencies in existing models, revealing how contact stiffness, influenced by the flexibility relationship between the coating and substrate, affects the size of the contact area. Finally, conclusions are drawn that adjusting coating factors can induce full contact conditions. Quantitative analysis shows a 2.23-fold increase in load-bearing capacity with a 2 mm increase in adhesive layer thickness, and a 23-fold increase with a toughness ratio rise from 0.1 to 5. These findings are recommended for optimizing adhesive layer properties, contributing to advancements in materials science and innovation. [ABSTRACT FROM AUTHOR]

Published

2024

46. Three-Loop Divergences in Effective Action of 4-Dimensional Yang–Mills Theory with Cutoff Regularization: Γ42-Contribution.

Author

Ivanov, A. V. and Kharuk, N. V.

Subjects

*GREEN'S functions

Abstract

In the paper, we study three-loop divergences in the effective action of the four-dimensional Yang–Mills theory from the Γ 4 2 -contribution. As a regularization we use a cutoff (deformation of the Green's function) in the coordinate representation. [ABSTRACT FROM AUTHOR]

Published

2024

47. Horizontal well hydraulics in leaky confined aquifer near a stream: analytical solutions for induced drawdown and water budget components.

Author

Mahdavi, Ali

Subjects

GREEN'S functions, STEADY-state flow, INTEGRAL transforms, WATER levels, ANALYTICAL solutions, HORIZONTAL wells

Abstract

Horizontal wells have gained popularity as a technology for exploring water resources and remediating aquifers over the last decades, due to costs and numerous technical benefits compared to traditional vertical wells. This study presents a set of analytical solutions for drawdown distribution and various components of water budget contributing to flow toward a horizontal well in an aquifer-aquitard system interacting with a fully penetrating stream. It is assumed that the water level in the upper unconfined aquifer remains fixed at a specific elevation during the course of the pumping in the lower leaky aquifer. The water budget components account for inflows from aquifer storage, stream depletion, and leakage across the aquifer-aquitard interface. Analytical solutions to this three-dimensional, transient, non-axisymmetric Darcian flow model are given for both transient and steady-state flow conditions, relying on a four-fold integral transform technique that includes a Robin-type boundary condition at the aquifer-aquitard interface. It is shown how various components of water budget collectively counterbalance the effect of pumping discharge, confirming that the mass is conserved under both continuous and non-continuous pumping scenarios. Response maps are prepared to assess how different components of water budget react to changes in the well position. Furthermore, it is found that the components of water budget are most sensitive to the well-to-stream distance and anisotropy ratio of the leaky aquifer. [ABSTRACT FROM AUTHOR]

Published

2024

48. Rational Design of High-Performance Photocontrolled Molecular Switches Based on Chiroptical Dimethylcethrene: A Theoretical Study.

Author

Han, Li, Wang, Mei, Zhang, Yifan, Cui, Bin, and Liu, Desheng

Subjects

*GREEN'S functions, *MOLECULAR switches, *DENSITY functional theory, *SINGLE molecules, *ELECTRIC conductivity, *IRRADIATION

Abstract

The reversible photo-induced conformation transition of a single molecule with a [5]helicene backbone has garnered considerable interest in recent studies. Based on such a switching process, one can build molecular photo-driven switches for potential applications of nanoelectronics. But the achievement of high-performance reversible single-molecule photoswitches is still rare. Here, we theoretically propose a 13,14-dimethylcethrene switch whose photoisomerization between the ring-closed and ring-open forms can be triggered by ultraviolet (UV) and visible light irradiation. The electronic structure transitions and charge transport characteristics, concurrent with the photo-driven electrocyclization of the molecule, are calculated by the non-equilibrium Green's function (NEGF) in combination with density functional theory (DFT). The electrical conductivity bears great diversity between the closed and open configurations, certifying the switching behavior and leading to a maximum on–off ratio of up to 103, which is considerable in organic junctions. Further analysis confirms the evident switching behaviors affected by the molecule–electrode interfaces in molecular junctions. Our findings are helpful for the rational design of organic photoswitches at the single-molecule level based on cethrene and analogous organic molecules. [ABSTRACT FROM AUTHOR]

Published

2024

49. Optimal Arrangements and Local Anisotropy of {100} Guinier–Preston (GP) Zones by Parametric Dislocation Dynamics (PDD) Simulations.

Author

Zheng, Haiwei, Liu, Jianbin, and Muraishi, Shinji

Subjects

*GREEN'S functions, *EDGE dislocations, *LINE integrals, *ANISOTROPY, *BLOOD platelets

Abstract

Stress-oriented precipitation and the resulting mechanical anisotropy have been widely studied over the decades. However, the local anisotropy of precipitates with specific orientations has been less thoroughly investigated. This study models the interaction between an edge dislocation source and {100} variants of Guinier–Preston (GP) zones in Al-Cu alloys using the parametric dislocation dynamics (PDD) method. Concentric geometrically necessary dislocation (GND) loops were employed to construct a line integral model for thin platelets. The simulations, conducted with our self-developed code based on Green's function method and Eshelby inclusion theory revealed distinct strengthening behavior along the strong and weak directions for 60° GP zones, demonstrating anisotropic strengthening from the perspective of elastic interactions. Furthermore, the optimal inclined arrangement of the GP zone array was determined through elastic energy calculations, and these results were corroborated by TEM observations. [ABSTRACT FROM AUTHOR]

Published

2024

50. Parametric Study on the Effect of Rail Dampers on Track Decay Rate.

Author

Fologea, Dorina, Mazilu, Traian, Gheți, Marius-Alin, and Apostol, Ioana-Izabela

Subjects

GREEN'S functions, STREET railroads, NOISE, RAILROADS, POSSIBILITY

Abstract

Track decay rate (TDR), meaning the rate of attenuation of bending waves through the rail, is the most important indicator of a track's dynamic characteristic impacting the rail noise emission. TDR depends on various parameters related to the construction of the track, and it can be increased using rail dampers. These are mechanical devices working on the principle of dynamic absorbers and are attached to the rail. This paper addresses the track with light rails needing improvements to reduce the rail noise emission using a particular rail damper with a mixed damping system (rubber–oil). The bending waves that propagate through the rail, the frequency response function of the rail, and TDR are investigated considering different scenarios regarding the parameters of the track: soft/stiff rail pad, tampered/settled ballast, and sleeper bay. To this end, an analytic model of the track featuring rail dampers consisting of an infinite Timoshenko beam with discrete attached oscillators is used. Numerical results show the possibility to increase TDR of railway track with light rails for both soft/stiff rail pads from 4 to 500 Hz up to 1250–1600 Hz using rail dampers with a mixed damping system. [ABSTRACT FROM AUTHOR]

Published

2024