Your search keyword '"Bhattarai, Romakanta"' showing total 33 results

1. Phosphorus Nanotubes from Chemical Cleavage

Author

Bhattarai, Romakanta and Shen, Xiao

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We propose a strategy to make phosphorus nanotubes from two well-known phosphorus allotropes: violet phosphorus and red phosphorus. First-principles calculations show that doping with sulfur dissociates the covalent bonds between tubular phosphorus structures that form bilayers in these allotropes, resulting in free-standing 1D nanotubes. Due to the substitutional nature of the sulfur dopant, the resulting 1D structure is linear, unlike the helical ring structure studied previously. The sulfur sites are situated periodically along the 1D nanotubes and can be further functionalized. Our results show that the S-doped phosphorus nanotube can sustain a tensile strain of up to 18%. The strain also substantially modifies the electronic band gap and the effective mass of carriers. Calculations using the many-body Green's functions (GW) and the Bethe-Salpeter equation (BSE) approaches reveal a large exciton binding energy of 1.57 eV. The one-dimensional nature, linearity, functionalizability, mechanical flexibility, tunability of electronic properties, and large exciton binding energy make this material interesting for applications in optoelectronic devices, solar cells, chemical sensors, and quantum computing.

Published

2024

2. Ferroelectric 2D Antimony Oxides with Wide Bandgaps

Author

Bhattarai, Romakanta, Ni, Kai, and Shen, Xiao

Subjects

Condensed Matter - Materials Science

Abstract

The first two-dimensional (2D) polymorphs of antimony dioxide, namely, $\gamma$-Sb$_2$O$_4$ and $\delta$-Sb$_2$O$_4$, are predicted using the evolutionary algorithm combined with first-principles density functional theory (DFT) calculations. Out-of-plane ferroelectricity is found in $\gamma$-Sb$_2$O$_4$, while in-plane ferroelectricity is found in $\delta$-Sb$_2$O$_4$. The predicted dipole moments of $\gamma$-Sb$_2$O$_4$ and $\delta$-Sb$_2$O$_4$ phases are 36.63 and 14.96 e\r{A}, respectively, implying that they can be good candidates for making ferroelectric devices. The calculations show that doping with other group V elements or applying strain can lower the switching energy barriers and thus facilitate switching. Results from GW calculations show indirect band gaps of 5.51 and 3.39 eV for $\gamma$-Sb$_2$O$_4$ and $\delta$-Sb$_2$O$_4$ in their monolayers, respectively. Raman spectra are calculated to facilitate the experimental investigation of the predicted structures. The existence of both in-plane and out-of-plane 2D ferroelectricity and the large band gaps make this material system particularly interesting for potential applications.

Published

2022

3. Optical and Electronic Properties of SiTe_x(x=1,2) from First-Principles

Author

Bhattarai, Romakanta and Shen, Xiao

Subjects

Condensed Matter - Materials Science

Abstract

The optical and electronic properties of the {\alpha}-SiTe, {\beta}-SiTe, and RX-SiTe_2 are investigated. A detailed analysis of electronic properties is done using standard density functional theory (DFT) and hybrid functional (HSE06) methods. The optical dielectric properties are studied under three different methods: standard DFT, many-body Green's functions (GW), and Bethe-Salpeter equation (BSE). Our calculations show that the SiTe compounds possess extremely high static dielectric constants in their bulk forms ({\epsilon}_0({\bot}) = 68.58, {\epsilon}_0({\parallel}) = 127.29 for {\alpha}-SiTe, and {\epsilon}_0({\bot}) = 76.23, {\epsilon}_0({\parallel}) = 98.15 for {\beta}-SiTe). The frequency-dependent dielectric functions Im({\epsilon}) have very large values (>100) in the optical regime, which are among the highest of layered materials, suggesting them as excellent light absorbents in the corresponding frequencies. {\alpha}-SiTe exhibits a high degree of optical anisotropy as compared to the other two compounds, consistent with their structural configurations. A strong interlayer excitonic effect is observed in bulk RX-SiTe_2. In addition, an analysis of Raman intensity is also performed.

Published

2021

4. Pressure-Induced Insulator-Metal Transition in Silicon Telluride from First-Principles Calculations

Author

Bhattarai, Romakanta and Shen, Xiao

Subjects

Condensed Matter - Materials Science

Abstract

Silicon telluride (Si2Te3) is a two-dimensional semiconductor with unique structural properties due to the size contrast between Si and Te atoms. A recent experiment shows that the material turns metallic under hydrostatic pressure, while the lattice structure of the metallic phase remains to be identified. In this paper, we propose two metallic phases, M1 and M2, of Si2Te3 using the evolution algorithm and first-principles density functional theory (DFT) calculations. Unlike the presence of Si-Si dimers in the semiconducting (SC) phase, both M1 and M2 phases have individual Si atoms, which play important roles in the metallicity. Analysis of structural properties, electronic properties, dynamical as well as thermal stability is performed. The energies of these new structures are compared with the SC phase under the subsequent hydrostatic pressure up to 12 GPa. The results show that M1 and M2 phases have lower energies under high pressure, thus elucidating the appearance of the metallic phase of Si2Te3. In addition, the external pressure causes the SC phase to have an indirect-direct-indirect bandgap transition. Analysis of Raman spectra of the SC phase at a different pressure shows the shifting of the major Raman peaks, and finally disappearing confirms the phase transition. The results are in good agreement with the experimental observations. The understanding of the insulator-metal phase transition increases the potential usefulness of the material system.

Published

2021

5. Temperature- and Polarization- Dependent Optical Properties of Single Si2Te3 Nanoplates

Author

Chen, Jiyang, Bhattarai, Romakanta, Cui, Jingbiao, Shen, Xiao, and Hoang, Thang

Subjects

Condensed Matter - Materials Science, Physics - Optics

Abstract

We report a combined experimental and computational study of the optical properties of individual silicon telluride (Si2Te3) nanoplates. The p-type semiconductor Si2Te3 has a unique layered crystal structure with hexagonal closed-packed Te sublattices and Si-Si dimers occupying octahedral intercalation sites. The orientation of the silicon dimers leads to unique optical and electronic properties. Two-dimensional Si2Te3 nanoplates with thicknesses of hundreds of nanometers and lateral sizes of tens of micrometers are synthesized by a chemical vapor deposition technique. At temperatures below 150 K, the Si2Te3 nanoplates exhibit a direct band structure with a band gap energy of 2.394 eV at 7 K and an estimated free exciton binding energy of 150 meV. Polarized reflection measurements at different temperatures show anisotropy in the absorption coefficient due to an anisotropic orientation of the silicon dimers, which is in excellent agreement with theoretical calculations of the dielectric functions. Polarized Raman measurements of single Si2Te3 nanoplates at different temperatures reveal various vibrational modes, which agree with density functional perturbation theory calculations. The unique structural and optical properties of nanostructured Si2Te3 hold great potential applications in optoelectronics and chemical sensing., Comment: 19 pages, 6 Figures

Published

2020

6. Predicting A Novel Phase of 2D SiTe$_2$

Author

Bhattarai, Romakanta and Shen, Xiao

Subjects

Condensed Matter - Materials Science

Abstract

Layered IV-VI$_2$ compounds often exist in the CdI$_2$ structure. Using the evolution algorithm and first-principles calculations, we predict a novel layered structure of silicon ditelluride (SiTe$_2$) that is more stable than the CdI$_2$ phase. The structure has a triclinic unit cell in its bulk form and exhibits the competition between the Si atoms' tendency to form tetrahedral bonds and the Te atoms' tendency to form hexagonal close-packing. The electronic and vibrational properties of the predicted phase are investigated. The effective mass of electron is small among 2D semiconductors, which is beneficial for applications such as field-effect transistors. The vibrational Raman and IR spectra are calculated to facilitate future experimental investigations

Published

2020

7. Tunable magnetic and magnetocaloric properties of scandium doped Gd3Fe5-xScxO12 garnet compound

Author

Sultana, Jolaikha, Mohapatra, Jeotikanta, Bhattarai, Romakanta, Ping Liu, J., David Rhone, Trevor, and Mishra, Sanjay R.

Published

2023

8. Data-driven study of magnetic anisotropy in transition metal dichalcogenide monolayers

Author

Minch, Peter, Bhattarai, Romakanta, and Rhone, Trevor David

Published

2023

9. Ultra-High Mechanical Flexibility of 2D Silicon Telluride

Author

Bhattarai, Romakanta and Shen, Xiao

Subjects

Condensed Matter - Materials Science

Abstract

Silicon telluride (Si2Te3) is a two-dimensional material with a unique variable structure where the silicon atoms form Si-Si dimers to fill the "metal" sites between the Te layers. The Si-Si dimers have four possible orientations: three in-plane and one out-of-the plane directions. The structural variability of Si2Te3 allows unusual properties especially the mechanical properties. Using results from first-principles calculations, we show that the Si2Te3 monolayer can sustain a uniaxial tensile strain up to 38%, highest among all two-dimensional materials reported. The high mechanical flexibility allows applying mechanical strain to reduce the band gap by 1.4 eV. With increasing strain, the band gap undergoes an unusual indirect-direct-indirect-direct transition. We also show that the uniaxial strain can effectively control the Si-Si dimer alignment, which is beneficial for practical applications.

Published

2019

10. Anisotropic Optical Properties of 2D Silicon Telluride From Ab Initio Calculations

Author

Bhattarai, Romakanta and Shen, Xiao

Subjects

Condensed Matter - Materials Science

Abstract

Silicon telluride (Si2Te3) is a silicon-based 2D chalcogenide with potential applications in optoelectronics. It has a unique crystal structure where Si atoms form Si-Si dimers to occupy the "metal" sites. In this paper, we report an ab initio computational study of its optical dielectric properties using the GW approximation and the Bethe-Salpeter equation (BSE). Strong optical anisotropy is discovered. The imaginary part of the dielectric constant in the direction parallel to the Si-Si dimers is found to be much lower than that perpendicular to the dimers. We show this effect originates from the particular compositions of the wavefunctions in the valence and conduction bands. BSE calculations reduce GW quasiparticle band gap by 0.3 eV in bulk and 0.6 eV in monolayer, indicating a large excitonic effect in Si2Te3. Furthermore, including electron-hole interaction in bulk calculations significantly reduces the imaginary part of the dielectric constant in the out-of-plane direction, suggesting strong interlayer exciton effect in Si2Te3 multilayers.

Published

2019

11. Enhanced magnetocaloric effect in aluminum doped Gd3Fe5-xAlxO12 garnet: Structural, magnetic, and Mössbauer study

Author

Neupane, Dipesh, Hulsebosch, Liam, Ali, K.S. Syed, Bhattarai, Romakanta, Shen, Xiao, Pathak, Arjun K., and Mishra, Sanjay R.

Published

2022

12. Exploring Bonding Configurations in MnBi2Te4-Type Materials

Author

Bhattarai, Romakanta and Rhone, Trevor David

Abstract

We perform a systematic investigation of several crystal structures, based on monolayer MnBi2Te4, of the form MnBiBiiXi2Xii2using first-principles calculations. Our analysis shows that the most energetically favorable bonding configuration of the constituent elements in monolayer MnBiBiiXi2Xii2is determined by the bond length between the Mn atom and its nearest X-site atoms. Tuning the bonding configuration of the material alters the magnetic, electronic, and topological properties. We also calculate the magnetic exchange parameters and magnetic anisotropy energy of the predicted structures. The calculations show that the elements at the X sites mainly determine the magnetic properties. Finally, we propose a stable phase of monolayer MnBi2S2Te2(i.e., γ-MnBi2S2Te2) that exhibits the quantum anomalous Hall effect (QAHE). This study demonstrates that the bonding configuration of MnBi2Te4-type materials provides avenues for tuning the magnetic, electronic, and topological properties of van der Waals (vdW) materials.

Published

2024

13. Strain-induced topological phase transition in ferromagnetic Janus monolayer MnSbBiS2Te2

Author

Bhattarai, Romakanta, primary, Minch, Peter, additional, Liang, Yunfan, additional, Zhang, Shengbai, additional, and Rhone, Trevor David, additional

Published

2024

14. Anisotropic Optical Properties of 2D Silicon Telluride

Author

Bhattarai, Romakanta, Chen, Jiyang, Hoang, Thang B., Cui, Jingbiao, and Shen, Xiao

Published

2020

15. Effect of Dual-Organic Cations on the Structure and Properties of 2D Hybrid Perovskites as Scintillators.

Author

Kuddus Sheikh, Md Abdul, Maddalena, Francesco, Kowal, Dominik, Makowski, Michal, Mahato, Somnath, Jȩdrzejewski, Roman, Bhattarai, Romakanta, Witkowski, Marcin Eugeniusz, Drozdowski, Konrad Jacek, Drozdowski, Winicjusz, Dang, Cuong, Rhone, Trevor David, and Birowosuto, Muhammad Danang

Published

2024

16. Strain-induced topological phase transition in ferromagnetic Janus monolayer MnSbBiS2Te2.

Author

Bhattarai, Romakanta, Minch, Peter, Liang, Yunfan, Zhang, Shengbai, and Rhone, Trevor David

Abstract

We investigate a strain-induced topological phase transition in the ferromagnetic Janus monolayer MnSbBiS2Te2 using first-principles calculations. The electronic, magnetic, and topological properties are studied under biaxial strain within the range of −8 to +8%. The ground state of monolayer MnSbBiS2Te2 is metallic with an out-of-plane magnetic easy axis. A band gap is opened when a compressive strain between −4% and −7% is applied. We observe a topological phase transition at a biaxial strain of −5%, where the material becomes a Chern insulator exhibiting a quantum anomalous hall (QAH) effect. We find that biaxial strain and spin–orbit coupling (SOC) are responsible for the topological phase transition in MnSbBiS2Te2. In addition, we find that biaxial strain can alter the direction of the magnetic easy axis of MnSbBiS2Te2. The Curie temperature is calculated using the Heisenberg model and is found to be 24 K. This study could pave the way to the design of topological materials with potential applications in spintronics, quantum computing, and dissipationless electronics. [ABSTRACT FROM AUTHOR]

Published

2024

17. Anisotropic optical properties of single Si2Te3 nanoplates

Author

Chen, Jiyang, Bhattarai, Romakanta, Cui, Jingbiao, Shen, Xiao, and Hoang, Thang

Published

2020

18. Rare-Earth Doped Gd 3− x RE x Fe 5 O 12 (RE = Y, Nd, Sm, and Dy) Garnet: Structural, Magnetic, Magnetocaloric, and DFT Study.

Author

Neupane, Dipesh, Kramer, Noah, Bhattarai, Romakanta, Hanley, Christopher, Pathak, Arjun K., Shen, Xiao, Karna, Sunil, and Mishra, Sanjay R.

Subjects

GARNET, SAMARIUM, RARE earth metals, MAGNETIC entropy, BOND angles, MAGNETIZATION measurement, LATTICE constants

Abstract

The study reports the influence of rare-earth ion doping on the structural, magnetic, and magnetocaloric properties of ferrimagnetic Gd3−xRExFe5O12 (RE = Y, Nd, Sm, and Dy, x = 0.0, 0.25, 0.50, and 0.75) garnet compound prepared via facile autocombustion method followed by annealing in air. X-Ray diffraction (XRD) data analysis confirmed the presence of a single-phase garnet. The compound's lattice parameters and cell volume varied according to differences in ionic radii of the doped rare-earth ions. The RE3+ substitution changed the site-to-site bond lengths and bond angles, affecting the magnetic interaction between site ions. Magnetization measurements for all RE3+-doped samples demonstrated paramagnetic behavior at room temperature and soft-ferrimagnetic behavior at 5 K. The isothermal magnetic entropy changes (−ΔSM) were derived from the magnetic isotherm curves, M vs. T, in a field up to 3 T in the Gd3−xRExFe5O12 sample. The maximum magnetic entropy change ( − ∆ S M m a x ) increased with Dy3+ and Sm3+substitution and decreased for Nd3+ and Y3+ substitution with x content. The Dy3+-doped Gd2.25Dy0.75Fe5O12 sample showed − ∆ S M m a x ~2.03 Jkg−1K−1, which is ~7% higher than that of Gd3Fe5O12 (1.91 Jkg−1K−1). A first-principal density function theory (DFT) technique was used to shed light on observed properties. The study shows that the magnetic moments of the doped rare-earths ions play a vital role in tuning the magnetocaloric properties of the garnet compound. [ABSTRACT FROM AUTHOR]

Published

2023

19. Artificial Intelligence Guided Studies of van der Waals Magnets

Author

Rhone, Trevor David, primary, Bhattarai, Romakanta, additional, Gavras, Haralambos, additional, Lusch, Bethany, additional, Salim, Misha, additional, Mattheakis, Marios, additional, Larson, Daniel T., additional, Krockenberger, Yoshiharu, additional, and Kaxiras, Efthimios, additional

Published

2023

20. Optical and electronic properties of SiTex (x = 1, 2) from first-principles.

Author

Bhattarai, Romakanta and Shen, Xiao

Subjects

OPTICAL properties, GREEN'S functions, PERMITTIVITY, BETHE-Salpeter equation, DIELECTRIC function

Abstract

The optical and electronic properties of α-SiTe, β-SiTe, and RX-SiTe2 are investigated. A detailed analysis of electronic properties is done using standard density functional theory (DFT) and hybrid functional methods. The static dielectric properties are investigated using the density functional perturbation theory method. The optical properties are studied under three different methods: standard DFT, many-body Green's functions, and the Bethe–Salpeter equation. Our calculations show that the SiTe compounds possess extremely high static dielectric constants in their bulk forms [ε0(⊥) = 68.58 and ε0(‖) = 127.29 for α-SiTe, and ε0(⊥) = 76.23 and ε0(‖) = 74.61 for β-SiTe]. The frequency-dependent dielectric functions Im(ε) have very large values (>100) in the optical regime, which are among the highest of layered materials, suggesting them as excellent light absorbents in the corresponding frequencies. α-SiTe exhibits a high degree of optical anisotropy as compared to the other two compounds, consistent with their structural configurations. A strong interlayer excitonic effect is observed in bulk RX-SiTe2. In addition, an analysis of Raman intensity is also performed. [ABSTRACT FROM AUTHOR]

Published

2021

21. Data-Driven Study of Magnetic Anisotropy in Transition Metal Dichalcogenide Monolayers

Author

Minch, Peter, primary, Bhattarai, Romakanta, additional, and Rhone, Trevor David, additional

Published

2023

22. Investigating magnetic van der Waals materials using data- driven approaches

Author

Bhattarai, Romakanta, primary, Minch, Peter, additional, and Rhone, Trevor, additional

Published

2023

23. Enhanced magnetocaloric effect in aluminum doped Gd3Fe5-Al O12 garnet: Structural, magnetic, and Mössbauer study

Author

Neupane, Dipesh, primary, Hulsebosch, Liam, additional, Ali, K.S. Syed, additional, Bhattarai, Romakanta, additional, Shen, Xiao, additional, Pathak, Arjun K., additional, and Mishra, Sanjay R., additional

Published

2022

24. Ferroelectric 2D antimony oxides with wide bandgaps

Author

Bhattarai, Romakanta, primary, Ni, Kai, additional, and Shen, Xiao, additional

Published

2022

25. Electrochemical Performance of Iron-Doped Cobalt Oxide Hierarchical Nanostructure

Author

Guragain, Deepa, primary, Karna, Sunil, additional, Choi, Jonghyun, additional, Bhattarai, Romakanta, additional, Poudel, Tej P., additional, Gupta, Ram Krishna, additional, Shen, Xiao, additional, and Mishra, Sanjay R., additional

Published

2021

26. Electrochemical Performance of Aluminum Doped Ni1−xAlxCo2O4 Hierarchical Nanostructure: Experimental and Theoretical Study

Author

Guragain, Deepa, primary, Bhattarai, Romakanta, additional, Choi, Jonghyun, additional, Lin, Wang, additional, Gupta, Ram Krishna, additional, Shen, Xiao, additional, Perez, Felio A., additional, and Mishra, Sanjay R., additional

Published

2021

27. Pressure-Induced Insulator–Metal Transition in Silicon Telluride from First-Principles Calculations

Author

Bhattarai, Romakanta, primary and Shen, Xiao, additional

Published

2021

28. Predicting a Novel Phase of 2D SiTe2

Author

Bhattarai, Romakanta, primary and Shen, Xiao, additional

Published

2020

29. Ultra-high mechanical flexibility of 2D silicon telluride

Author

Bhattarai, Romakanta, primary and Shen, Xiao, additional

Published

2020

30. Predicting a Novel Phase of 2D SiTe2.

Author

Bhattarai, Romakanta and Shen, Xiao

Published

2020

31. Electrochemical Performance of Aluminum Doped Ni 1−x Al x Co 2 O 4 Hierarchical Nanostructure: Experimental and Theoretical Study.

Author

Guragain, Deepa, Bhattarai, Romakanta, Choi, Jonghyun, Lin, Wang, Gupta, Ram Krishna, Shen, Xiao, Perez, Felio A., and Mishra, Sanjay R.

Subjects

CARBON dioxide, ENERGY density, ENERGY storage, ENERGY bands, ELECTRODE performance

Abstract

For electrochemical supercapacitors, nickel cobaltite (NiCo2O4) has emerged as a new energy storage material. The electrocapacitive performance of metal oxides is significantly influenced by their morphology and electrical characteristics. The synthesis route can modulate the morphological structure, while their energy band gaps and defects can vary the electrical properties. In addition to modifying the energy band gap, doping can improve crystal stability and refine grain size, providing much-needed surface area for high specific capacitance. This study evaluates the electrochemical performance of aluminum-doped Ni1−xAlxCo2O4 (0 ≤ x ≤ 0.8) compounds. The Ni1−xAlxCo2O4 samples were synthesized through a hydrothermal method by varying the Al to Ni molar ratio. The physical, morphological, and electrochemical properties of Ni1−xAlxCo2O4 are observed to vary with Al3+ content. A morphological change from urchin-like spheres to nanoplate-like structures with a concomitant increase in the surface area, reaching up to 189 m2/g for x = 0.8, was observed with increasing Al3+ content in Ni1−xAlxCo2O4. The electrochemical performance of Ni1−xAlxCo2O4 as an electrode was assessed in a 3M KOH solution. The high specific capacitance of 512 F/g at a 2 mV/s scan rate, 268 F/g at a current density of 0.5 A/g, and energy density of 12.4 Wh/kg was observed for the x = 0.0 sample, which was reduced upon further Al3+ substitution. The as-synthesized Ni1−xAlxCo2O4 electrode exhibited a maximum energy density of 12.4 W h kg−1 with an outstanding high-power density of approximately 6316.6 W h kg−1 for x = 0.0 and an energy density of 8.7 W h kg−1 with an outstanding high-power density of approximately 6670.9 W h kg−1 for x = 0.6. The capacitance retention of 97% and 108.52% and the Coulombic efficiency of 100% and 99.24% were observed for x = 0.0 and x = 0.8, respectively. First-principles density functional theory (DFT) calculations show that the band-gap energy of Ni1−xAlxCo2O4 remained largely invariant with the Al3+ substitution for low Al3+ content. Although the capacitance performance is reduced upon Al3+ doping, overall, the Al3+ doped Ni1−xAlxCo2O4 displayed good energy, powder density, and retention performance. Thus, Al3+ could be a cost-effective alternative in replacing Ni with the performance trade off. [ABSTRACT FROM AUTHOR]

Published

2021

32. Anisotropic optical properties of single Si2Te3 nanoplates.

Author

Chen, Jiyang, Bhattarai, Romakanta, Cui, Jingbiao, Shen, Xiao, and Hoang, Thang

Subjects

*OPTICAL properties, *SILICON, *CHEMICAL vapor deposition, *P-type semiconductors, *OPTOELECTRONICS

Abstract

We report a combined experimental and computational study of the optical properties of individual silicon telluride (Si2Te3) nanoplates. The p-type semiconductor Si2Te3 has a unique layered crystal structure with hexagonal closed-packed Te sublattices and Si–Si dimers occupying octahedral intercalation sites. The orientation of the silicon dimers leads to unique optical and electronic properties. Two-dimensional Si2Te3 nanoplates with thicknesses of hundreds of nanometers and lateral sizes of tens of micrometers are synthesized by a chemical vapor deposition technique. At temperatures below 150 K, the Si2Te3 nanoplates exhibit a direct band structure with a band gap energy of 2.394 eV at 7 K and an estimated free exciton binding energy of 150 meV. Polarized reflection measurements at different temperatures show anisotropy in the absorption coefficient due to an anisotropic orientation of the silicon dimers, which is in excellent agreement with theoretical calculations of the dielectric functions. Polarized Raman measurements of single Si2Te3 nanoplates at different temperatures reveal various vibrational modes, which agree with density functional perturbation theory calculations. The unique structural and optical properties of nanostructured Si2Te3 hold great potential applications in optoelectronics and chemical sensing. [ABSTRACT FROM AUTHOR]

Published

2020

33. Exploring Bonding Configurations in MnBi 2 Te 4 -Type Materials.

Author

Bhattarai R and Rhone TD

Abstract

We perform a systematic investigation of several crystal structures, based on monolayer MnBi 2 Te 4 , of the form MnB i B ii X i 2 X ii 2 using first-principles calculations. Our analysis shows that the most energetically favorable bonding configuration of the constituent elements in monolayer MnB i B ii X i 2 X ii 2 is determined by the bond length between the Mn atom and its nearest X-site atoms. Tuning the bonding configuration of the material alters the magnetic, electronic, and topological properties. We also calculate the magnetic exchange parameters and magnetic anisotropy energy of the predicted structures. The calculations show that the elements at the X sites mainly determine the magnetic properties. Finally, we propose a stable phase of monolayer MnBi 2 S 2 Te 2 (i.e., γ-MnBi 2 S 2 Te 2 ) that exhibits the quantum anomalous Hall effect (QAHE). This study demonstrates that the bonding configuration of MnBi 2 Te 4 -type materials provides avenues for tuning the magnetic, electronic, and topological properties of van der Waals (vdW) materials.

Published

2024