First-principles calculation of shift current in chalcopyrite semiconductor ZnSnP2

Banasree Sadhukhan; Yang Zhang; Rajyavardhan Ray; Jeroen Van Den Brink

doi:10.1103/PhysRevMaterials.4.064602

First-principles calculation of shift current in chalcopyrite semiconductor ZnSnP2

Banasree Sadhukhan
, Yang Zhang
, Rajyavardhan Ray
, Jeroen Van Den Brink

Materials Theory

Research output: Contribution to journal › Article › peer-review

24 Scopus citations

Abstract

The bulk photovoltaic effect generates intrinsic photocurrents in materials without inversion symmetry. Shift current is one of the bulk photovoltaic phenomena related to the Berry phase of the constituting electronic bands: photoexcited carriers coherently shift in real space due to the difference in the Berry connection between the valence and conduction bands. Ferroelectric semiconductors and Weyl semimetals are known to exhibit such nonlinear optical phenomena. Here we consider the chalcopyrite semiconductor ZnSnP2, which lacks inversion symmetry, and calculate the shift-current conductivity. We find that the magnitude of the shift current is comparable to the recently measured values on other ferroelectric semiconductors and an order of magnitude larger than bismuth ferrite. The peak response for both optical and shift-current conductivity, which mainly comes from P-3p and Sn-5p orbitals, is several eV above the band gap.

Original language	English
Article number	064602
Journal	Physical Review Materials
Volume	4
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevMaterials.4.064602
State	Published - Jun 2020

Funding

We thank Manuel Richter for helpful discussions and Ulrike Nitzsche for technical assistance. This work was supported by the German Research Foundation (DFG) via Grant No. SFB 1143, Project No. A5 and by the Würzburg-Dresden Cluster of Excellence on Complexity and Topology in Quantum Matter — ct.qmat (EXC 2147, Project No. 39085490).

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title = "First-principles calculation of shift current in chalcopyrite semiconductor ZnSnP2",

abstract = "The bulk photovoltaic effect generates intrinsic photocurrents in materials without inversion symmetry. Shift current is one of the bulk photovoltaic phenomena related to the Berry phase of the constituting electronic bands: photoexcited carriers coherently shift in real space due to the difference in the Berry connection between the valence and conduction bands. Ferroelectric semiconductors and Weyl semimetals are known to exhibit such nonlinear optical phenomena. Here we consider the chalcopyrite semiconductor ZnSnP2, which lacks inversion symmetry, and calculate the shift-current conductivity. We find that the magnitude of the shift current is comparable to the recently measured values on other ferroelectric semiconductors and an order of magnitude larger than bismuth ferrite. The peak response for both optical and shift-current conductivity, which mainly comes from P-3p and Sn-5p orbitals, is several eV above the band gap.",

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AU - Ray, Rajyavardhan

AU - Van Den Brink, Jeroen

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AB - The bulk photovoltaic effect generates intrinsic photocurrents in materials without inversion symmetry. Shift current is one of the bulk photovoltaic phenomena related to the Berry phase of the constituting electronic bands: photoexcited carriers coherently shift in real space due to the difference in the Berry connection between the valence and conduction bands. Ferroelectric semiconductors and Weyl semimetals are known to exhibit such nonlinear optical phenomena. Here we consider the chalcopyrite semiconductor ZnSnP2, which lacks inversion symmetry, and calculate the shift-current conductivity. We find that the magnitude of the shift current is comparable to the recently measured values on other ferroelectric semiconductors and an order of magnitude larger than bismuth ferrite. The peak response for both optical and shift-current conductivity, which mainly comes from P-3p and Sn-5p orbitals, is several eV above the band gap.

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First-principles calculation of shift current in chalcopyrite semiconductor ZnSnP2

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