Unified theory of direct or indirect band-gap nature of conventional semiconductors

Dec 1, 2018·
Linding Yuan
Linding Yuan
,
Hui-Xiong Deng
,
Shu-Shen Li
,
Su-Huai Wei
,
Jun-Wei Luo
· 0 min read
Abstract
Although the direct or indirect nature of the bandgap transition is an essential parameter of semiconductors for optoelectronic applications, the understanding why some of the conventional semiconductors have direct or indirect bandgaps remains ambiguous. In this Letter, we revealed that the existence of the occupied cation d bands is a prime element in determining the directness of the bandgap of semiconductors through the s–d and p–d couplings, which push the conduction band energy levels at the X- and L-valley up, but leaves the Γ-valley conduction state unchanged. This unified theory unambiguously explains why Diamond, Si, Ge, and Al-containing group III–V semiconductors, which do not have active occupied d bands, have indirect bandgaps and remaining common semiconductors, except GaP, have direct bandgaps. Besides s–d and p–d couplings, bond length and electronegativity of anions are two remaining factors regulating the energy ordering of the Γ-, X-, and L-valley of the conduction band, and are responsible for the anomalous bandgap behaviors in GaN, GaP, and GaAs that have direct, indirect, and direct bandgaps, respectively, despite the fact that N, P, and As are in ascending order of the atomic number. This understanding will shed light on the design of new direct bandgap light-emitting materials.
Type
Publication
Physical Review B 98, 245203 (2018)
publications
Linding Yuan
Authors

I develop predictive theories of condensed matter materials and propose them for experimentalists to make. My work pairs first-principles calculations with symmetry analysis to discover new classes of materials with interesting electronic and magnetic properties. Specific material class of interests include semicondcutors and ferroic materials. My recent interest extends to integrating these methods into agentic workflows to accelerate materials discovery.

I moved to Evanston in May 2023 to join the Rondinelli Group at Northwestern University as a research associate.