Hamiltonian Transformation for Band Structure Calculations

First-principles electronic band structure calculations are essential for understanding periodic systems in condensed matter physics and materials science. We propose an accurate and parameter-free method, called Hamiltonian transformation (HT), to calculate band structures in both density functional theory (DFT) and post-DFT calculations with plane-wave basis sets. The cost of HT is independent of the choice of the density functional and scales as $\mathcal{O}(N_e^3N_k\log N_k)$, where $N_e$ and $N_k$ are the number of electrons and the number of $\mathbf{k}$-points. Compared to the widely used Wannier interpolation (WI), HT adopts an eigenvalue transformation to construct a spatial localized representation of the spectrally truncated Hamiltonian. HT also uses a non-iterative algorithm to change the basis sets to circumvent the construction of the maximally localized Wannier functions. As a result, HT can significantly outperform WI in terms of the accuracy of the band structure calculation. We also find that the eigenvalue transformation can be of independent interest, and can be used to improve the accuracy of the WI for systems with entangled bands.Comment: 5 pages, 4 figure

Observation of polarity-switchable photoconductivity in III-nitride/MoSx core-shell nanowires

A novel polarity-switchable photoelectrochemical photodetector based on III-nitride/MoSxcore-shell nanowires is constructed. Such unique device architecture provides a new route for multiple-band spectrally distinctive photodetection