全网所有网赌网址大全-澳门十大网赌排行榜-信誉认证
简体中文
English
Home
About us
Research
Faculty
Graduate
Admission
Join Us
Open Class
Home
>
Open Class
>
Content
【Lecture】Electronic Band Structures from the GW Perspective
Published:2012-12-27 14:52:22 From:Editor hits:
Direct utilization of solar energy by photovoltaics and photo-catalysis is currently one of the most actively pursued frontiers in basic energy sciences. In particular, the direct photo-splitting of water to H
2
and O
2
is regarded as the “holy grail” for solar energy conversion. One of the greatest challenges is to find a semiconductor with a suitable band gap that allows efficient absorption of solar energy in the visible light regime, and appropriate valence and conduction band positions that match the redox potentials for water reduction and oxidation. Electronic band structures therefore play a crucial role in solar-energy conversion. Kohn-Sham density functional theory (KS-DFT) in the local or semi-local density approximations (LDA/GGA) has serious difficulty in describing electronic properties of extended systems. In this work, we apply many-body perturbation theory in the
GW
approximation to investigate electronic properties of several materials that are promising for solar energy conversion, including in particular, early transition metal dichalcogenides (TMDC) MX
2
(M=Zr, Hf, Mo and W, X=S and Se)[1,2], and alkaline tantalum oxides ATaO
3
(A=Li, Na, K)[3]. In addition, we also perform a systematic investigation on the accuracy of the current first-principles methods for the prediction of absolute band positions, the energies of the valence band maximum (VBM) and conduction band minimum (CBM) with respect to the vacuum level by considering a set of prototypical semiconductors.
More:
Full Text
Declaration:
This article reprint is merely of spread information needs, does not mean that represent this website to view or confirm the authenticity of its contents, Like any other media, websites or individuals from the websites use, must keep this website marked "source".