Complex bands k(E) in a semiconductor crystal, along a general direction n, can be computed by casting Schrödingers equation as a generalized polynomial eigenvalue problem. When working with primitive lattice vectors, the order of this eigenvalue problem can grow large for arbitrary n. It is, however, possible to always choose a set of non-primitive lattice vectors such that the eigenvalue problem is restricted to be quadratic. The complex bands so obtained need to be unfolded onto the primitive Brillouin zone. In this paper, we present a unified method to unfold real and complex bands. Our method ensures that the measure associated with the projections of the non-primary wavefunction onto all candidate primary wavefunctions is invariant with respect to the energy E. © 2012 IOP Publishing Ltd.

Shreepad Karmalkar

Department of Electrical Engineering

Brillouin zones

Eigenvalue problem

GENERALIZED POLYNOMIALS

LATTICE VECTORS

NEAREST NEIGHBOUR

SEMICONDUCTOR CRYSTALS

Tight binding

UNIFIED METHOD

Condensed Matter Physics

Physics

Eigenvalues and eigenfunctions

Fulltext

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IIT Madras

Journal of Physics Condensed Matter

We present a TCAD (Technology Computer Aided Design) compatible multiscale model of phonon-assisted band-to-band tunneling in semiconductors, which incorporates the non-parabolic nature of complex bands within the bandgap of the material. This model is shown capture the measured current-voltage data in silicon, for current transport along the [100], [110], and [111] directions. Our model will be useful to predict band-to-band tunneling phenomena to quantify on and off currents in tunnel FETs and in small geometry MOSFETs and FINFETs. © 2013 American Institute of Physics.

Journal of Applied Physics

Multiscale model for phonon-assisted band-to-band tunneling in semiconductors

Over the last decade, Si1-xGex has increasingly been used as a channel material in MOSFETs. Though many studies have dealt with the real bandstructure of Si1-xGex, the effect of germanium mole fraction x on complex bandstructure has been unexplored. Complex bands fundamentally determine band to band tunneling (BTBT) current. For example, using the orientation dependent complex bandstructure of silicon [1], it has been shown [2] that the BTBT current in the [110] direction is an order of magnitude larger than that along the [100] direction. BTBT contributes significantly to off-current Ioff in conventional MOSFETs, via the mechanism of gate induced drain leakage (GIDL). Additionally, BTBT determines the on current Ion in tunneling FETs, which have been suggested as next generation devices. Further, BTBT is more dominant in Si 1-xGex than silicon, owing to a narrower bandgap. In this work, we determine the orientation dependent complex bandstructure of Si 1-xGex along common crystallographic directions and predict trends in BTBT current. © 2011 IEEE.

Device Research Conference - Conference Digest, DRC

Orientation dependent complex bandstructure of Si1-xGe x alloys

Numerische Mathematik

Palindromic quadratization and structure-preserving algorithm for palindromic matrix polynomials of even degree

Physical Review Letters

Unfolding First-Principles Band Structures

2009 13th International Workshop on Computational Electronics

Computation of Complex Band Structures in Bulk and Confined Structures

Physica E: Low-dimensional Systems and Nanostructures

Non-primitive rectangular cells for tight-binding electronic structure calculations

Brillouin zone unfolding of complex bands in a nearest neighbour tight binding scheme

Journal	Journal of Physics Condensed Matter
ISSN	09538984
Open Access	Yes