Title :
Study of the Wigner Function Computed by Solving the Schrödinger Equation
Author :
Savio, Andrea ; Poncet, Alain
Author_Institution :
Lyon Inst. of Nanotechnol., INSA-Lyon, Villeurbanne, France
Abstract :
In this work, we compute the Wigner distribution function from wavefunctions generated by solving the Schrodinger equation. Our goal is to propose an avenue of research that may help better understand certain limitations of Wigner transport equation solvers, such as negative charge densities or limited charge drop-offs in presence of potential barriers. We evaluate the numerical accuracy required by the Schrodinger solver to compute the Wigner function and compare the performance of an analytic and a numerical solver applied to a constant potential profile, as well as to single- and double-barrier structures. Finally, we use the Schro¿dinger solver to better understand certain conditions to be applied to Wigner transport equation solvers, namely the minimum contact length and k-grid range.
Keywords :
Schrodinger equation; nonlinear differential equations; wave functions; Schrodinger equation; Schrodinger solver; Wigner distribution function; Wigner transport equation solvers; double-barrier structures; k-grid range; limited charge drop-offs; negative charge densities; potential barriers; wavefunctions; Distributed computing; Distribution functions; Effective mass; Electrons; MOSFETs; Nanoscale devices; Performance analysis; Quantum computing; Schrodinger equation; Tunneling; Quantum transport; Schrödinger equation; Wigner function;
Conference_Titel :
Quantum, Nano and Micro Technologies, 2010. ICQNM '10. Fourth International Conference on
Conference_Location :
St. Maarten
Print_ISBN :
978-1-4244-5807-3
DOI :
10.1109/ICQNM.2010.18
