All Categories (1-20 of 27)

1. 1-D Phonon BTE Solver

   Tools | 28 Jul 2014 | Contributor(s):: Joseph Adrian Sudibyo, Amr Mohammed, Ali Shakouri

   Simulate heat transport by solving one dimensional Boltzmann transport equation.

2. ab initio Model for Mobility and Seebeck coefficient using Boltzmann Transport (aMoBT) equation

   Tools | 15 May 2015 | Contributor(s):: Alireza Faghaninia, Joel Ager (editor), Cynthia S Lo (editor)

   ab initio electronic transport model to calculate low-field electrical mobility and Seebeck coefficient of semiconductors in Boltzmann transport framework.

3. Acoustic Phonon Scattering Explained

   Teaching Materials | 05 Feb 2011 | Contributor(s):: Dragica Vasileska

   In this lecture notes we derive and explain acoustic deformation potential scattering as it applies to transport calculations in covalent semiconductors.

4. Boltzmann Transport Equation and Scattering Theory

   Teaching Materials | 29 Jan 2011 | Contributor(s):: Dragica Vasileska

   In this presentation we give simple derivation of the Boltzmann transport equation, describe the derivation of Fermi's Golden Rule, and present the derivation of most common scattering mechanisms in semiconductors.

5. Bulk Monte Carlo: Implementation Details and Source Codes Download

   Teaching Materials | 01 Jun 2010 | Contributor(s):: Dragica Vasileska, Stephen M. Goodnick

   The Ensemble Monte Carlo technique has been used now for over 30 years as a numerical method to simulate nonequilibrium transport in semiconductor materials and devices, and has been the subject of numerous books and reviews. In application to transport problems, a random walk is generated to...

6. Device Physics Studies of III-V and Silicon MOSFETS for Digital Logic

   Papers | 25 Jun 2013 | Contributor(s):: Himadri Pal

   III-V's are currently gaining a lot of attraction as possible MOSFET channel materials due to their high intrinsic mobility. Several challenges, however, need to be overcome before III-V's can replace silicon (Si) in extremely scaled devices. The effect of low density-of-states of III-V materials...

7. 

   Dibya Prakash Rai

   https://nanohub.org/members/187116

8. Direct Solution of the Boltzmann Transport Equation in Nanoscale Si Devices

   Papers | 27 Jun 2013 | Contributor(s):: Kausar Banoo

   Predictive semiconductor device simulation faces a challenge these days. As devices are scaled to nanoscale lengths, the collision-dominated transport equations used in current device simulators can no longer be applied. On the other hand, the use of a better, more accurate Boltzmann Transport...

9. ECE 656 Lecture 14: The Boltzmann Transport Equation

   Online Presentations | 05 Oct 2011 | Contributor(s):: Mark Lundstrom

   Outline:IntroductionEquation of motionThe BTESolving the s.s. BTEDiscussionSummary

10. ECE 656 Lecture 29: The BTE Revisited - Equilibrium and Ballistic

    Online Presentations | 11 Nov 2011 | Contributor(s):: Mark Lundstrom

    Outline:Quick reviewEquilibrium BTEBallistic BTEDiscussionSummary

11. ECE 656 Lecture 41: Transport in a Nutshell

    Online Presentations | 20 Dec 2011 | Contributor(s):: Mark Lundstrom

12. Fundamentals of Current Flow

    Papers | 30 Jan 2022 | Contributor(s):: Supriyo Datta

    Everyone is familiar with the amazing performance of a modern smartphone, powered by a billion-plus nanotransistors, each having an active region that is barely a few hundred atoms long. The same amazing technology has also led to a deeper understanding of the nature of current flow and heat...

13. Generalized Monte Carlo Presentation

    Teaching Materials | 17 Jun 2011 | Contributor(s):: Dragica Vasileska

    This presentation goes along with the Bulk Monte Carlo tool on the nanoHUB that calculates transients and steady-state velocity-field characteristics of arbitrary materials such as Si, Ge, GaAs, GaN, SiC, etc. The tool employs a non-parabolic bandstructure.

14. 

    Heeyuen Koh

    https://nanohub.org/members/56621

15. Introduction to Boltzmann Transport Equation

    Teaching Materials | 28 Jun 2011 | Contributor(s):: Dragica Vasileska

    This set of handwritten notes is part of the Semiconductor Transport class.

16. IWCN 2021: Thermoelectric Properties of Complex Band and Nanostructured Materials

    Online Presentations | 13 Jul 2021 | Contributor(s):: Neophytos Neophytou, Patrizio Graziosi, Vassilios Vargiamidis

    In this work, we describe a computational framework to compute the electronic and thermoelectric transport in materials with multi-band electronic structures of an arbitrary shape by coupling density function theory (DFT) bandstructures to the Boltzmann Transport Equation (BTE).

17. Lecture 7: The Boltzmann Transport Equation

    Online Presentations | 16 Aug 2011 | Contributor(s):: Mark Lundstrom

    Semi-classical carrier transport is traditionally described by the Boltzmann Transport Equation (BTE). In this lecture, we present theBTE, show how it is solved, and relate it to the Landauer Approach usedin these lectures

18. Limitations of the BTE

    Teaching Materials | 28 Jun 2011 | Contributor(s):: Dragica Vasileska

    This set of handwritten notes is part of the Semiconductor Transport class.

19. Linearized Boltzmann transport calculator for thermoelectric materials

    Tools | 11 Jul 2013 | Contributor(s):: Je-Hyeong Bahk, Robert Benjamin Post, Kevin Margatan, Zhixi Bian, Ali Shakouri

    Simulation tool to calculate thermoelectric transport properties of bulk materials based on their multiple nonparabolic band structure information using the linearized Boltzmann transport equation

20. Low Temperature Enhancement of the Thermoelectric Seebeck Coefficient in Semiconductor Nanoribbons

    Online Presentations | 21 Oct 2016 | Contributor(s):: Kommini Adithya, Zlatan Aksamija

    IWCE 2015 Presentation. We propose a novel approach to achieving a narrow window-shaped TDF through a combination of a step-like 2-dimensional density-of-states (DOS) and inelastic optical phonon scattering. A shift in the onset of scattering with respect to the step-like DOS creates a TDF which...