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Progress in technology has brought microelectronics to the nanoscale, but nanoelectronics is not yet a well-defined engineering discipline with a coherent, experimentally verified, theoretical framework. The NCN has a vision for a new, 'bottom-up' approach to electronics, which involves: understanding electronic conduction at the atomistic level; formulating new simulation techniques; developing a new generation of software tools; and bringing this new understanding and perspective into the classroom. We address problems in atomistic phenomena, quantum transport, percolative transport in inhomogeneous media, reliability, and the connection of nanoelectronics to new problems such as biology, medicine, and energy. We work closely with experimentalists to understand nanoscale phenomena and to explore new device concepts. In the course of this work, we produce open source software tools and educational resources that we share with the community through the nanoHUB.
This page is a starting point for nanoHUB users interested in nanoelectronics. It lists key resources developed by the NCN Nanoelectronics team. The nanoHUB contains many more resources for nanoelectronics, and they can be located with the nanoHUB search function. To find all nanoelectronics resources, search for 'nanoelectronics.' To find those contributed by the NCN nanoelectronics team, search for 'NCNnanoelectronics.'
More information on Nanoelectronics can be found here.
ECE 495N Lecture 35: NEGF Continued II
out of 5 stars
10 Dec 2008 | | Contributor(s):: Supriyo Datta
ECE 495N Lecture 36: Spin
ECE 495N Lecture 37: Spin Matrices
15 Dec 2008 | | Contributor(s):: Supriyo Datta
ECE 495N Lecture 38: Spin Rotation
29 Dec 2008 | | Contributor(s):: Supriyo Datta
ECE 495N Lecture 39: Where is the Heating?
ECE 495N Lecture 3: Importance of Electrostatics
10 Sep 2008 | | Contributor(s):: Supriyo Datta
ECE 495N Lecture 40: Thermoelectricity
ECE 495N Lecture 41: Entropy
ECE 495N Lecture 4: Quantitative Model for Nanodevices I
ECE 495N Lecture 5: Quantitative Model for Nanodevices II
12 Sep 2008 | | Contributor(s):: Supriyo Datta
ECE 495N Lecture 6: Quantitative Model for Nanodevices III
ECE 495N Lecture 7: Quantum Capacitance/Shrödinger's Equation
17 Sep 2008 | | Contributor(s):: Supriyo Datta
ECE 495N Lecture 8: Shrödinger's Equation
30 Sep 2008 | | Contributor(s):: Supriyo Datta
ECE 495N Lecture 9: Finite Difference Method
ECE 595E Lecture 20: Bandstructure Concepts
06 Mar 2013 | | Contributor(s):: Peter Bermel
Outline:Recap from FridayBandstructure Problem FormulationBloch’s TheoremReciprocal Lattice SpaceNumerical Solutions1D crystal2D triangular lattice3D diamond lattice
ECE 595E Lecture 21: 3D Bandstructures
19 Mar 2013 | | Contributor(s):: Peter Bermel
Outline:Recap from MondayBandstructure Symmetries2D Photonic BandstructuresPeriodic Dielectric WaveguidesPhotonic Crystal Slabs
ECE 595E Lecture 22: Full 3D Bandgaps
Outline:Recap from Wednesday3D Lattice TypesFull 3D Photonic Bandgap StructuresYablonoviteWoodpileInverse OpalsRod-Hole 3D PhCs
ECE 595E Lecture 23: Electronic Bandstructures
27 Mar 2013 | | Contributor(s):: Peter Bermel
Outline:3D Lattice TypesFull 3D Photonic Bandgap StructuresYablonoviteWoodpileInverse OpalsRod-Hole 3D PhCs
ECE 595E Lecture 24: Electronic Bandstructure Simulation Tools
Outline:Electronic bandstructure labBasic PrinciplesInput InterfaceExemplary OutputsDensity functional theory (DFT)DFT in Quantum ESPRESSO
ECE 606 Lecture 14: Bulk Recombination
29 Mar 2009 | | Contributor(s):: Muhammad A. Alam
Outline:Derivation of SRH formulaApplication of SRH formula for special casesDirect and Auger recombinationConclusion