|
Page Information : Quantum Dynamics
|
This page provides technical and administrative information regarding School of Physics - Quantum Dynamics. For enquiries about the contents of the referring page, contact addresses in the Ownership table, below.
For general enquiries please check the General Enquiries page.
For technical issues or problems relating to these web pages, contact the University Website Office.
Return to referring page
| Page Properties | |
| Site Name |
|
| Page Name |
|
Quantum Dynamics
|
Page ID: 26263
|
|
| Short Page Name | Quantum Dynamics |
| Description |
Quantum dynamics in nanostructured electronic, devices, Quantum information and quantum computation, Electronic structure of artificial atoms (quantum dots), Scattering in atomic and mesoscopic systems, Density matrix theory on complete scattering experiments and Acoustic wave propagator and its applications at the School of Physics, University of Western Australia.
|
| Keywords |
electronic scattering dots wave atoms electron information theory contents logic structure acoustic computation experiments theoretical computer atomic ph.d devices mechanical gates quot collision physics approach electrons problems basic components size example propagator controlled research potential operation applications engineering project jointly supervised energy time density systems waves artificial prof complete aim propagation provide phenomena otherwise methods chris several calculations dynamics events inaccessible treating extremely time-independent nature accurate levels used field evolving entirely designs transient current variety consequently between wires matrix hines speed nanostructured collaboration processes transport mesoscopic provides therefore traditional plasma charge environment modelling including without intractable conventional possibilities shape associated analysis design precisely process computational computers structures past next-generation properties department hons main sound need direct range students real examine gate bits cavities natural data individual positron ions distinct behaviours allows watch visualisation atom wavepacket many advantages over space fabricated help opened like user-designed achieve wide areas bem build exploring technology nanofabrication shell quantised normally makes special exhibit advanced similar dimensions lasers various focus confined principal carriers highly develop objective dream realising wavelengths handles three become building hoped chips blocks time-dependent easy alignment orientation sections cross energies parameters performed fusion laser describing sometimes essential transition reliable test models stringent available obtaining many-particle once established model certain validity discharge planetary enclosure inhomogeneous decay long-standing solutions non-linear media boundaries moving spaces variation give method extend fem pan astronomical atmospheres study air solids treated frequency domain optimum guidance implement flexible difficult comparatively problem versatile large serious resolve expected many-body value initial post-collision interaction resonance ionisation states thus free approaches encountered difficulties inherited discrepancies existing complexity prevents unfortunately atmosphere great quantitative purpose theme laboratories out carried occur stelbovics physical hidden reveal artificially theories identify characterise a.t williams j.f impurities continuum challenge recent beams transfer radiative publications fifty power doubling witnessed years simulation carlo euler schemes huynh positron-hydrogen sod chebyshev monte carter woolford charlie approximately every reached already microprocessor pentium circuit patterns few wavelength since 130nm latest circuits possible advances technological months continuing reduction integrated designing innovations dependent riste algorithm manouchehri kia simulations hongmei sun muhandiramge ranga green richard cluster heterogeneous wang jingbo staff directions home stuart welna filip waveguide midgley electrical material mccarthy shane barjaktarevic paul under influence neil fields external time-varying john effect spheroidal falloon peter group harmonics general orlando adrian arguments mev around rapidly description theoreticians pressing interdisciplinary attracted instead mathematics science researchers paradigm automata propagate nonlocality through cells powerful architectures cellular quantum-dot transistorless nano-computer brute-force minitrization interested types different detail aspects cryptography entanglement state commitment bit fast remarkably solve promises architecture utilises heart laws tasks perform mechanics dot communications scale nanometer emerge effects cannot scaled ultra-fast fact further down dealing properly soon meters nano tens start play functionality role dominant advantageously operate less amounting changes small offers ultra-high establish possibility another very-low-power response off present-day rather phase controlling opens horizon switched source-to-drain electronics discrimination
|
| URL(s) |
http://www.physics.uwa.edu.au/page/26263
|
| Source |
http://www.physics.uwa.edu.au/page/26263
|
| Lineage |
Home
Information About
Research
Quantum Dynamics
|
| Rights |
Copyright 2009, Legal Services, The University of Western Australia
|
| Site Management Plan |
Site management plan
|
| Page History |
Today's Date is Wednesday, 25th November 2009 |
| Create Date |
Tue, 12 Aug 2003 16:23:29 +0800
|
| Content Last Edited |
Tue, 19 Aug 2008 11:49:39 +0800
|
| Content Last Approved |
Tue, 19 Aug 2008 11:49:39 +0800
|
| Next Review Date |
A review date has not been set for this page.
|
Return to referring page
|
|