26 th US Army Science Conference, Orlando 3 December 2008 Nano and Biological Technology Panel: Quantum Information Science Professor Andrew Dzurak NSW Manager, Centre for Quantum Computer Technology NSW Director, Australian National Fabrication Facility School of Electrical Engineering & Telecommunications The University of New South Wales
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Quantum Information Science Data Security National Security Financial Services e-commerce Decryption National Security Intelligence Killer Apps Supercomputers Database Searching Bioinformatics Modeling & Design Semiconductors Integrated Circuits Sensors Nano-structuring
Outline Quantum Computing & Communications Science fiction becomes science fact Single Atom & Single Photon Nanotechnologies Plenty of room at the bottom Future q-it Applications What could be possible? Visualizing a Quantum Computer of the Future Computing at the atomic level
Conventional computing must confront some serious issues Transistors per chip 10 9? Cost of Fab $60B 10 8 $50B 10 7 Pentium Pro 80786 $40B 10 6 10 5 8086 80386 80286 80486 Pentium 360B $20B 10 4 8080 4004 10 3 1970 1975 1980 1985 1990 1995 2000 2005 2010 Year $10B $0B 1992 1995 1998 2001 2004 2007 2010 Year
Quantum computing could well be the solution Conventional Computer Quantum Computer 1> 0, 1 0>, 1> 0> bits qubits Quantum state of a two-level system 0> 1>
The power of quantum superposition Ever wished you could be in two places at the same time? Consider a 300 qubit byte of information x = b 300 b 299 b 3 b 2 b 1 Example: x = 100110100 110011010 Possible states = 2 300 = Number of atoms in universe!!! A QC would compute with all of these in parallel Blue Gene: 10 15 ops/sec would take 10 78 years to look at each
From basic science to new technologies. Algorithms for quantum computation: discrete logarithms and factorings (1994) quantum technologies
Quantum Communications when absolute security of information is vital Bob Alice Eve
The first quantum computers
Australia-US Partnership in QC Silicon Solid State QC Single Atom Nanoelectronics Linear Optics QC Single Photon Photonics B=2T
Computing + Communications =
Computing + Communications =
Australian Research Council Centre of Excellence for Quantum Computer Technology
Underpinning Nanotechnologies Nano-scale Fabrication Atom-scale Fabrication Quantum Measurement
Single Atom Nanoelectronics : Top Down Sydney - UNSW U Melbourne D.N. Jamieson et al.
Single Atom Nanoelectronics : Bottom Up 1nm 10 nm UNSW M.Y. Simmons et al.
Single Atom Nanoelectronics : Bottom Up Optical Image SEM Image SEM Image STM Image 100µm 20 μm 5 μm 90 x 900nm STM Fabricated Device 100nm SEM Imaging 12µm 2mm 22 scan area STM Imaging 50nm 27nm 3.5µm 6 wide wide 2 scan wire wire area
Single Electron Electronics 100 nm 1.95 0 1 0.24 0,N+2 1,N+2 1.94 0,N+1 1,N+1 V top gate (V) 1.93 1.92 0,N 0,N 1 1,N 1,N 1 di/dv (e 2 /h) 1.91 0,N 2 1,N 2 1.90-2 -1 0 1 2 V SD (mv) -50-40 -30 V plunger (mv) 0
Single Atom Transistor: Control Device barrier/donor gate V plunger 20 10 di/dv (e 2 /h) 0.16 V SD (mv) 0-10 -20 0.8 0.9 1.0 1.1 V barrier (V) -0.020 no P-implant no resonant tunneling features A. Morello et al.
Single Atom Transistor: P Atom Implants timed P-implant <n> = 3 in 50 30 nm barrier/donor gate 20 di/dv P-implant area V plunger (e 2 /h) 10 0.16 V SD (mv) 0-10 -20 0.8 0.9 1.0 1.1 V barrier (V) -0.020 <n> = 3 atoms 3 pairs of sharp resonant tunneling features
Single Atom Transistor: Tunneling Spectra V barrier (V) 0.90 0.95 1.00 V SD (mv) 20 10 0-10 di/dv (e 2 /h) 0.16 0.0 0.1-20 0.8 0.9 1.0 1.1-0.020 G (e 2 /h) V barrier (V)
Zeeman Shift of P-Atom Electron States V barrier (V) 0.90 0.95 1.00 Second electron on the donor D - state spin-up 0.0 0.1 G (e 2 /h) 0 1 2 3 4 5 6 7 B (T) First electron on the donor D 0 state spin-down Resolved the Zeeman shift on electron states of individual donors
Single Photon Photonics Linear Optics Quantum Computing Predicted Experiment Free Space & Fibre Integrated Optics CNOT Gate Polarisation or Frequency Encoding CNOT Gate U Queensland A.G. White et al. U Queensland & Australian Defence Forces Academy U Bristol J.L O Brien et al.
QIS Key Application Areas Data Security National Security Financial Services e-commerce Decryption National Security Intelligence Killer Apps Supercomputers Database Searching Bioinformatics Modeling & Design Semiconductors Integrated Circuits Sensors Nano-structuring
Secure Communications Quantum communication systems can be made perfectly secure (existing protocol BB84) Key applications (near to medium term): Military & Security Services Communications Financial Services e-commerce Corporate Communications (sensitive data) Current data encryption market = $10 billion Quantum LAN now available: MagiQ (USA) ID-Quantique (Switz)
Code Decryption Public key encryption (RSA-129) is (almost) uncrackable. Basis of public secure comms today A full-scale (few hundred qubits) quantum computer could crack RSA-129 in seconds (Peter Shor 1994) Obvious applications in national and global security
High Performance Computing Simulation (modeling) & database searching Existing supercomputers now under strain Application areas: Nuclear weapons simulation Rapid data search Security services Biotechnology modeling (new reagents & pharma) searching (bioinformatics) Advanced R&D modeling (commercial, govt) Internet Search Engines q-google? Longer term prospect (15 30 years)
Next Generation Integrated Circuits Spin-off or pathway technologies potentially provide nearer term applications than QC per se Eg: Single atom nanotechnologies Possible applications: Next generation transistors - extending Moore s Law (to 2020) - single atom transistors Current world semiconductor market $200 billion Transistors per chip 10 9 10 8 10 7 10 6 10 5 8086 80386 80286 Pentium Pro 80486 Pentium 80786? 10 4 8080 4004 10 3 1970 1975 1980 1985 1990 1995 2000 2005 2010 Year
CQCT: Key International Collaborations
Major International QC Projects
QIS Investment Worldwide World Total = US$180m p.a.* * Source: 2004 - Oxford Business School
Summary Quantum Information Science Quantum information technologies now a reality First impacts will be secure communications: local area networks (0 5 years) q-internet & satellite comms (5 15 years) Longer term (15 30 years) quantum computing: high-end computing (simulation, biotech) High risk, high pay-off technologies
Visualizing a Silicon Quantum Computer See: Barry Sanders, Lloyd Hollenberg et al., in New Journal of Physics v10 (2008). Barry Sanders, in Physics World, December 2008.