Timeline of quantum computing

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Timeline of quantum computers

Contents

[edit] 1970s

  • 1973 - Alexander Holevo publishes a paper showing that n qubits cannot carry more than n classical bits of information (a result known as "Holevo's theorem" or "Holevo's bound"). Charles H. Bennett shows that computation can be done reversibly.
  • 1975 - R. P. Poplavskii publishes "Thermodynamical models of information processing" (in Russian), Uspekhi Fizicheskikh Nauk,115:3, 465–501 which showed the computational infeasibility of simulating quantum systems on classical computers, due to the superposition principle.

[edit] 1980s

  • 1980 - Yuri I. Manin, publishes Computable and uncomputable (in Russian), Moscow, Sovetskoye Radio.
  • 1981
    • Richard Feynman in his talk at the First Conference on the Physics of Computation, held at MIT, observed that it appeared to be impossible in general to simulate an evolution of a quantum system on a classical computer in an efficient way. He proposed a basic model for a quantum computer that would be capable of such simulations.
    • Tommaso Toffoli introduced the reversible Toffoli gate, which, together with the NOT and XOR gates provides a universal set for quantum computation.

[edit] 1990s

  • 1997
    • David Cory, Amr Fahmy and Timothy Havel, and at the same time Neil Gershenfeld and Isaac L. Chuang at MIT published the first papers on quantum computers based on bulk spin resonance, or thermal ensembles. The technology is based on a nuclear magnetic resonance (NMR) machine, which is similar to the medical magnetic resonance imaging machine. This room-temperature (thermal) collection of molecules (ensemble) maintains coherence for several seconds. However, this approach to quantum computing is not scalable beyond a few tens of qubits.
    • Alexei Kitaev describes the principles of topological quantum computation as a method for combatting decoherence.
  • 1999 - Samuel L. Braunstein and collaborators showed that there was no quantum entanglement in any bulk NMR experiment, implying that the NMR device is at best a classical simulator of a quantum computer.[2]

[edit] 2000-2004

  • 2001
    • First execution of Shor's algorithm at IBM's Almaden Research Center and Stanford University. The number 15 was factored using 1018 identical molecules, each containing seven active nuclear spins. However all these NMR results do not represent true quantum computing as no quantum entanglement is present (see 1999 above).
  • 2002 - The Quantum Information Science and Technology Roadmapping Project, involving some of the main participants in the field, laid out the Quantum computation roadmap.

Since the NMR experiments cannot prepare pure quantum states and exhibit no quantum entanglement during computation, concerns have arisen about their quantum nature. In particular, it has been proved that the presence of entanglement is a necessary condition for quantum computation.[5]

[edit] 2005

  • University of Illinois at Urbana-Champaign scientists demonstrate quantum entanglement of multiple characteristics, potentially allowing multiple qubits per particle.
  • Two teams of physicists have measured the capacitance of a Josephson junction for the first time. The methods could be used to measure the state of quantum bits in a quantum computer without disturbing the state. [6]
  • In December, the first quantum byte, or qubyte, is announced to have been created by scientists at The Institute of Quantum Optics and Quantum Information at the University of Innsbruck in Austria, with the formal paper published in the December 1st issue of Nature.
  • Harvard University and Georgia Institute of Technology researchers succeeded in transferring quantum information between "quantum memories" – from atoms to photons and back again.

[edit] 2006

  • Materials Science Department of Oxford University, cage a qubit in a buckyball (a Buckminster fullerene particle), and demonstrated quantum "bang-bang" error correction. [7]
  • Researchers from the University of Illinois at Urbana-Champaign use the Zeno Effect, repeatedly measuring the properties of a photon to gradually change it without actually allowing the photon to reach the program, to search a database without actually "running" the quantum computer.[8]
  • Vlatko Vedral of the University of Leeds and colleagues at the universities of Porto and Vienna found that the photons in ordinary laser light can be quantum mechanically entangled with the vibrations of a macroscopic mirror.[9]
  • Professor Samuel L.Braunstein at the University of York along with the University of Tokyo and the Japan Science and Technology Agency gave the first experimental demonstration of quantum telecloning.[10]
  • Professors at the University of Sheffield develop a means to efficiently produce and manipulate individual photons at high efficiency at room temperature.[11]
  • New error checking method theorized for Josephson junction computers. [12]
  • First 12 qubit quantum computer benchmarked. [13]
  • Two dimensional ion trap developed for quantum computing.[14]
  • Seven atoms placed in stable line, a step on the way to constructing a quantum gate, at the University of Bonn.[15]
  • A team at Delft University of Technology in the Netherlands created a device that can manipulate the "up" or "down" spin-states of electrons on quantum dots. [16]
  • University of Arkansas develops quantum dot molecules.[17]
  • Spinning new theory on particle spin brings science closer to quantum computing.[18]
  • University of Copenhagen develops quantum teleportation between photons and atoms.[19]
  • University of Southern California develops new quantum error correction method.[19]
  • University of Camerino scientists develop theory of macroscopic object entanglement, which has implications for the development of quantum repeaters.[20]
  • Scientists at Illinois at Urbana-Champaign find that quantum coherence is possible in incommensurate electronic systems.[21]
  • University of Utah Scientist shows it's feasible to read data stored as nuclear spins.[22]

[edit] 2007

  • Subwavelength waveguide developed for light. [23]
  • Single photon emitter for optical fibers developed. [24]
  • New material proposed for quantum computing. [25]
  • Single atom single photon server devised. [26]
  • First use of Deutsch's Algorithm in a cluster state quantum computer. [27]
  • University of Cambridge develops electron quantum pump. [28]
  • Superior method of qubit coupling developed. [29]
  • Successful Demonstration of Controllably Coupled Qubits. [30]
  • Breakthrough in applying spin-based electronics to silicon.[31]
  • Scientists demonstrate quantum state exchange between light and matter. [32]
  • Diamond quantum register developed. [33]
  • Controlled-NOTquantum gates on a pair of superconducting quantum bits realized.[34]
  • Scientists contain, study hundreds of individual atoms in 3D array. [35]
  • Nitrogen in buckyball used in quantum computing. [36]
  • Large number of electrons quantum coupled. [37]
  • Spin-orbit interaction of electrons measured. [38]
  • Atoms quantum manipulated in laser light. [39]
  • Light pulses used to control electron spins. [40]
  • Quantum effects demonstrated across tens of nanometers. [41]
  • Light pulses used to accelerate quantum computing development. [42]
  • Quantum RAM blueprint unveiled. [43]
  • Model of quantum transistor developed. [44]
  • Long distance entanglement demonstrated. [45]
  • Photonic quantum computing used to factor number by two independent labs. [46]
  • Quantum bus developed by two independent labs. [47]
  • Superconducting quantum cable developed. [48]
  • Transmission of qubits demonstrated. [49]
  • Superior qubit material devised. [50]
  • Single electron qubit memory. [51]
  • Bose-Einstein condensate quantum memory developed [52]
  • D-Wave Systems claims to have working 28-qubit quantum computer.[53]
  • New cryonic method reduces decoherence and increases interaction distance.(and thus quantum computing speed)[54]
  • Photonic quantum computer demonstrated.[55]

[edit] 2008

  • Graphene quantum dot qubits[56]
  • Quantum bit stored[57]
  • 3D qubit-qutrit entanglement demonstrated[58]
  • Analog quantum computing devised[59]
  • Control of quantum tunneling[60]
  • Entangled memory developed[61]
  • Superior NOT gate developed[62]
  • Qutrits developed[63]
  • Quantum logic gate in optical fiber[64]
  • Nano-Diamonds devised[65]
  • Superior quantum Hall Effect discovered[66]
  • Enduring spin states in quantum dots[67]
  • Molecular magnets proposed for quantum RAM[68]
  • Quasiparticles offer hope of stable quantum computer[69]

[edit] References

  1. ^ Monroe, C.; Meekhof, D.M.; King, B.E.; Itano, W.M.; Wineland, D.J. (December 18, 1995). "Demonstration of a Fundamental Quantum Logic Gate". Physical Review Letters vol. 75 (#25): pp. 4714 - 4717. 
  2. ^ S. L. Braunstein, et al., "Separability of Very Noisy Mixed States and Implications for NMR Quantum Computing", Phys. Rev. Lett. 83, 1054 (1999)
  3. ^ T. B. Pittman, M. J. Fitch, B. C Jacobs, and J. D. Franson, "Experimental controlled-not logic gate for single photons in the coincidence basis," Phys. Rev. A 68, 032316 (2003)
  4. ^ J. L. O'Brien, G. J. Pryde,, A. G. White, T. C. Ralph, & D. Branning, "Demonstration of an all-optical quantum controlled-NOT gate," Nature 426, 264-267 (20 November 2003)
  5. ^ [1]
  6. ^ Dumé, Belle. "Breakthrough for quantum measurement", PhysicsWeb, 2005-11-22. Retrieved on 2007-12-29. 
  7. ^ January 4, 2006 University of Oxford "Bang-bang: a step closer to quantum supercomputers". Retrieved on 2007-12-29. 
  8. ^ Jonathan P. Dowling, "To Compute or Not to Compute?" Nature 439, 919 (2006)
  9. ^ Belle Dumé, "Entanglement heats up," Physics World (February 23, 2007)
  10. ^ February 16, 2006 University of York "Captain Kirk's clone and the eavesdropper". Press release. Retrieved on 2007-12-29.
  11. ^ March 24th, 2006 Soft Machines The best of both worlds - organic semiconductors in inorganic nanostructures. Retrieved on 2007-12-29.
  12. ^ June 8, 2006 New Scientist Tom Simonite. "Error-check breakthrough in quantum computing". Retrieved on 2007-12-29. 
  13. ^ May 8, 2006 ScienceDaily "12-qubits Reached In Quantum Information Quest". Retrieved on 2007-12-29. 
  14. ^ July 7, 2006 New Scientist Tom Simonite. "Flat 'ion trap' holds quantum computing promise". Retrieved on 2007-12-29. 
  15. ^ July 12, 2006 PhysOrg.com Luerweg, Frank. "Quantum Computer: Laser tweezers sort atoms". Retrieved on 2007-12-29. 
  16. ^ August 16, 2006 New Scientist "'Electron-spin' trick boosts quantum computing". Retrieved on 2007-12-29. 
  17. ^ August 16, 2006 NewswireToday Michael Berger. "Quantum Dot Molecules - One Step Further Towards Quantum Computing". Retrieved on 2007-12-29. 
  18. ^ September 07, 2006 PhysOrg.com "Spinning new theory on particle spin brings science closer to quantum computing". Retrieved on 2007-12-29. 
  19. ^ a b October 4,2006 New Scientist Zeeya Merali. "Spooky steps to a quantum network". 
  20. ^ October 24, 2006 PhysOrg.com Lisa Zyga. "Scientists present method for entangling macroscopic objects". Retrieved on 2007-12-29. 
  21. ^ November 2, 2006 University of Illinois at Urbana-Champaign James E. Kloeppel. "Quantum coherence possible in incommensurate electronic systems". Retrieved on 2007-12-29. 
  22. ^ November 19, 2006 PhysOrg.com "A Quantum (Computer) Step: Study Shows It's Feasible to Read Data Stored as Nuclear 'Spins'". Retrieved on 2007-12-29. 
  23. ^ January 8, 2007 New Scientist Jeff Hecht. "Nanoscopic 'coaxial cable' transmits light". Retrieved on 2007-12-30. 
  24. ^ February 21, 2007 The Engineer "Toshiba unveils quantum security". Retrieved on 2007-12-30. 
  25. ^ March 15, 2007 New Scientist Zeeya Merali. "The universe is a string-net liquid". Retrieved on 2007-12-30. 
  26. ^ March 12, 2007 Max Planck Society "A Single-Photon Server with Just One Atom". Press release. Retrieved on 2007-12-30.
  27. ^ April 18, 2007 PhysOrg.com Miranda Marquit. "First use of Deutsch's Algorithm in a cluster state quantum computer". Retrieved on 2007-12-30. 
  28. ^ April 19, 2007 Electronics Weekly Steve Bush. "Cambridge team closer to working quantum computer". Retrieved on 2007-12-30. 
  29. ^ May 7, 2007 Wired Cyrus Farivar. "It's the "Wiring" That's Tricky in Quantum Computing". Retrieved on 2007-12-30. 
  30. ^ May 8, 2007 Media-Newswire.com "NEC, JST, and RIKEN Successfully Demonstrate World's First Controllably Coupled Qubits". Press release. Retrieved on 2007-12-30.
  31. ^ May 16, 2007 Scientific American JR Minkel. "Spintronics Breaks the Silicon Barrier". Retrieved on 2007-12-30. 
  32. ^ May 22, 2007 PhysOrg.com Lisa Zyga. "Scientists demonstrate quantum state exchange between light and matter". Retrieved on 2007-12-30. 
  33. ^ June 1, 2007 Science "Quantum Register Based on Individual Electronic and Nuclear Spin Qubits in Diamond" . doi:10.1126/science.1139831. 
  34. ^ June 14, 2007 Nature "Demonstration of controlled-NOT quantum gates on a pair of superconducting quantum bits" . doi:10.1038/nature05896. 
  35. ^ June 17, 2007 New Scientist Mason Inman. "Atom trap is a step towards a quantum computer". Retrieved on 2007-12-30. 
  36. ^ June 29, 2007 Nanowerk.com "Can nuclear qubits point the way?". Retrieved on 2007-12-30. 
  37. ^ July 27, 2007 ScienceDaily "Discovery Of 'Hidden' Quantum Order Improves Prospects For Quantum Super Computers". Retrieved on 2007-12-30. 
  38. ^ July 23, 2007 PhysOrg.com Miranda Marquit. "Indium arsenide may provide clues to quantum information processing". Retrieved on 2007-12-30. 
  39. ^ July 25, 2007 National Institute of Standards and Technology "Thousands of Atoms Swap ‘Spins’ with Partners in Quantum Square Dance". Retrieved on 2007-12-30. 
  40. ^ August 15, 2007 PhysOrg.com Lisa Zyga. "Ultrafast quantum computer uses optically controlled electrons". Retrieved on 2007-12-30. 
  41. ^ August 15, 2007 Electronics Weekly Steve Bush. "Research points way to qubits on standard chips". Retrieved on 2007-12-30. 
  42. ^ August 17, 2007 ScienceDaily "Computing Breakthrough Could Elevate Security To Unprecedented Levels". Retrieved on 2007-12-30. 
  43. ^ August 21, 2007 New Scientist Stephen Battersby. "Blueprints drawn up for quantum computer RAM". Retrieved on 2007-12-30. 
  44. ^ August 26, 2007 PhysOrg.com "Photon-transistors for the supercomputers of the future". Retrieved on 2007-12-30. 
  45. ^ September 5, 2007 University of Michigan "Physicists establish "spooky" quantum communication". Retrieved on 2007-12-30. 
  46. ^ September 13, 2007 huliq.com "Qubits poised to reveal our secrets". Retrieved on 2007-12-30. 
  47. ^ September 26, 2007 New Scientist Saswato Das. "Quantum chip rides on superconducting bus". Retrieved on 2007-12-30. 
  48. ^ September 27, 2007 ScienceDaily "Superconducting Quantum Computing Cable Created". Retrieved on 2007-12-30. 
  49. ^ October 11, 2007 Electronics Weekly Steve Bush. "Qubit transmission signals quantum computing advance". Retrieved on 2007-12-30. 
  50. ^ October 08, 2007 TG Daily Rick C. Hodgin. "New material breakthrough brings quantum computers one step closer". Retrieved on 2007-12-30. 
  51. ^ October 19, 2007 Optics.org "Single electron-spin memory with a semiconductor quantum dot". Retrieved on 2007-12-30. 
  52. ^ November 7, 2007 New Scientist Stephen Battersby. "'Light trap' is a step towards quantum memory". Retrieved on 2007-12-30. 
  53. ^ November 12, 2007 Nanowerk.com "World's First 28 qubit Quantum Computer Demonstrated Online at Supercomputing 2007 Conference". Retrieved on 2007-12-30. 
  54. ^ December 12, 2007 PhysOrg.com "Desktop device generates and traps rare ultracold molecules". Retrieved on 2007-12-31. 
  55. ^ December 19, 2007 University of Toronto Kim Luke. "U of T scientists make quantum computing leap Research is step toward building first quantum computers". Retrieved on 2007-12-31. 
  56. ^ January 15,2008 Miranda Marquit. "Graphene quantum dot may solve some quantum computing problems". Retrieved on 2008-01-16. 
  57. ^ January 25, 2008 EETimes Europe. "Scientists succeed in storing quantum bit". Retrieved on 2008-02-05. 
  58. ^ February 26, 2008 Lisa Zyga. "Physicists demonstrate qubit-qutrit entanglement". Retrieved on 2008-02-27. 
  59. ^ February 26, 2008 ScienceDaily. "Analog logic for quantum computing". Retrieved on 2008-02-27. 
  60. ^ March 5, 2008 Zenaida Gonzalez Kotala. "Future 'quantum computers' will offer increased efficiency... and risks". Retrieved on 2008-03-05. 
  61. ^ March 6, 2008 Ray Kurzweil. "Entangled memory is a first". Retrieved on 2008-03-08. 
  62. ^ March 27, 2008 Joann Fryer. "Silicon chips for optical quantum technologies". Retrieved on 2008-03-29. 
  63. ^ April 7, 2008 Ray Kurzweil. "Qutrit breakthrough brings quantum computers closer". Retrieved on 2008-04-07. 
  64. ^ April 15, 2008 Kate Greene. "Toward a quantum internet". Retrieved on 2008-04-16. 
  65. ^ April 16, 2008 Ehud Rattner. "Nano-Diamonds Might Lead to Quantum Computing". Retrieved on 2008-05-05. 
  66. ^ April 24, 2008 Princeton University. "Scientists discover exotic quantum state of matter". Retrieved on 2008-04-29. 
  67. ^ May 23, 2008 Belle Dumé. "Spin states endure in quantum dot". Retrieved on 2008-06-03. 
  68. ^ May 27, 2008 Chris Lee. "Molecular magnets in soap bubbles could lead to quantum RAM". Retrieved on 2008-06-03. 
  69. ^ June 2, 2008 Weizmann Institute of Science. "Scientists find new 'quasiparticles'". Retrieved on 2008-06-03. 
v  d  e
Quantum computing
General
Quantum communication
Quantum channelQuantum cryptographyQuantum teleportationLOCC • Entanglement distillation
Quantum algorithms
Quantum computing models
Decoherence prevention
Physical implementations
Quantum optics
Linear optics QC • Cavity QED
Ultracold atoms
Spin-based
Other