“Quantum simulator”的意思、由来-开放百科全书

A universal quantum simulator is a quantum computer proposed by Yuri Manin in 1980^[4] and Richard Feynman in 1982.^[5] Feynman showed that a classical Turing machine would experience an exponential slowdown when simulating quantum phenomena, while his hypothetical universal quantum simulator would not. David Deutsch in 1985, took the ideas further and described a universal quantum computer. In 1996, Seth Lloyd showed that a standard quantum computer can be programmed to simulate any local quantum system efficiently.^[6]

A quantum system of many particles is described by a Hilbert space whose dimension is exponentially large in the number of particles. Therefore, the obvious approach to simulate such a system requires exponential time on a classical computer. However, it is conceivable that a quantum system of many particles could be simulated by a quantum computer using a number of quantum bits similar to the number of particles in the original system. As shown by Lloyd, this is true for a class of quantum systems known as local quantum systems. This has been extended to much larger classes of quantum systems.^[7]^[8]^[9]^[10]

Quantum simulators have been realized on a number of experimental platforms, including systems of ultracold quantum gases, trapped ions, photonic systems and superconducting circuits.^[11]

Solving physics problems

A trapped-ion simulator, built by a team that included the NIST and reported in April 2012, can engineer and control interactions among hundreds of quantum bits (qubits). Previous endeavors were unable to go beyond 30 quantum bits. As described in the scientific journal Nature, the capability of this simulator is 10 times more than previous devices. Also, it has passed a series of important benchmarking tests that indicate a capability to solve problems in material science that are impossible to model on conventional computers.

Furthermore, many important problems in physics, especially low-temperature physics, remain poorly understood because the underlying quantum mechanics is vastly complex. Conventional computers, including supercomputers, are inadequate for simulating quantum systems with as few as 30 particles. Better computational tools are needed to understand and rationally design materials, whose properties are believed to depend on the collective quantum behavior of hundreds of particles.^[2]^[3]

The trapped-ion simulator

The trapped-ion simulator consists of a tiny, single-plane crystal of hundreds of beryllium ions, less than 1 millimeter in diameter, hovering inside a device called a Penning trap. The outermost electron of each ion acts as a tiny quantum magnet and is used as a qubit, the quantum equivalent of a “1” or a “0” in a conventional computer. In the benchmarking experiment, physicists used laser beams to cool the ions to near absolute zero. Carefully timed microwave and laser pulses then caused the qubits to interact, mimicking the quantum behavior of materials otherwise very difficult to study in the laboratory. Although the two systems may outwardly appear dissimilar, their behavior is engineered to be mathematically identical. In this way, simulators allow researchers to vary parameters that couldn’t be changed in natural solids, such as atomic lattice spacing and geometry.

Friedenauer et al., adiabatically manipulated 2 spins, showing their separation into ferromagnetic and antiferromagnetic states

Kim et al., extended the trapped ion quantum simulator to 3 spins, with global antiferromagnetic Ising interactions featuring frustration and showing the link between frustration and entanglement

and Islam et al., used adiabatic quantum simulation to demonstrate the sharpening of a phase transition between paramagnetic and ferromagnetic ordering as the number of spins increased from 2 to 9

Barreiro et al. created a digital quantum simulator of interacting spins with up to 5 trapped ions by coupling to an open reservoir ^[15] and

Islam, et al., demonstrated adiabatic quantum simulation of the transverse Ising model with variable (long) range interactions with up to 18 trapped ion spins, showing control of the level of spin frustration by adjusting the antiferromagnetic interaction range

Britton, et al. from NIST has experimentally benchmarked Ising interactions in a system of hundreds of qubits for studies of quantum magnetism.^[18]

Pagano, et al., reported a new cryogenic ion trapping system designed for long time storage of large ion chains demonstrating coherent one and two-qubit operations for chains of up to 44 ions.^[19]

Quantum simulation

Simulators exploit a property of quantum mechanics called superposition, wherein a quantum particle is made to be in two distinct states at the same time, for example, aligned and anti-aligned with an external magnetic field.

Crucially, the simulator can also engineer a second quantum property called entanglement between the qubits, so that even physically well separated particles may be made tightly interconnected.^[2]^[3]^[20]

See also

References

1. ^{{cite journal|doi=10.1140/epjqt10|url=http://www.epjquantumtechnology.com/content/1/1/10|title=What is a quantum simulator?|year=2014|last1=Johnson|first1=Tomi H.|last2=Clark|first2=Stephen R.|last3=Jaksch|first3=Dieter|journal=EPJ Quantum Technology|volume=1|number=10|doi-broken-date=2019-02-11}}
2. ^¹²{{NIST-PD|article=NIST Physicists Benchmark Quantum Simulator with Hundreds of Qubits|Date= May 2, 2012|url=https://www.nist.gov/public_affairs/tech-beat/tb20120502.cfm/|author=Michael E. Newman|accessdate=2013-02-22}}
3. ^¹²{{cite journal|doi=10.1038/nature10981|url=http://tf.boulder.nist.gov/general/pdf/2614.pdf|arxiv=1204.5789 |bibcode = 2012Natur.484..489B|title=Engineered two-dimensional Ising interactions in a trapped-ion quantum simulator with hundreds of spins|year=2012|last1=Britton|first1=Joseph W.|last2=Sawyer|first2=Brian C.|last3=Keith|first3=Adam C.|last4=Wang|first4=C.-C. Joseph|last5=Freericks|first5=James K.|last6=Uys|first6=Hermann|last7=Biercuk|first7=Michael J.|last8=Bollinger|first8=John J.|journal=Nature|volume=484|issue=7395|pages=489–92|pmid=22538611 }} Note: This manuscript is a contribution of the US National Institute of Standards and Technology and is not subject to US copyright.
4. ^{{cite book | author=Manin, Yu. I. | title=Vychislimoe i nevychislimoe | trans-title=Computable and Noncomputable | year=1980 | publisher=Sov.Radio | url=http://publ.lib.ru/ARCHIVES/M/MANIN_Yuriy_Ivanovich/Manin_Yu.I._Vychislimoe_i_nevychislimoe.(1980).%5Bdjv%5D.zip | pages=13–15 | language=Russian | accessdate=2013-03-04 | deadurl=yes | archiveurl=https://web.archive.org/web/20130510173823/http://publ.lib.ru/ARCHIVES/M/MANIN_Yuriy_Ivanovich/Manin_Yu.I._Vychislimoe_i_nevychislimoe.(1980).%5Bdjv%5D.zip | archivedate=2013-05-10 | df=}}
5. ^{{cite journal | last = Feynman | first = Richard | authorlink = Richard Feynman | title = Simulating Physics with Computers | journal = International Journal of Theoretical Physics | volume = 21 | pages = 467–488 | year = 1982 | url = http://www.springerlink.com/content/t2x8115127841630 | doi = 10.1007/BF02650179 | accessdate = 2007-10-19 |bibcode = 1982IJTP...21..467F | issue = 6–7 | citeseerx = 10.1.1.45.9310 }}
6. ^{{Cite journal | title = Universal quantum simulators | url = http://www.sciencemag.org/cgi/content/abstract/273/5278/1073 | year = 1996 | author = Lloyd, S. | journal = Science | pages = 1073–8 | volume = 273 | issue = 5278 | accessdate = 2009-07-08 | doi = 10.1126/science.273.5278.1073 | pmid = 8688088|bibcode = 1996Sci...273.1073L }}
7. ^{{cite arXiv|eprint=quant-ph/0301023 |author1=Dorit Aharonov|author2=Amnon Ta-Shma|title=Adiabatic Quantum State Generation and Statistical Zero Knowledge |year=2003}}
8. ^{{cite journal|last1=Berry | first1=Dominic W.|author2=Graeme Ahokas|author3=Richard Cleve|last4=Sanders | first4=Barry C.|title=Efficient quantum algorithms for simulating sparse Hamiltonians|year=2007|doi=10.1007/s00220-006-0150-x|journal=Communications in Mathematical Physics|volume=270|issue=2|pages=359–371 |arxiv=quant-ph/0508139 |bibcode= 2007CMaPh.270..359B }}
9. ^{{cite journal|last1=Childs |first1=Andrew M. |title=On the relationship between continuous- and discrete-time quantum walk |year=2010 |doi=10.1007/s00220-009-0930-1 |journal=Communications in Mathematical Physics |volume=294 |issue=2 |pages=581–603 |arxiv=0810.0312 |bibcode= 2010CMaPh.294..581C }}
10. ^{{cite journal |author = Kliesch, M. |title=Dissipative Quantum Church-Turing Theorem |year=2011 |doi=10.1103/PhysRevLett.107.120501 |journal=Physical Review Letters |volume=107 |issue=12 |pages=120501 |arxiv= 1105.3986 |bibcode= 2011PhRvL.107l0501K |display-authors=etal|pmid=22026760}}
11. ^Nature Physics Insight – Quantum Simulation. Nature.com. April 2012.
12. ^{{cite journal | url = http://www.nature.com/nphys/journal/v4/n10/abs/nphys1032.html| year = 2008 | author = Friedenauer, J. T.| journal = Nature Physics | doi = 10.1038/nphys1032 | title = Simulating a quantum magnet with trapped ions | volume = 4 | pages = 757–761 |bibcode = 2008NatPh...4..757F | issue=10|display-authors=etal}}
13. ^{{cite journal | url = http://www.nature.com/nature/journal/v465/n7298/nature09071/metrics/citations?page=5| year = 2010 | author = Kim, K.| journal = Nature | doi = 10.1038/nature09071 | accessdate = 2011-02-23 | title = Quantum simulation of frustrated Ising spins with trapped ions | volume = 465 | pages = 590–593 |bibcode = 2010Natur.465..590K | issue=7298 | pmid=20520708|display-authors=etal}}
14. ^{{cite journal | url = http://www.nature.com/ncomms/journal/v2/n7/full/ncomms1374.html| year = 2011 | author = Islam, R.| journal = Nature Communications | doi = 10.1038/ncomms1374 | title = Onset of a quantum phase transition with a trapped ion quantum simulator | volume = 2 | pages = 377 |arxiv = 1103.2400 |bibcode = 2011NatCo...2E.377I | issue=7|display-authors=etal | pmid=21730958}}
15. ^{{cite journal | year = 2011 | author = Barreiro, J. T.| journal = Nature | doi = 10.1038/nature09801 | title = An Open-System Quantum Simulator with Trapped Ions | volume = 470 | issue = 7335 | pages = 486–91 |arxiv = 1104.1146 |bibcode = 2011Natur.470..486B |display-authors=etal | pmid=21350481}}
16. ^{{cite journal | url = http://www.sciencemag.org/content/early/2011/08/31/science.1208001 | year = 2011 | author = Lanyon, B. P.| journal = Science | doi = 10.1126/science.1208001 | title = Universal Digital Quantum Simulation with Trapped Ions | volume = 334 | issue = 6052 | pages = 57–61|arxiv = 1109.1512 |bibcode = 2011Sci...334...57L |display-authors=etal | pmid=21885735}}
17. ^{{cite journal | url = http://www.sciencemag.org/content/340/6132/583.abstract| year = 2013 | author = Islam, R.| journal = Science | doi = 10.1126/science.1232296 | title = Emergence and Frustration of Magnetism with Variable-Range Interactions in a Quantum Simulator | volume = 340 | pages = 583–587 |arxiv = 1210.0142 |bibcode = 2013Sci...340..583I | issue=6132|display-authors=etal | pmid=23641112}}
18. ^{{cite journal | url = https://www.nist.gov/pml/div688/qubits-042512.cfm | year = 2012 | author = Britton, J.W.| journal = Nature | doi = 10.1038/nature10981 | accessdate = 2012-04-28 | title = Engineered two-dimensional Ising interactions in a trapped-ion quantum simulator with hundreds of spins | volume = 484 | issue = 7395 | pages = 489–492 | arxiv=1204.5789 |bibcode = 2012Natur.484..489B | pmid=22538611|display-authors=etal}}
19. ^{{cite journal | year = 2019 | author = Pagano, G.| journal = Quantum Science and Technology | doi = 10.1088/2058-9565/aae0fe | title = Cryogenic trapped-ion system for large scale quantum simulation | volume = 4 | issue = | pages = 014004 |bibcode = | pmid=|display-authors=etal}}
20. ^{{cite journal|doi=10.1038/nphys2275|url= http://211.144.68.84:9998/91keshi/Public/File/34/8-4/pdf/nphys2275.pdf|bibcode= 2012NatPh...8..264C|title=Goals and opportunities in quantum simulation|year=2012|last1=Cirac|first1=J. Ignacio|last2=Zoller|first2=Peter|journal=Nature Physics|volume=8|issue=4|pages=264–266}}

Solving physics problems

The trapped-ion simulator

Quantum simulation

See also

References

External links