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Quantum simulator

April 12, 2024

Quantum simulators permit the study of a quantum system in a programmable fashion. In this instance, simulators are special purpose devices designed to provide insight about specific physics problems.[1][2][3] Quantum simulators may be contrasted with generally programmable "digital" quantum computers, which would be capable of solving a wider class of quantum problems.

In this photograph of a quantum simulator crystal the ions are fluorescing, indicating the qubits are all in the same state (either "1" or "0"). Under the right experimental conditions, the ion crystal spontaneously forms this nearly perfect triangular lattice structure. Credit: Britton/NIST
Trapped ion quantum simulator illustration: The heart of the simulator is a two-dimensional crystal of beryllium ions (blue spheres in the graphic); the outermost electron of each ion is a quantum bit (qubit, red arrows). The ions are confined by a large magnetic field in a device called a Penning trap (not shown). Inside the trap the crystal rotates clockwise. Credit: Britton/NIST

A universal quantum simulator is a quantum computer proposed by Yuri Manin in 1980[4] and Richard Feynman in 1982.[5]

A quantum system may be simulator by either a Turing machine or a quantum Turing machine, as a classical Turing machine is able to simulate a universal quantum computer (and therefore any simpler quantum simulator), meaning they are equivalent from the point of view of computability theory. In other words, quantum computers provide no additional power over classical computers in terms of computability. However, it is suspected that they can solve certain problems faster than classical computers, meaning they may be in different complexity classes, which is why quantum Turing machines may be useful for simulating quantum systems.

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.[5] This has been extended to much larger classes of quantum systems.[6][7][8][9]

Quantum simulators have been realized on a number of experimental platforms, including systems of ultracold quantum gases, polar molecules, trapped ions, photonic systems, quantum dots, and superconducting circuits.[10]

Solving physics problems edit

Many important problems in physics, especially low-temperature physics and many-body 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 because the dimension of the Hilbert space grows exponentially with particle number.[11] 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] Quantum simulators provide an alternative route to understanding the properties of these systems. These simulators create clean realizations of specific systems of interest, which allows precise realizations of their properties. Precise control over and broad tunability of parameters of the system allows the influence of various parameters to be cleanly disentangled.

Quantum simulators can solve problems which are difficult to simulate on classical computers because they directly exploit quantum properties of real particles. In particular, they 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, simulators also take advantage of a second quantum property called entanglement, allowing the behavior of even physically well separated particles to be correlated.[2][3][12]

Recently quantum simulators have been used to obtain time crystals[13][14] and quantum spin liquids.[15][16]

Trapped-ion simulators edit

Ion trap based system forms an ideal setting for simulating interactions in quantum spin models.[17] A trapped-ion simulator, built by a team that included the NIST can engineer and control interactions among hundreds of quantum bits (qubits).[18] Previous endeavors were unable to go beyond 30 quantum bits. The capability of this simulator is 10 times more than previous devices. 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.

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.[19] 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[20] 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.[21] Barreiro et al. created a digital quantum simulator of interacting spins with up to 5 trapped ions by coupling to an open reservoir[22] and Lanyon et al. demonstrated digital quantum simulation with up to 6 ions.[23] 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.[24] 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.[25] Joshi, et al., probed the quantum dynamics of 51 individually controlled ions, realizing a long-range interacting spin chain.[26]

Ultracold atom simulators edit

Many ultracold atom experiments are examples of quantum simulators. These include experiments studying bosons or fermions in optical lattices, the unitary Fermi gas, Rydberg atom arrays in optical tweezers. A common thread for these experiments is the capability of realizing generic Hamiltonians, such as the Hubbard or transverse-field Ising Hamiltonian. Major aims of these experiments include identifying low-temperature phases or tracking out-of-equilibrium dynamics for various models, problems which are theoretically and numerically intractable.[27][28] Other experiments have realized condensed matter models in regimes which are difficult or impossible to realize with conventional materials, such as the Haldane model and the Harper-Hofstadter model.[29][30][31][32][33]

Superconducting qubits edit

Quantum simulators using superconducting qubits fall into two main categories. First, so called quantum annealers determine ground states of certain Hamiltonians after an adiabatic ramp. This approach is sometimes called adiabatic quantum computing. Second, many systems emulate specific Hamiltonians and study their ground state properties, quantum phase transitions, or time dynamics.[34] Several important recent results include the realization of a Mott insulator in a driven-dissipative Bose-Hubbard system and studies of phase transitions in lattices of superconducting resonators coupled to qubits.[35][36]

See also edit

References edit

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External links edit

    April 12, 2024
    quantum, simulator, permit, study, quantum, system, programmable, fashion, this, instance, simulators, special, purpose, devices, designed, provide, insight, about, specific, physics, problems, contrasted, with, generally, programmable, digital, quantum, compu. Quantum simulators permit the study of a quantum system in a programmable fashion In this instance simulators are special purpose devices designed to provide insight about specific physics problems 1 2 3 Quantum simulators may be contrasted with generally programmable digital quantum computers which would be capable of solving a wider class of quantum problems In this photograph of a quantum simulator crystal the ions are fluorescing indicating the qubits are all in the same state either 1 or 0 Under the right experimental conditions the ion crystal spontaneously forms this nearly perfect triangular lattice structure Credit Britton NISTTrapped ion quantum simulator illustration The heart of the simulator is a two dimensional crystal of beryllium ions blue spheres in the graphic the outermost electron of each ion is a quantum bit qubit red arrows The ions are confined by a large magnetic field in a device called a Penning trap not shown Inside the trap the crystal rotates clockwise Credit Britton NISTA universal quantum simulator is a quantum computer proposed by Yuri Manin in 1980 4 and Richard Feynman in 1982 5 A quantum system may be simulator by either a Turing machine or a quantum Turing machine as a classical Turing machine is able to simulate a universal quantum computer and therefore any simpler quantum simulator meaning they are equivalent from the point of view of computability theory In other words quantum computers provide no additional power over classical computers in terms of computability However it is suspected that they can solve certain problems faster than classical computers meaning they may be in different complexity classes which is why quantum Turing machines may be useful for simulating quantum systems 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 5 This has been extended to much larger classes of quantum systems 6 7 8 9 Quantum simulators have been realized on a number of experimental platforms including systems of ultracold quantum gases polar molecules trapped ions photonic systems quantum dots and superconducting circuits 10 Contents 1 Solving physics problems 2 Trapped ion simulators 3 Ultracold atom simulators 4 Superconducting qubits 5 See also 6 References 7 External linksSolving physics problems editMany important problems in physics especially low temperature physics and many body 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 because the dimension of the Hilbert space grows exponentially with particle number 11 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 Quantum simulators provide an alternative route to understanding the properties of these systems These simulators create clean realizations of specific systems of interest which allows precise realizations of their properties Precise control over and broad tunability of parameters of the system allows the influence of various parameters to be cleanly disentangled Quantum simulators can solve problems which are difficult to simulate on classical computers because they directly exploit quantum properties of real particles In particular they 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 simulators also take advantage of a second quantum property called entanglement allowing the behavior of even physically well separated particles to be correlated 2 3 12 Recently quantum simulators have been used to obtain time crystals 13 14 and quantum spin liquids 15 16 Trapped ion simulators editIon trap based system forms an ideal setting for simulating interactions in quantum spin models 17 A trapped ion simulator built by a team that included the NIST can engineer and control interactions among hundreds of quantum bits qubits 18 Previous endeavors were unable to go beyond 30 quantum bits The capability of this simulator is 10 times more than previous devices 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 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 19 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 20 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 21 Barreiro et al created a digital quantum simulator of interacting spins with up to 5 trapped ions by coupling to an open reservoir 22 and Lanyon et al demonstrated digital quantum simulation with up to 6 ions 23 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 24 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 25 Joshi et al probed the quantum dynamics of 51 individually controlled ions realizing a long range interacting spin chain 26 Ultracold atom simulators editMany ultracold atom experiments are examples of quantum simulators These include experiments studying bosons or fermions in optical lattices the unitary Fermi gas Rydberg atom arrays in optical tweezers A common thread for these experiments is the capability of realizing generic Hamiltonians such as the Hubbard or transverse field Ising Hamiltonian Major aims of these experiments include identifying low temperature phases or tracking out of equilibrium dynamics for various models problems which are theoretically and numerically intractable 27 28 Other experiments have realized condensed matter models in regimes which are difficult or impossible to realize with conventional materials such as the Haldane model and the Harper Hofstadter model 29 30 31 32 33 Superconducting qubits editQuantum simulators using superconducting qubits fall into two main categories First so called quantum annealers determine ground states of certain Hamiltonians after an adiabatic ramp This approach is sometimes called adiabatic quantum computing Second many systems emulate specific Hamiltonians and study their ground state properties quantum phase transitions or time dynamics 34 Several important recent results include the realization of a Mott insulator in a driven dissipative Bose Hubbard system and studies of phase transitions in lattices of superconducting resonators coupled to qubits 35 36 See also editHamiltonian simulation Quantum Turing machine Quantum computingReferences edit Johnson Tomi H Clark Stephen R Jaksch Dieter 2014 What is a quantum simulator EPJ Quantum Technology 1 10 arXiv 1405 2831 doi 10 1140 epjqt10 S2CID 120250321 a b c nbsp This article incorporates public domain material from Michael E Newman NIST Physicists Benchmark Quantum Simulator with Hundreds of Qubits National Institute of Standards and Technology Retrieved 2013 02 22 a b c Britton Joseph W Sawyer Brian C Keith Adam C Wang C C Joseph Freericks James K Uys Hermann Biercuk Michael J Bollinger John J 2012 Engineered two dimensional Ising interactions in a trapped ion quantum simulator with hundreds of spins PDF Nature 484 7395 489 92 arXiv 1204 5789 Bibcode 2012Natur 484 489B doi 10 1038 nature10981 PMID 22538611 S2CID 4370334 Note This manuscript is a contribution of the US National Institute of Standards and Technology and is not subject to US copyright Manin Yu I 1980 Vychislimoe i nevychislimoe Computable and Noncomputable in Russian Sov Radio pp 13 15 Archived from the original on 2013 05 10 Retrieved 2013 03 04 a b Feynman Richard 1982 Simulating Physics with Computers International Journal of Theoretical Physics 21 6 7 467 488 Bibcode 1982IJTP 21 467F CiteSeerX 10 1 1 45 9310 doi 10 1007 BF02650179 S2CID 124545445 Dorit Aharonov Amnon Ta Shma 2003 Adiabatic Quantum State Generation and Statistical Zero Knowledge arXiv quant ph 0301023 Berry Dominic W Graeme Ahokas Richard Cleve Sanders Barry C 2007 Efficient quantum algorithms for simulating sparse Hamiltonians Communications in Mathematical Physics 270 2 359 371 arXiv quant 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