Quantum memory

Last updated

In quantum computing, quantum memory is the quantum-mechanical version of ordinary computer memory. Whereas ordinary memory stores information as binary states (represented by "1"s and "0"s), quantum memory stores a quantum state for later retrieval. These states hold useful computational information known as qubits. Unlike the classical memory of everyday computers, the states stored in quantum memory can be in a quantum superposition, giving much more practical flexibility in quantum algorithms than classical information storage.

Contents

Quantum memory is essential for the development of many devices in quantum information processing, including a synchronization tool that can match the various processes in a quantum computer, a quantum gate that maintains the identity of any state, and a mechanism for converting predetermined photons into on-demand photons. Quantum memory can be used in many aspects, such as quantum computing and quantum communication. Continuous research and experiments have enabled quantum memory to realize the storage of qubits. [1]

Background and history

The interaction of quantum radiation with multiple particles has sparked scientific interest over the past decade.[ needs context ] Quantum memory is one such field, mapping the quantum state of light onto a group of atoms and then restoring it to its original shape. Quantum memory is a key element in information processing, such as optical quantum computing and quantum communication, while opening a new way for the foundation of light-atom interaction. However, restoring the quantum state of light is no easy task. While impressive progress has been made, researchers are still working to make it happen. [2]

Quantum memory based on the quantum exchange to store photon qubits has been demonstrated to be possible. Kessel and Moiseev [3] discussed quantum storage in the single photon state in 1993. The experiment was analyzed in 1998 and demonstrated in 2003. In summary, the study of quantum storage in the single photon state can be regarded as the product of the classical optical data storage technology proposed in 1979 and 1982, an idea inspired by the high density of data storage in the mid-1970s[ citation needed ]. Optical data storage can be achieved by using absorbers to absorb different frequencies of light, which are then directed to beam space points and stored.

Types

Atomic Gas Quantum Memory

Normal, classical optical signals are transmitted by varying the amplitude of light. In this case, a piece of paper, or a computer hard disk, can be used to store information on the lamp[ clarification needed ]. In the quantum information scenario, however, the information may be encoded according to the amplitude and phase of the light. For some signals, you cannot measure both the amplitude and phase of the light without interfering with the signal. To store quantum information, light itself needs to be stored without being measured. An atomic gas quantum memory is recording the state of light into the atomic cloud. When light's information is stored by atoms, relative amplitude and phase of light is mapped to atoms and can be retrieved on-demand. [4]

Solid Quantum Memory

In classical computing, memory is a trivial resource that can be replicated in long-lived memory hardware and retrieved later for further processing. In quantum computing, this is forbidden because, according to the no clone theorem, any quantum state cannot be reproduced completely. Therefore, in the absence of quantum error correction, the storage of qubits is limited by the internal coherence time of the physical qubits holding the information. "Quantum memory" beyond the given physical qubit storage limits will be a quantum information transmission to "storing qubits" not easily affected by environmental noise and other factors. The information would later be transferred back to the preferred "process qubits" to allow rapid operations or reads. [5]

Navg1.png

Discovery

Optical quantum memory is usually used to detect and store single photon quantum states. However, producing efficient memory of this kind is still a huge challenge for current science. A single photon is so low in energy as to be lost in a complex light background. These problems have long kept quantum storage rates below 50%. A team led by professor Du Shengwang of the department of physics at the Hong Kong University of science and technology [6] and William Mong Institute of Nano Science and Technology at HKUST [7] has found a way to increase the efficiency of optical quantum memory to more than 85 percent. The discovery also brings the popularity of quantum computers closer to reality. At the same time, the quantum memory can also be used as a repeater in the quantum network, which lays the foundation for the quantum Internet.

Research and application

Quantum memory is an important component of quantum information processing applications such as quantum network, quantum repeater, linear optical quantum computation or long-distance quantum communication. [8]

Optical data storage has been an important research topic for many years. Its most interesting function is the use of the laws of quantum physics to protect data from theft, through quantum computing and quantum cryptography unconditionally guaranteed communication security. [9]

They allow particles to be superimposed and in a superposition state, which means they can represent multiple combinations at the same time. These particles are called quantum bits, or qubits. From a cybersecurity perspective, the magic of qubits is that if a hacker tries to observe them in transit, their fragile quantum states shatter. This means it is impossible for hackers to tamper with network data without leaving a trace. Now, many companies are taking advantage of this feature to create networks that transmit highly sensitive data. In theory, these networks are secure. [10]

Microwave storage and light learning microwave conversion

The nitrogen-vacancy center in diamond has attracted a lot of research in the past decade due to its excellent performance in optical nanophotonic devices. In a recent experiment, electromagnetically induced transparency was implemented on a multi-pass diamond chip to achieve full photoelectric magnetic field sensing. Despite these closely related experiments, optical storage has yet to be implemented in practice. The existing nitrogen-vacancy center (negative charge and neutral nitrogen-vacancy center) energy level structure makes the optical storage of the diamond nitrogen-vacancy center possible.

The coupling between the nitrogen-vacancy spin ensemble and superconducting qubits provides the possibility for microwave storage of superconducting qubits. Optical storage combines the coupling of electron spin state and superconducting quantum bits, which enables the nitrogen-vacancy center in diamond to play a role in the hybrid quantum system of the mutual conversion of coherent light and microwave. [11]

Orbital angular momentum is stored in alkali vapor

Large resonant light depth is the premise of constructing efficient quantum-optical memory. Alkali metal vapor isotopes of a large number of near-infrared wavelength optical depth, because they are relatively narrow spectrum line and the number of high density in the warm temperature of 50-100 ∘ C. Alkali vapors have been used in some of the most important memory developments, from early research to the latest results we are discussing, due to their high optical depth, long coherent time and easy near-infrared optical transition.

Because of its high information transmission ability, people are more and more interested in its application in the field of quantum information. Structured light can carry orbital angular momentum, which must be stored in the memory to faithfully reproduce the stored structural photons. An atomic vapor quantum memory is ideal for storing such beams because the orbital angular momentum of photons can be mapped to the phase and amplitude of the distributed integration excitation. Diffusion is a major limitation of this technique because the motion of hot atoms destroys the spatial coherence of the storage excitation. Early successes included storing weakly coherent pulses of spatial structure in a warm, ultracold atomic whole. In one experiment, the same group of scientists in a caesium magneto-optical trap was able to store and retrieve vector beams at the single-photon level. [12] The memory preserves the rotation invariance of the vector beam, making it possible to use it in conjunction with qubits encoded for maladjusted immune quantum communication.

The first storage structure, a real single photon, was achieved with electromagnetically induced transparency in rubidium magneto-optical trap. The predicted single photon generated by spontaneous four-wave mixing in one magneto-optical trap is prepared by an orbital angular momentum unit using spiral phase plates, stored in the second magneto-optical trap and recovered. The dual-orbit setup also proves coherence in multimode memory, where a preannounced single photon stores the orbital angular momentum superposition state for 100 nanoseconds. [11]

Optical Quantum KennedyReceiver.png
Optical Quantum

GEM

GEM (Gradient Echo Memory) is a protocol for storing optical information and it can be applied to both atomic gas and solid-state memories. The idea was first demonstrated by researchers at ANU. The experiment in a three-level system based on hot atomic vapor resulted in demonstration of coherent storage with efficiency up to 87%. [13]

Electromagnetically induced transparency

Electromagnetically induced transparency (EIT) was first introduced by Harris and his colleagues at Stanford University in 1990. [14] The work showed that when a laser beam causes a quantum interference between the excitation paths, the optical response of the atomic medium is modified to eliminate absorption and refraction at the resonant frequencies of atomic transitions. Slow light, optical storage, and quantum memories can be achieved based on EIT. In contrast to other approaches, EIT has a long storage time and is a relatively easy and inexpensive solution to implement. For example, electromagnetically induced transparency does not require the very high power control beams usually needed for Raman quantum memories, nor does it require the use of liquid helium temperatures. In addition, photon echo can read EIT while the spin coherence survives due to the time delay of readout pulse caused by a spin recovery in non-uniformly broadened media. Although there are some limitations on operating wavelength, bandwidth, and mode capacity, techniques have been developed to make EIT-based quantum memories a valuable tool in the development of quantum telecommunication systems. [11] In 2018, a highly efficient EIT-based optical memory in cold atom demonstrated a 92% storage-and-retrieval efficiency in the classical regime with coherent beams [15] and a 70% storage-and-retrieval efficiency was demonstrated for polarization qubits encoded in weak coherent states, beating any classical benchmark. [16] Following these demonstrations, single-photon polarization qubits were then stored via EIT in a 85Rb cold atomic ensemble and retrieved with an 85% efficiency [17] and entanglement between two cesium-based quantum memories was also achieved with an overall transfer efficiency close to 90%. [18]

Crystals doped with rare earth

The mutual transformation of quantum information between light and matter is the focus of quantum informatics. The interaction between a single photon and a cooled crystal doped with rare earth ions is investigated. Crystals doped with rare earth have broad application prospects in the field of quantum storage because they provide a unique application system. [19] Li Chengfeng from the quantum information laboratory of the Chinese Academy of Sciences developed a solid-state quantum memory and demonstrated the photon computing function using time and frequency. Based on this research, a large-scale quantum network based on quantum repeater can be constructed by utilizing the storage and coherence of quantum states in the material system. Researchers have shown for the first time in rare-earth ion-doped crystals. By combining the three-dimensional space with two-dimensional time and two-dimensional spectrum, a kind of memory that is different from the general one is created. It has the multimode capacity and can also be used as a high fidelity quantum converter. Experimental results show that in all these operations, the fidelity of the three-dimensional quantum state carried by the photon can be maintained at around 89%. [20]

Raman scattering in solids

Diamond has very high Raman gain in optical phonon mode of 40 THz and has a wide transient window in a visible and near-infrared band, which makes it suitable for being an optical memory with a very wide band. After the Raman storage interaction, the optical phonon decays into a pair of photons through the channel, and the decay lifetime is 3.5 ps, which makes the diamond memory unsuitable for communication protocol.

Nevertheless, diamond memory has allowed some revealing studies of the interactions between light and matter at the quantum level: optical phonons in a diamond can be used to demonstrate emission quantum memory, macroscopic entanglement, pre-predicted single-photon storage, and single-photon frequency manipulation. [11]

Future development

For quantum memory, quantum communication and cryptography are the future research directions. However, there are many challenges to building a global quantum network. One of the most important challenges is to create memories that can store the quantum information carried by light. Researchers at the University of Geneva in Switzerland working with France's CNRS have discovered a new material in which an element called ytterbium can store and protect quantum information, even at high frequencies. This makes ytterbium an ideal candidate for future quantum networks. Because signals cannot be replicated, scientists are now studying how quantum memories can be made to travel farther and farther by capturing photons to synchronize them. In order to do this, it becomes important to find the right materials for making quantum memories. Ytterbium is a good insulator and works at high frequencies so that photons can be stored and quickly restored.

See also

Related Research Articles

<span class="mw-page-title-main">Quantum teleportation</span> Physical phenomenon

Quantum teleportation is a technique for transferring quantum information from a sender at one location to a receiver some distance away. While teleportation is commonly portrayed in science fiction as a means to transfer physical objects from one location to the next, quantum teleportation only transfers quantum information. The sender does not have to know the particular quantum state being transferred. Moreover, the location of the recipient can be unknown, but to complete the quantum teleportation, classical information needs to be sent from sender to receiver. Because classical information needs to be sent, quantum teleportation cannot occur faster than the speed of light.

This is a timeline of quantum computing.

<span class="mw-page-title-main">Electromagnetically induced transparency</span>

Electromagnetically induced transparency (EIT) is a coherent optical nonlinearity which renders a medium transparent within a narrow spectral range around an absorption line. Extreme dispersion is also created within this transparency "window" which leads to "slow light", described below. It is in essence a quantum interference effect that permits the propagation of light through an otherwise opaque atomic medium.

<span class="mw-page-title-main">Lene Hau</span> Danish physicist and educator (born 1959)

Lene Vestergaard Hau is a Danish physicist and educator. She is the Mallinckrodt Professor of Physics and of Applied Physics at Harvard University.

Atomic coherence is the induced coherence between levels of a multi-level atomic system.

<span class="mw-page-title-main">Trapped-ion quantum computer</span> Proposed quantum computer implementation

A trapped-ion quantum computer is one proposed approach to a large-scale quantum computer. Ions, or charged atomic particles, can be confined and suspended in free space using electromagnetic fields. Qubits are stored in stable electronic states of each ion, and quantum information can be transferred through the collective quantized motion of the ions in a shared trap. Lasers are applied to induce coupling between the qubit states or coupling between the internal qubit states and the external motional states.

Quantum networks form an important element of quantum computing and quantum communication systems. Quantum networks facilitate the transmission of information in the form of quantum bits, also called qubits, between physically separated quantum processors. A quantum processor is a small quantum computer being able to perform quantum logic gates on a certain number of qubits. Quantum networks work in a similar way to classical networks. The main difference is that quantum networking, like quantum computing, is better at solving certain problems, such as modeling quantum systems.

Time-bin encoding is a technique used in quantum information science to encode a qubit of information on a photon. Quantum information science makes use of qubits as a basic resource similar to bits in classical computing. Qubits are any two-level quantum mechanical system; there are many different physical implementations of qubits, one of which is time-bin encoding.

<span class="mw-page-title-main">Nitrogen-vacancy center</span> Point defect in diamonds

The nitrogen-vacancy center is one of numerous photoluminescent point defects in diamond. Its most explored and useful properties include its spin-dependent photoluminescence, and its relatively long (millisecond) spin coherence at room temperature. The NV center energy levels are modified by magnetic fields, electric fields, temperature, and strain, which allow it to serve as a sensor of a variety of physical phenomena. Its atomic size and spin properties can form the basis for useful quantum sensors. It has also been explored for applications in quantum computing and spintronics.

Within quantum technology, a quantum sensor utilizes properties of quantum mechanics, such as quantum entanglement, quantum interference, and quantum state squeezing, which have optimized precision and beat current limits in sensor technology. The field of quantum sensing deals with the design and engineering of quantum sources and quantum measurements that are able to beat the performance of any classical strategy in a number of technological applications. This can be done with photonic systems or solid state systems.

Single-photon sources are light sources that emit light as single particles or photons. These sources are distinct from coherent light sources (lasers) and thermal light sources such as incandescent light bulbs. The Heisenberg uncertainty principle dictates that a state with an exact number of photons of a single frequency cannot be created. However, Fock states can be studied for a system where the electric field amplitude is distributed over a narrow bandwidth. In this context, a single-photon source gives rise to an effectively one-photon number state. Photons from an ideal single-photon source exhibit quantum mechanical characteristics. These characteristics include photon antibunching, so that the time between two successive photons is never less than some minimum value. This behaviour is normally demonstrated by using a beam splitter to direct about half of the incident photons toward one avalanche photodiode, and half toward a second. Pulses from one detector are used to provide a ‘counter start’ signal, to a fast electronic timer, and the other, delayed by a known number of nanoseconds, is used to provide a ‘counter stop’ signal. By repeatedly measuring the times between ‘start’ and ‘stop’ signals, one can form a histogram of time delay between two photons and the coincidence count- if bunching is not occurring, and photons are indeed well spaced, a clear notch around zero delay is visible.

Quantum metamaterials extend the science of metamaterials to the quantum level. They can control electromagnetic radiation by applying the rules of quantum mechanics. In the broad sense, a quantum metamaterial is a metamaterial in which certain quantum properties of the medium must be taken into account and whose behaviour is thus described by both Maxwell's equations and the Schrödinger equation. Its behaviour reflects the existence of both EM waves and matter waves. The constituents can be at nanoscopic or microscopic scales, depending on the frequency range .

Zachary John Dutton is an American physicist who has worked on research centred mainly around cold atomic gases, EIT, low light level nonlinear optics, quantum memories, and coherent optical. Dutton graduated from Lindsay High School in Lindsay CA, and was awarded a BSc in physics from UC Berkeley in 1996. He was awarded his PhD in theoretical physics at Harvard University in 2000. His doctoral advisor was Prof.Lene Hau for his thesis entitled "Ultra-slow, stopped, and compressed light in Bose–Einstein condensates" He worked on a number of papers with Hau and Cyrus Behroozi, being amongst the first group to stop light completely. He undertook postdoctoral work at NIST–Gaithersburg with Dr. Charles Clark, prior to becoming a staff physicist at the Naval Research Lab in Washington. He conducted research centred mainly around cold atomic gases, EIT, low light level nonlinear optics, quantum memories, and coherent optical storage.

In quantum mechanics, the cat state, named after Schrödinger's cat, is a quantum state composed of two diametrically opposed conditions at the same time, such as the possibilities that a cat is alive and dead at the same time.

<span class="mw-page-title-main">Christopher Monroe</span> American physicist

Christopher Roy Monroe is an American physicist and engineer in the areas of atomic, molecular, and optical physics and quantum information science, especially quantum computing. He directs one of the leading research and development efforts in ion trap quantum computing. Monroe is the Gilhuly Family Presidential Distinguished Professor of Electrical and Computer Engineering and Physics at Duke University and is College Park Professor of Physics at the University of Maryland and Fellow of the Joint Quantum Institute and Joint Center for Quantum Computer Science. He is also co-founder and chief scientist at IonQ, Inc.

Linear optical quantum computing or linear optics quantum computation (LOQC) is a paradigm of quantum computation, allowing universal quantum computation. LOQC uses photons as information carriers, mainly uses linear optical elements, or optical instruments to process quantum information, and uses photon detectors and quantum memories to detect and store quantum information.

The DiVincenzo criteria are conditions necessary for constructing a quantum computer, conditions proposed in 2000 by the theoretical physicist David P. DiVincenzo, as being those necessary to construct such a computer—a computer first proposed by mathematician Yuri Manin, in 1980, and physicist Richard Feynman, in 1982—as a means to efficiently simulate quantum systems, such as in solving the quantum many-body problem.

<span class="mw-page-title-main">Silicon carbide color centers</span> Crystal defect

Silicon carbide color centers are point defects in the crystal lattice of silicon carbide, which are known as color centers. These color centers have multiple uses, some of which are in photonics, semiconductors, and quantum applications like metrology and quantum communication. Defects in materials have a plethora of applications, but the reason defects, or color centers in silicon carbide are significant is due to many important properties of these color centers. Silicon carbide as a material has second-order nonlinearity, as well as optical transparency and low two-photon absorption. This makes silicon carbide viable to be an alternate platform for many things, including but not limited to nanofabrication, integrated quantum photonics, and quantum systems in large-scale wafers.

References

  1. Lvovsky AI, Sanders BC, Tittel W (December 2009). "Optical quantum memory". Nature Photonics. 3 (12): 706–714. Bibcode:2009NaPho...3..706L. doi:10.1038/nphoton.2009.231. ISSN   1749-4893. S2CID   4661175.
  2. Le Gouët JL, Moiseev S (2012). "Quantum Memory". Journal of Physics B: Atomic, Molecular and Optical Physics. 45 (12): 120201. doi: 10.1088/0953-4075/45/12/120201 .
  3. Ohlsson N, Kröll S, Moiseev SA (2003). "Delayed single-photon self-interference — A double slit experiment in the time domain". In Bigelow NP, Eberly JH, Stroud CR, Walmsley IA (eds.). Coherence and Quantum Optics VIII. Springer US. pp. 383–384. doi:10.1007/978-1-4419-8907-9_80. ISBN   9781441989079.
  4. Hosseini M, Sparkes B, Hétet G, et al. (2009). "Coherent optical pulse sequencer for quantum applications". Nature. 461 (7261): 241–245. Bibcode:2009Natur.461..241H. doi:10.1038/nature08325. PMID   19741705. S2CID   1077208.
  5. Freer S, Simmons S, Laucht A, Muhonen JT, Dehollain JP, Kalra R, et al. (2016). "A single-atom quantum memory in silicon". Quantum Science and Technology. 2: 015009. arXiv: 1608.07109 . doi:10.1088/2058-9565/aa63a4. S2CID   118590076.
  6. "Shengwang Du Group | Atom and Quantum Optics Lab" . Retrieved 2019-05-12.
  7. "RC02_William Mong Institute of Nano Science and Technology | Institutes and Centers | Research Institutes and Centers | Research | HKUST Department of Physics". physics.ust.hk. Retrieved 2019-05-12.
  8. "Quantum memories [GAP-Optique]". www.unige.ch. Retrieved 2019-05-12.
  9. Tittel W, Afzelius M, Chaneliere T, Cone RL, Kröll S, Moiseev SA, Sellars M (2010). "Photon-echo quantum memory in solid state systems". Laser & Photonics Reviews. 4 (2): 244–267. Bibcode:2010LPRv....4..244T. doi:10.1002/lpor.200810056. ISSN   1863-8899. S2CID   120294578.
  10. "Quantum Communication | PicoQuant". www.picoquant.com. Retrieved 2019-05-12.
  11. 1 2 3 4 Heshami K, England DG, Humphreys PC, Bustard PJ, Acosta VM, Nunn J, Sussman BJ (November 2016). "Quantum memories: emerging applications and recent advances". Journal of Modern Optics. 63 (20): 2005–2028. doi:10.1080/09500340.2016.1148212. PMC   5020357 . PMID   27695198.
  12. Nicolas A, Veissier L, Giner L, Giacobino E, Maxein D, Laurat J (March 2014). "A quantum memory for orbital angular momentum photonic qubits". Nature Photonics. 8 (3): 234–238. arXiv: 1308.0238 . Bibcode:2014NaPho...8..234N. doi:10.1038/nphoton.2013.355. S2CID   118585951.
  13. Hosseini M, Sparkes B, Campbell G, et al. (2011). "High efficiency coherent optical memory with warm rubidium vapour". Nat Commun. 2: 174. arXiv: 1009.0567 . Bibcode:2011NatCo...2..174H. doi:10.1038/ncomms1175. PMC   3105315 . PMID   21285952. S2CID   6545778.
  14. Harris SE, Field JE, Imamoglu A (March 1990). "Nonlinear optical processes using electromagnetically induced transparency". Physical Review Letters. American Physical Society (APS). 64 (10): 1107–1110. Bibcode:1990PhRvL..64.1107H. doi:10.1103/physrevlett.64.1107. PMID   10041301.
  15. Hsiao YF, Tsai PJ, Chen HS, Lin SX, Hung CC, Lee CH, et al. (May 2018). "Highly Efficient Coherent Optical Memory Based on Electromagnetically Induced Transparency". Physical Review Letters. 120 (18): 183602. arXiv: 1605.08519 . Bibcode:2018PhRvL.120r3602H. doi:10.1103/PhysRevLett.120.183602. PMID   29775362. S2CID   21741318.
  16. Vernaz-Gris P, Huang K, Cao M, Sheremet AS, Laurat J (January 2018). "Highly-efficient quantum memory for polarization qubits in a spatially-multiplexed cold atomic ensemble". Nature Communications. 9 (1): 363. arXiv: 1707.09372 . Bibcode:2018NatCo...9..363V. doi: 10.1038/s41467-017-02775-8 . PMC   5785556 . PMID   29371593.
  17. Wang Y, Li J, Zhang S, Su K, Zhou Y, Liao K, Du S, Yan H, Zhu SL (March 2019). "Efficient quantum memory for single-photon polarization qubits". Nature Photonics. 13 (5): 346–351. arXiv: 2004.03123 . Bibcode:2019NaPho..13..346W. doi:10.1038/s41566-019-0368-8. S2CID   126945158.
  18. Cao M, Hoffet F, Qiu S, Sheremet AS, Laurat J (2020-10-20). "Efficient reversible entanglement transfer between light and quantum memories". Optica. 7 (10): 1440–1444. arXiv: 2007.00022 . Bibcode:2020Optic...7.1440C. doi: 10.1364/OPTICA.400695 .
  19. "Solid State Quantum Memories | QPSA @ ICFO". qpsa.icfo.es. Retrieved 2019-05-12.
  20. Simon C, Afzelius M, Appel J, de la Giroday AB, Dewhurst SJ, Gisin N, Hu CY, Jelezko F, Kröll S (2010-05-01). "Quantum memories". The European Physical Journal D. 58 (1): 1–22. arXiv: 1003.1107 . doi:10.1140/epjd/e2010-00103-y. ISSN   1434-6079. S2CID   11793247.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.