Quantum technology

Quantum technology is an emerging field of physics and engineering, encompassing technologies that rely on the properties of quantum mechanics,^[1] especially quantum entanglement, quantum superposition, and quantum tunneling. Quantum computing, sensors, cryptography, simulation, measurement, and imaging are all examples of emerging quantum technologies. The development of quantum technology also heavily impacts established fields such as space exploration.^[2]

Colloidal quantum dots irradiated with a UV light. Different sized quantum dots emit different colour light due to quantum confinement.

Secure communications

Main article: Quantum communication

Quantum secure communication is a method that is expected to be 'quantum safe' in the advent of quantum computing systems that could break current cryptography systems using methods such as Shor's algorithm. These methods include quantum key distribution (QKD), a method of transmitting information using entangled light in a way that makes any interception of the transmission obvious to the user. Another method is the quantum random number generator, which is capable of producing truly random numbers unlike non-quantum algorithms that merely imitate randomness.^[3]

Computing

Main article: Quantum computing

Quantum computers are expected to have a number of important uses in computing fields such as optimization and machine learning. They are perhaps best known for their expected ability to carry out Shor's algorithm, which can be used to factorize large numbers and is an important process in the securing of data transmissions.

Quantum simulators

Main article: Quantum simulator

Quantum simulators are types of quantum computers used to simulate a real world system and can be used to simulate chemical compounds or solve high energy physics problems.^[4][5] Quantum simulators are simpler to build as opposed to general purpose quantum computers because complete control over every component is not necessary.^[4] Current quantum simulators under development include ultracold atoms in optical lattices, trapped ions, arrays of superconducting qubits, and others.^[4]

Sensors

Main article: Quantum sensor

Quantum sensors are expected to have a number of applications in a wide variety of fields including positioning systems, communication technology, electric and magnetic field sensors, gravimetry^[6] as well as geophysical areas of research such as civil engineering^[7] and seismology.

History

The field of quantum technology was first outlined in a 1997 book by Gerard J. Milburn,^[8] which was then followed by a 2003 article by Jonathan P. Dowling and Gerard J. Milburn,^[9][10] as well as a 2003 article by David Deutsch.^[11]

Many devices already available are fundamentally reliant on the effects of quantum mechanics. These include laser systems, transistors and semiconductor devices, as well as other devices such as MRI imagers. The UK Defence Science and Technology Laboratory (DSTL) grouped these devices as 'quantum 1.0' to differentiate them from what it dubbed 'quantum 2.0', which it defined as a class of devices that actively create, manipulate, and read out quantum states of matter using the effects of superposition and entanglement.^[12]

Future Goals

In the realm of Quantum technology we are in the first couple years of its life. For each individual section of Quantum technology such as quantum computers, simulators, communications, sensors and metrology there is so much room for improvement according to Quantum in a nutshell.^[13] In the next couple years Quantum computers hope to process 50 qubits, as well as demonstrate quantum speed-up and outpreforming classical computers. Quantum simulators have the capability to solve problems beyond supercomputer capacity. For more information visit Quantum technologies in a nut shell.^[13] According to quantum technology expert Paul Martin Quantum technology promises improvements in everyday gadgets such as navigation, timing systems, communication security, computers, and more accurate healthcare imaging.^[14]

Research programmes

From 2010 onwards, multiple governments have established programmes to explore quantum technologies,^[15] such as the UK National Quantum Technologies Programme,^[16] which created four quantum 'hubs', the Centre for Quantum Technologies in Singapore, and QuTech, a Dutch center to develop a topological quantum computer.^[17] In 2016, the European Union introduced the Quantum Technology Flagship,^[18][19] a €1 Billion, 10-year-long megaproject, similar in size to earlier European Future and Emerging Technologies Flagship projects. ^[20][21] In December 2018, the United States passed the National Quantum Initiative Act, which provides a US$1 billion annual budget for quantum research.^[22] China is building the world's largest quantum research facility with a planned investment of 76 billion Yuan (approx. €10 Billion).^[23][24] Indian government has also invested 8000 crore Rupees (approx. US$1.02 Billion) over 5-years to boost quantum technologies under its National Quantum Mission.^[25]

In the private sector, large companies have made multiple investments in quantum technologies. Organizations such as Google, D-wave systems, and University of California Santa Barbara^[26] have formed partnerships and investments to develop quantum technology.

Country/Group	Name of Center/ Project	Government control (yes/no/partial)	Type of Quantum Technology Research	Established date	Funding
AUSTRIALIA	Australian Research Council Centres of Excellence	Yes	Computing	2017	US$94 million
AUSTRIALIA	Department of Defence’s Next Generation Technologies Fund	Yes	Integrated intelligence, surveillance and reconnaissance Space capabilities Enhanced human performance Medical countermeasure products Multi-disciplinary material sciences Quantum technologies Trusted autonomous systems Cyber Advanced sensors Hypersonics Directed energy capabilities[27]	2016[28]	US$4.5M
AUSTRIALIA	Sydney Quantum Academy	Partial	Quantum economy	December 7, 2020 [29]	US$15.0M[30]
AUSTRIALIA	Silicon Quantum Computing	Partial	Quantum computing	May 2017	US$83M[31]
CANADA	Canadian Space Agency Quantum Encryption and Science Satellite	Partial	Quantum key distribution(QKD)[32]	December 2017
CANADA	National Research Council of Canada’s Security and Disruptive Technologies Research Centre: Quantum Sensors and Security program	Partial	Longer-range emerging and disruptive technologies	2012	US$23M
CANADA	Natural Sciences and Engineering Research Council/UK Research and Innovation	Partial	Quantum technology development		US$3.4M
CHINA	Chinese Academy of Sciences Center for Excellence in Quantum Information and Quantum Physics	Yes	General	May 2015	US$10.0B
CHINA	Quantum Experiments at Space Scale (QUESS) project (the Micius satellite)	Yes	Quantum key distribution	May 2015
CHINA	Beijing–Shanghai Quantum Secure Communication Backbone	Yes	Quantum Communications	May 2015
CHINA	National Quantum Laboratory	Yes	Quantum metrology and building a quantum computer	May 2015 (opened in 2020)
EUROPEAN UNION	Quantum Technologies Flagship program	Yes	Quantum computing Quantum simulation Quantum communication Quantum metrology and sensing[33]	2018	Expected budget of €1 billion[33]
EUROPEAN UNION	Coordination and support action for Quantum Technology Education (QTEdu)	Yes	Education[34]	2020
EUROPEAN UNION	QuantERA	Yes	Quantum technologies	2016[35]	€89 million[36]
EUROPEAN UNION	Open European Quantum Key Distribution (OpenQKD)	Yes	Quantum-based cryptography[37]	Sept. 2, 2019 (ended Sept. 1, 2022) [38]	€ 17 974 246,25[38]
EUROPEAN UNION	European Quantum Communication Infrastructure (EuroQCI)	Yes	Quantum communicationinfrastructure[39]	June 2019[39]	€ 90,000,000[40]
FRANCE	National Strategy for Quantum Technologies	Yes	Quantum computing, quantum communications and quantum sensors  [41]	January 21, 2021[41]	US$1.8B[41]
GERMANY	Quantum Technologies — From Basic Research to Market	Yes	Quantum technologies	September 26, 2018	€650M[42]
GERMANY	Agenda Quantensysteme 2030	Yes	quantum computing, quantum simulation, quantum communication, quantum sensors, supporting technologies, public outreach	March 23, 2021.[43]
GERMANY	Fraunhofer-Gesellschaft-IBM collaboration	Yes	Quantum computing[44]	September, 2019[44]	€40M[44]
GERMANY	QuNET	Yes	Quantum communication[45]	2018[45]	€165M[45]
INDIA	National Mission on Quantum Technologies & Applications	Yes	Quantum communication, quantum simulation, quantum computation, Quantum sensing, and quantum metrology[46]	2020[46]	Rs 8000 Crore [46]
ISRAEL	National Program for Quantum Science and Technology	Yes	National quantum development[47]	2019[47]	US$360[47]
JAPAN	Quantum Technology Innovation Strategy	Yes	Quantum technology	2020	US$470
JAPAN	Quantum Strategic Industry Alliance for Revolution (Q-STAR)	Yes	An industry council to promote quantum technologies	September 1, 2021
JAPAN	Quantum Leap Flagship Program	Yes	Superconducting quantum computer, quantum simulation, quantum computing, solid state quantum sensors, lasers[48]	2018 [48]	US$200M[48]
JAPAN	The Moonshot Research and Development Program (Goal 6)	Yes	Quantum computing	2019[49]	US$963M for total program not just quantum[49]
NETHERLANDS	National Agenda for Quantum Technology: Quantum Delta NL	Yes	Quantum computing,quantum communication, and quantum sensing [50]	2020 [51]	€615M[51]
RUSSIA	Rosatom	Yes	Quantum technologies and research infrastructure [52]	2021 [52]	23 billion rubles[52]
RUSSIA	RZD (Russian Railways)	Yes	Quantum Communications[53]	October 2021[53]	138M Russian rubles[53]
SINGAPORE	Quantum Engineering Program	Yes	Quantum technology[54]	2018[54]	US$121.6M[54]
SINGAPORE	Centre for Quantum Technologies (CQT)	Yes	Quantum Technologies[55]	2007[55]	US$194.9M[55]
SINGAPORE	SGInnovate- Quantum Techologies[56]	Yes	Digital financing	2015[57]
SOUTH KOREA	Quantum Computing Technology Development Project	Yes	Quantum technologies[58]	2019[58]	US$39.8M[58]
UNITED KINGDOM	National Quantum Technologies Programme	Yes	Funding UK quantum technologies[59]	2013[60]	US$1B[59]
UNITED KINGDOM	National Quantum Computing Centre	Yes	Quantum computing[61]	Set to open in 2023[61]	£93m[61]
UNITED KINGDOM	Rigetti Computing	Partial	Quantum computing[62]	2013[63]	US$268m[63]
UNITED STATES	Quantum Industry Consortium	Yes	General "quantum ecosystem" (quantum industry supply chain, federal R&D investment priorities, standards and regulation, industry interactions, etc.)[64]	2018	US$1.25B[65]
UNITED STATES	National Quantum Coordination Office	Yes	Quantum technology research and development[66]	2019[66]
UNITED STATES	The National Science Foundation (Five Quantum Leap Challenges Institutes)	Yes	Quantum computing, quantum seniors, quantum processors, quantum biological sensing, and quantum simulation[67][68]	2020[68]	US$125M[67][68]
UNITED STATES	National Quantum Initiative Act	Yes	Quantum information science and Quantum technology development[69]	Dec. 21, 2018[69]	US$1.275B[69]
UNITED STATES	MonArk Quantum Foundry	Partial	Development of quantum materials and devices[70]	August 17, 2021[71]	US$19,990,000[71]
UNITED STATES	Center for Quantum Networks	Partial	Quantum computing[72]	2020[72]	US$26 m[72]
UNITED STATES	National Q-12 Education Partnership	Yes	Education[73]	2020[73]	US$1M[73]

See also

• Quantum nanoscience
• Atomic engineering
• QFET (quantum field-effect transistor)

References

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