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A sort of information system that utilises the concepts of quantum mechanics is known as a quantum information management system (QIMS). Quantum information, the fundamental unit of information in the quantum universe, is processed, stored, and transmitted by it.
Quantum hardware, quantum algorithms, quantum communication channels, and quantum error correction protocols are usually present in a QIMS. Together, these elements guarantee the precise and dependable processing of quantum information.
Quantum error correction, which is required to fix mistakes that happen during the transmission and processing of quantum information, is one of the most crucial components of a QIMS. Quantum error correction codes, which resemble classical error correction codes but are made to work with quantum bits, are used to accomplish this. (qubits).
Quantum cryptography, which is used to guarantee the security and secrecy of quantum information, is another essential part of a QIMS. The use of quantum cryptography allows for the creation of secure communication lines that are impervious to eavesdropping and tampering.
The development of QIMSs is still in its infancy, but they show tremendous potential for a variety of uses, such as secure communication, quantum simulation, and quantum computing.
Global Quantum information management system market accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.
At the Cleveland Clinic in the US, IBM has begun the first implementation of an IBM Quantum System One, where its 127-qubit Eagle QPU will be used for medical research.
The new IBM Quantum System Two, which combines numerous processors into a single system and is intended to be modular and flexible, has also been unveiled by IBM. With the introduction of its new 433 qubit “Osprey” processor, IBM advances the use of quantum computers for solving previously intractable problems.
A framework called CUDA Quantum, developed by Nvidia, allows users to create quantum algorithms using the well-liked C++ and Python programming languages. Depending on which computing system is most effective, the programme would assist in running the algorithm on both quantum and conventional computers.
Arizona State University has established The Quantum Collaborative, a significant 21st-century initiative to advance partnerships and understanding of quantum technology.
Quantinuum, a company integrated with quantum computing that has released next-generation quantum products like trapped-ion quantum computers, quantum computing enhanced cybersecurity, and quantum computational chemistry software, is one of the founding industry partners of the Quantum Collaborative. Quantinuum is a combination of Honeywell Quantum Solutions and Cambridge Quantum.
The National Science Foundation has a long history of funding research that has contributed to setting the stage for the quantum-based technology that is expected to experience rapid development in the coming years.
The use of uniquely quantum phenomena provides significant advances in fields like sensing and measurement, computing and simulation, and communication and networking.
This is a new paradigm that science and engineering must adapt to. The first new items are being discovered and introduced to the market as the industry starts to invest on its own. As a result, a workforce with training in a variety of disciplines is required to build the supply chain and put new scientific findings into action.
New materials, circuits, and algorithms will enable novel quantum and post-quantum applications, such as artificial photosynthesis, highly sensitive radiation detectors, and many others that are not currently anticipated.
Frontier knowledge generated through NSF-supported discoveries will open new vistas and opportunities in the quantum field. In order to address the fundamental scientific and engineering problems that will hasten progress in all areas of quantum applications, from sensing to communication to computing to simulation, NSF will take advantage of the full breadth of scientific and engineering fields that it funds. It will bring together researchers from various disciplines.
NSF investments will increase capacity by educating the workforce required for advancement and commercialization in this quickly increasing area of emerging technology.
These investments support research and education at institutions. The National Strategic Overview for Quantum Information Science articulates the policy objectives that are addressed by NSF investments, which are in line with the National Quantum Initiative.
Investments in specialised activities with clear goals, many of which overlap with NSF’s Quantum Leap Big Idea, as well as investments in the key NSF disciplines, are ways that NSF continues to show its support.
The Biden administration announced plans to issue a new policy directive to assist in launching what is expected to be a protracted and difficult procedure to protect the American information technology infrastructure from developing quantum supercomputers.
Although a fully functional quantum-driven computing machine has not yet been created, many countries and significant corporations are working feverishly to do so. Once operational, such a sophisticated system is expected to defeat most of the present internet-based cryptography used to secure modern digital communication.
Data that is encrypted even today may one day be decrypted by a quantum computer 10 years from now. The national security community must therefore make the transition to post-quantum cryptography in particular.
