2020
DOI: 10.48550/arxiv.2009.12472
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How will quantum computers provide an industrially relevant computational advantage in quantum chemistry?

Abstract: Numerous reports claim that quantum advantage, which should emerge as a direct consequence of the advent of quantum computers, will herald a new era of chemical research because it will enable scientists to perform the kinds of quantum chemical simulations that have not been possible before. Such simulations on quantum computers, promising a significantly greater accuracy and speed, are projected to exert a great impact on the way we can probe reality, predict the outcomes of chemical experiments, and even dri… Show more

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Cited by 47 publications
(82 citation statements)
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“…For example, the quantum phase estimation (QPE) [15] algorithm has been proven to be exponentially faster in finding eigenvalues of unitary operators than any available algorithm on a classical computer [69][70][71]. However, calculations using QPE are still impractical in the absence of error correction and require quantum resources that exceed the current capability of NISQ hardware [72]. An alternative algorithm to QPE is the variational quantum eigensolver (VQE) [73], which allows one to use shallower circuits than QPE and hence to perform calculations on non fault-tolerant quantum computers [74].…”
Section: B Variational Quantum Eigensolver To Obtain Ground State Ene...mentioning
confidence: 99%
“…For example, the quantum phase estimation (QPE) [15] algorithm has been proven to be exponentially faster in finding eigenvalues of unitary operators than any available algorithm on a classical computer [69][70][71]. However, calculations using QPE are still impractical in the absence of error correction and require quantum resources that exceed the current capability of NISQ hardware [72]. An alternative algorithm to QPE is the variational quantum eigensolver (VQE) [73], which allows one to use shallower circuits than QPE and hence to perform calculations on non fault-tolerant quantum computers [74].…”
Section: B Variational Quantum Eigensolver To Obtain Ground State Ene...mentioning
confidence: 99%
“…Such control could be used to transfer quantum states between light and biomolecular systems [25], and therefore to form the basis of a class of robust room temperature technologies for quantum computing, communication and sensing [21,25]. Quantum computers allow molecular simulations that go beyond what is possible with quantum chemistry [26,27]. These fully-quantum simulations are predicted to allow faster, more accurate simulations of large molecules [27,28], and could therefore play an important role in the design of future pharmaceuticals, artificial enzymes and energy harvesting systems.…”
Section: Overviewmentioning
confidence: 99%
“…Quantum computers allow molecular simulations that go beyond what is possible with quantum chemistry [26,27]. These fully-quantum simulations are predicted to allow faster, more accurate simulations of large molecules [27,28], and could therefore play an important role in the design of future pharmaceuticals, artificial enzymes and energy harvesting systems.…”
Section: Overviewmentioning
confidence: 99%
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