Towards quantum chemistry on a quantum computer

Lanyon, B. P.; Whitfield, James D.; Gillett, Geoff; Goggin, M. E.; Almeida, M. P.; Kassal, Ivan; Biamonte, Jacob; Mohseni, Masoud; Powell, B. J.; Barbieri, Marco; Aspuru‐Guzik, Alán; White, A. G.

doi:10.1038/nchem.483

Cited by 695 publications

(648 citation statements)

References 53 publications

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“…T he quantum interference 1 of two indistinguishable single photons is an important resource for long distance quantum communication and linear quantum computing [2][3][4][5] . Recent years have seen important progress in the development of bright single-photon sources in solid-state systems using semiconductor self-assembled quantum dots (QDs) 6 inserted in photonic structures [7][8][9][10] .…”

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confidence: 99%

Bright solid-state sources of indistinguishable single photons

et al. 2013

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Bright sources of indistinguishable single photons are strongly needed for the scalability of quantum information processing. Semiconductor quantum dots are promising systems to build such sources. Several works demonstrated emission of indistinguishable photons while others proposed various approaches to efficiently collect them. Here we combine both properties and report on the fabrication of ultrabright sources of indistinguishable single photons, thanks to deterministic positioning of single quantum dots in well-designed pillar cavities. Brightness as high as 0.79±0.08 collected photon per pulse is demonstrated. The indistinguishability of the photons is investigated as a function of the source brightness and the excitation conditions. We show that a two-laser excitation scheme allows reducing the fluctuations of the quantum dot electrostatic environment under high pumping conditions. With this method, we obtain 82 ± 10% indistinguishability for a brightness as large as 0.65 ± 0.06 collected photon per pulse.

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confidence: 99%

Bright solid-state sources of indistinguishable single photons

et al. 2013

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“…showed that these approaches might be particularly promising for quantum chemistry [7]. There have been many developments both in theory [8][9][10] and experimental realization [11][12][13] of quantum chemistry on quantum computers. The original gate construction for quantum chemistry introduced by Whitfield et al [14] was recently challenged as too expensive by Wecker et al [15].…”

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confidence: 99%

Exploiting Locality in Quantum Computation for Quantum Chemistry

McClean

Babbush

Love

et al. 2014

J. Phys. Chem. Lett.

126

190

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Accurate prediction of chemical and material properties from first principles quantum chemistry is a challenging task on traditional computers. Recent developments in quantum computation offer a route towards highly accurate solutions with polynomial cost, however this solution still carries a large overhead. In this perspective, we aim to bring together known results about the locality of physical interactions from quantum chemistry with ideas from quantum computation. We show that the utilization of spatial locality combined with the Bravyi-Kitaev transformation offers an improvement in the scaling of known quantum algorithms for quantum chemistry and provide numerical examples to help illustrate this point. We combine these developments to improve the outlook for the future of quantum chemistry on quantum computers.

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“…1a). Reducing the number of qubits in quantum simulations and quantum chemistry has been achieved with recursive phase estimation [13][14][15][16] , while ground state projections have been demonstrated by exploiting similar techniques in NMR 17 .…”

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Experimental realization of Shor's quantum factoring algorithm using qubit recycling

et al. 2012

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Quantum computational algorithms exploit quantum mechanics to solve problems exponentially faster than the best classical algorithms 1-3 . Shor's quantum algorithm 4 for fast number factoring is a key example and the prime motivator in the international effort to realise a quantum computer 5 . However, due to the substantial resource requirement, to date, there have been only four small-scale demonstrations 6-9 . Here we address this resource demand and demonstrate a scalable version of Shor's algorithm in which the n qubit control register is replaced by a single qubit that is recycled n times: the total number of qubits is one third of that required in the standard protocol [10][11][12] . Encoding the work register in higher-dimensional states, we implement a two-photon compiled algorithm to factor N = 21. The algorithmic output is distinguishable from noise, in contrast to previous demonstrations. These results point to larger-scale implementations of Shor's algorithm by harnessing scalable resource reductions applicable to all physical architectures.Shor's factoring algorithm consists of a quantum order finding algorithm, preceded and succeeded by various classical routines. While the classical tasks are known to be efficient on a classical computer, order finding is understood to be intractable classically. However, it is known that this part of the algorithm can be performed efficiently on a quantum computer. To determine the prime factors of an odd integer N , one chooses a coprime of N , x. The order r relates x to N according to x r mod N = 1, and can be used to obtain the factors, given by the greatest common divisor gcd(x r 2 ± 1, N ). The quantum order finding circuit involves two registers: a work register and a control register. In the standard protocol, the work register performs modular arithmetic with m = log 2 N qubits, enough to encode the number N , and the n qubit control register provides the algorithmic output, with n bits of precision.Measuring the control register in the computational basis will yield a result of k2 n /r where k is an integer between 0 and r − 1, with the value of k occurring probabilistically. Dividing the result by 2 n gives the first n bits of k/r and r may be found with classical processing, using the continued fraction algorithm. For large n, and a perfectly functioning circuit, the output probability distribution of the control register is a series of well defined peaks at values of k2 n /r (Fig. 1b). (See Appendix for details.)Here we implement an iterative version of the order finding algorithm 10,11 , in which the control register contains only a single qubit which is recycled n times, using a sequence of measurement and feed-forward operations, with each step providing an additional bit of precision (Fig. 1a). Reducing the number of qubits in quantum simulations and quantum chemistry has been achieved with recursive phase estimation 13-16 , while ground state projections have been demonstrated by exploiting similar techniques in NMR 17 .The iterative version of...

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Towards quantum chemistry on a quantum computer

Cited by 695 publications

References 53 publications

Bright solid-state sources of indistinguishable single photons

Bright solid-state sources of indistinguishable single photons

Exploiting Locality in Quantum Computation for Quantum Chemistry

Experimental realization of Shor's quantum factoring algorithm using qubit recycling

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