Neal C. Pisenti scite author profile

The field of quantum computing has grown from concept to demonstration devices over the past 20 years. Universal quantum computing offers efficiency in approaching problems of scientific and commercial interest, such as factoring large numbers, searching databases, simulating intractable models from quantum physics, and optimizing complex cost functions. Here, we present an 11-qubit fully-connected, programmable quantum computer in a trapped ion system composed of 13 171Yb+ ions. We demonstrate average single-qubit gate fidelities of 99.5, average two-qubit-gate fidelities of 97.5, and SPAM errors of 0.7. To illustrate the capabilities of this universal platform and provide a basis for comparison with similarly-sized devices, we compile the Bernstein-Vazirani and Hidden Shift algorithms into our native gates and execute them on the hardware with average success rates of 78 and 35, respectively. These algorithms serve as excellent benchmarks for any type of quantum hardware, and show that our system outperforms all other currently available hardware.

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Ground-state energy estimation of the water molecule on a trapped-ion quantum computer

Nam

et al. 2020

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Quantum computing leverages the quantum resources of superposition and entanglement to efficiently solve computational problems considered intractable for classical computers. Examples include calculating molecular and nuclear structure, simulating strongly-interacting electron systems, and modeling aspects of material function. While substantial theoretical advances have been made in mapping these problems to quantum algorithms, there remains a large gap between the resource requirements for solving such problems and the capabilities of currently available quantum hardware. Bridging this gap will require a co-design approach, where the expression of algorithms is developed in conjunction with the hardware itself to optimize execution. Here, we describe a scalable co-design framework for solving chemistry problems on a trapped ion quantum computer, and apply it to compute the ground-state energy of the water molecule. The robust operation of the trapped ion quantum computer yields energy estimates with errors approaching the chemical accuracy, which is the target threshold necessary for predicting the rates of chemical reaction dynamics.

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Ground-state energy estimation of the water molecule on a trapped ion quantum computer

Nam¹,

Chen²,

Pisenti³

et al. 2019

Preprint

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Efficient arbitrary simultaneously entangling gates on a trapped-ion quantum computer

et al. 2020

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Efficiently entangling pairs of qubits is essential to fully harness the power of quantum computing. Here, we devise an exact protocol that simultaneously entangles arbitrary pairs of qubits on a trapped-ion quantum computer. The protocol requires classical computational resources polynomial in the system size, and very little overhead in the quantum control compared to a single-pair case. We demonstrate an exponential improvement in both classical and quantum resources over the current state of the art. We implement the protocol on a software-defined trapped-ion quantum computer, where we reconfigure the quantum computer architecture on demand. Our protocol may also be extended to a wide variety of other quantum computing platforms.

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Distinguishability of hyperentangled Bell states by linear evolution and local projective measurement

2011

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Measuring an entangled state of two particles is crucial to many quantum communication protocols. Yet Bellstate distinguishability using a finite apparatus obeying linear evolution and local measurement is theoretically limited. We extend known bounds for Bell-state distinguishability in one and two variables to the general case of entanglement in n two-state variables. We show that at most 2 n+1 − 1 classes out of 4 n hyper-Bell states can be distinguished with one copy of the input state. With two copies, complete distinguishability is possible. We present optimal schemes in each case.

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Neal C. Pisenti

Benchmarking an 11-qubit quantum computer

Ground-state energy estimation of the water molecule on a trapped-ion quantum computer

Ground-state energy estimation of the water molecule on a trapped ion quantum computer

Efficient arbitrary simultaneously entangling gates on a trapped-ion quantum computer

Distinguishability of hyperentangled Bell states by linear evolution and local projective measurement

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