Additive manufacturing, commonly known as 3D printing, is gaining popularity in a variety of applications and has recently become routinely available. Today, 3D printing services are not only found in engineering design labs and through online companies, but also in university libraries offering student access. In addition, affordable options for home hobbyists have already been introduced. Here, we demonstrate the use of 3D printing to generate plastic models of molecular potential energy surfaces useful for understanding molecular structure and reactivity.
Decoherence and gate errors severely limit the capabilities
of
state-of-the-art quantum computers. This work introduces a strategy
for reference-state error mitigation (REM) of quantum chemistry that
can be straightforwardly implemented on current and near-term devices.
REM can be applied alongside existing mitigation procedures, while
requiring minimal postprocessing and only one or no additional measurements.
The approach is agnostic to the underlying quantum mechanical ansatz
and is designed for the variational quantum eigensolver. Up to two
orders-of-magnitude improvement in the computational accuracy of ground
state energies of small molecules (H2, HeH+,
and LiH) is demonstrated on superconducting quantum hardware. Simulations
of noisy circuits with a depth exceeding 1000 two-qubit gates are
used to demonstrate the scalability of the method.
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