Abstract
Quantum mechanical systems lose coherence through interacting with external environments—a process known as decoherence. Although decoherence is detrimental for most of the tasks in quantum information processing, a substantial degree of decoherence is crucial for boosting the efficiency of quantum processes, for example, in quantum biology and other open systems. The key to the success in simulating those open quantum systems is therefore the ability of controlling decoherence, instead of eliminating it. Motivated by simulating quantum open systems with Nitrogen-Vacancy centers, which has become an increasingly important platform for quantum information processing tasks, we developed a new set of steering pulse sequences for controlling various coherence times of Nitrogen-Vacancy centers; our method is based on a hybrid approach that exploits ingredients in both digital and analog quantum simulations to dynamically couple or decouple the system with the physical environment. Our numerical simulations, based on experimentally-feasible parameters, indicate that decoherence of Nitrogen-Vacancy centers can be controlled externally to a very large extend.
Highlights
A quantum simulator[1,2,3,4,5] is potentially a powerful tool for solving many-body problems that are not tractable by classical methods
An important approach to tackle the decoherence problem, called dynamical decoupling[30,31,32,33,34,35,36], has been developed to significantly eliminate the system-environment interactions[37], through a sequence of external pulses applied to the system
Dynamical decoupling has been applied to NV center for eliminating the noise from environment and prolong the coherence time of electron spin[40,54,55]
Summary
A quantum simulator[1,2,3,4,5] is potentially a powerful tool for solving many-body problems that are not tractable by classical methods. An important approach to tackle the decoherence problem, called dynamical decoupling[30,31,32,33,34,35,36], has been developed to significantly eliminate the system-environment interactions[37], through a sequence of external pulses applied to the system. An extension of dynamical decoupling is possible for universal quantum computation[46,47], and other applications[48,49]. Simulating open quantum systems through an extension of the idea of dynamical decoupling and apply it to NV centers. Dynamical decoupling has been applied to NV center for eliminating the noise from environment and prolong the coherence time of electron spin[40,54,55]. We developed a new set of decoupling pulse sequences that can control the decoherence of the off-diagonal matrix elements of the system density matrix
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