Quantum mechanics (QM) can be understood as a set of rules that forms the basis for
developing all quantum theories. One of these theories is quantum computation (QC), ie …

Computational complexities in modern power systems are reportedly increasing daily, and it
is anticipated that traditional computers might be inadequate to provide the computation …

Quantum computers must achieve large-scale, fault-tolerant operation to deliver on their
promise of transformational processing power [1-4]. This will require thousands or millions of …

Power system fault diagnosis is crucial for identifying the location and causes of faults and
providing decision-making support for power dispatchers. However, most classical methods …

Leveraging the current generation of quantum devices to solve optimization problems of
practical interest necessitates the development of hybrid quantum-classical (HQC) solution …

Quantum technology provides a ground-breaking methodology to tackle challenging
computational issues in power systems. It is especially promising for Distributed Energy …

As a large number of renewable energy resources are connected to power systems, the
operation, planning, and optimization of power systems have been becoming more and …

Much of recent progress in geophysics can be attributed to the adaptation of heterogeneous
high-performance computing architectures. It is projected that the next major leap in many …

Optimization problems are ubiquitous in various industrial settings, and multi-knapsack
optimization is one recurrent task faced daily by several industries. The advent of quantum …

In recent years, the attention of researchers has been drawn to identifying and investigating
new optimal approaches for operation of the distribution networks (ODNs) and the role of …