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From Qiskit Metal to pattern generation to real nanofabrication demo. Here, quantum devices on a chip are patterned via direct-write electron-beam lithography in a nanofabrication facility. Written & patterned by Onri Jay Benally, an Indigenous American quantum hardware engineer.
⚛️ 👨🏫 📚 A two-week intensive Summer School on Quantum Computing from IBM Quantum, using mostly the features of the IBM's Qiskit library. In this Summer School, were lectured topics on basics of Quantum Information, Quantum Entanglement, Quantum Algorithms, Quantum Error Mitigation, among many others.
⚛️ 🚀 👽 A self-paced, game-based Quantum Computing learning program for students, researchers and enthusiasts. This program offers a general understanding of Quantum Computing, as well as some of its applications, such as Quantum Machine Learning and Quantum Optimization, and how to program real quantum computers.
In this work, we use LR-QAOA protocol as an easy-to-implement scalable benchmarking methodology that assesses quantum process units (QPUs) at different widths (number of qubits) and 2-qubit gate depths.
The Non-Equilibrium Evolution PYthon based library (*Neepy*) is a programming tool designed to simulate the evolution of quantum systems out of equilibrium. This library presents a fast prototyping of the evolution of quantum systems based on commonly used evolution equations such as the von Neumann, the Lindblad, or the SEAQT equations of motion.