QRC has developed Qibo, a Python library enabling classical simulation of quantum algorithms with double precision. Qibo leverages hardware accelerators like GPUs and CPUs with multi-threading. It incorporates a multi-GPU distributed approach for circuit simulation. Why it matters: This framework allows researchers and developers in the region to explore and prototype quantum algorithms using existing classical computing infrastructure, fostering innovation in quantum computing research and applications.
Abu Dhabi's Technology Innovation Institute (TII), in collaboration with Google AI Quantum, the University of Maryland, and Freie Universität Berlin, has achieved a breakthrough in analogue quantum simulations. They successfully demonstrated learning large-scale quantum simulator dynamics from data using advanced data-processing algorithms developed by TII's Quantum Research Center. The research, published in Nature Communications, enables unprecedented precision in understanding quantum systems. Why it matters: This advancement positions Abu Dhabi as a key player in quantum research and its applications across material science, pharmaceuticals, and energy, with TII hosting a Quantum Technology Symposium to foster further collaboration.
The Atomtronics@AbuDhabi2021 meeting, held virtually via Zoom, focused on recent advancements in cold atom quantum technology, particularly within the emerging field of Atomtronics. The meeting covered applicative, experimental, and theoretical aspects of atomic circuits for computation, communication, and sensing. Poster sessions were organized in Zoom breakout rooms. Why it matters: The event signals growing interest and activity in quantum technologies and quantum simulation within the UAE, with potential implications for future research and development in the region.
This article summarizes presentations from an internal Quantum Research Center (QRC) workshop at the Technology Innovation Institute (TII). Topics covered included superconducting quantum computers, quantum coherent networks, quantum simulation, and quantum machine learning. Several presentations also discussed experimental quantum technologies. Why it matters: The workshop highlights TII's ongoing research activities in quantum computing and related technologies, signaling its commitment to advancing the field in the UAE.
The Technology Innovation Institute (TII) in Abu Dhabi, in collaboration with NVIDIA, has demonstrated large-scale simulations of the adiabatic quantum annealing (QA) algorithm for problem instances involving up to 500,000 qubits. TII's simulator achieved solution quality exceeding that of all solvers evaluated from the MQLib repository, a library for combinatorial optimization benchmarking. The emulator is accessible to external users via an experimental cloud platform hosted at https://q-inspired.tii.ae. Why it matters: This collaboration expands the range of complex optimization problems that can be investigated using quantum-inspired approaches, beyond those currently achievable with near-term quantum hardware.
Professor Christian Roos from the University of Innsbruck will present a seminar on investigating many-body physics using trapped ions dressed by laser light. The talk will cover encoding, manipulating, and entangling quantum information using laser-cooled trapped ions. Recent experiments demonstrating entangling interactions and single-qubit control in strings of up to 50 ions will be discussed. Why it matters: This seminar contributes to advancements in quantum computing and simulation, fields of increasing interest in the Middle East as the region invests in advanced technologies.
Researchers from LENS, CNR-INO, the University of Florence, UNAM, RPTU University Kaiserslautern-Landau, and TII Abu Dhabi have observed Shapiro steps in ultracold atoms for the first time. This allows for real-time observation of quantum mechanics and could lead to advanced quantum sensors and simulation. The experiments involved creating vortex-antivortex pairs, resulting in step-like signals, and the findings were published in Science. Why it matters: This breakthrough provides a new method to observe and control quantum coherence, potentially enabling advancements in quantum technologies and simulations within the region.