I produced this short to simplify Quantum computing explained #youtubeshorts #shorts #facts

🌐 Dive into how quantum computers operate uniquely with qubits that can represent multiple states simultaneously. Discover the fascinating world of quantum computing! 🌐 Dive into how quantum computers operate uniquely with qubits that can represent multiple states simultaneously. Learn the groundbreaking concepts of superposition and entanglement, which enable quantum computers to process vast amounts of information at once. Explore the immense potential of quantum computers to solve complex problems at unprecedented speeds, driving significant global investment. Don't miss out on this exciting journey into the future of technology! #QuantumComputing #Qubits #Superposition #Entanglement #FutureOfTech #TechInnovation #QuantumRevolution If you enjoyed this video, please like and share it with others who are interested in cutting-edge technology! OUTLINE: 00:00:00 Quantum Computing: The Future of Technology Explained!A quantum computer is a computer that exploits quantum mechanical phenomena. On small scales, physical matter exhibits properties of both particles and waves, and quantum computing leverages this behavior using specialized hardware. Classical physics cannot explain the operation of these quantum devices, and a scalable quantum computer could perform some calculations exponentially faster[a] than any modern "classical" computer. In particular, a large-scale quantum computer could break widely used encryption schemes and aid physicists in performing physical simulations; however, the current state of the art is largely experimental and impractical, with several obstacles to useful applications. Quantum System One, a quantum computer by IBM from 2019 with 20 superconducting qubits[1] The basic unit of information in quantum computing, the qubit (or "quantum bit"), serves the same function as the bit in classical computing. However, unlike a classical bit, which can be in one of two states (a binary), a qubit can exist in a superposition of its two "basis" states, which loosely means that it is in both states simultaneously. When measuring a qubit, the result is a probabilistic output of a classical bit. If a quantum computer manipulates the qubit in a particular way, wave interference effects can amplify the desired measurement results. The design of quantum algorithms involves creating procedures that allow a quantum computer to perform calculations efficiently and quickly. Physically engineering high-quality qubits has proven challenging. If a physical qubit is not sufficiently isolated from its environment, it suffers from quantum decoherence, introducing noise into calculations. National governments have invested heavily in experimental research that aims to develop scalable qubits with longer coherence times and lower error rates. Example implementations include superconductors (which isolate an electrical current by eliminating electrical resistance) and ion traps (which confine a single atomic particle using electromagnetic fields). In principle, a classical computer can solve the same computational problems as a quantum computer, given enough time. Quantum advantage comes in the form of time complexity rather than computability, and quantum complexity theory shows that some quantum algorithms are exponentially more efficient than the best known classical algorithms. A large-scale quantum computer could in theory solve computational problems unsolvable by a classical computer in any reasonable amount of time. While claims of such quantum supremacy have drawn significant attention to the discipline, near-term practical use cases remain limited.