![]() ![]() Why is the future of quantum computing important now? More complex problems are arisingĪs technology advances, the problems encountered are getting more complex. Superposition states that qubits can hold both 0 and 1 state at the same time. Entanglement is a property of qubits that allow them to be dependent of each other that a change in the state of one qubit can result and immediate change in others. Shortly, qubits have two different property that is different than the whole concept of classical computing. Feel free to visit our earlier article on quantum computing to learn the basic concepts for qubits and quantum computing. However, quantum computers work with interdependent and nonlinear structures called qubits. Classical computers work with key-like structures that open and close, which is called bits. The quantum computer concept brings a completely different perspective to the classical computer concept. Wikipedia describes quantum computing as ” the use of quantum-mechanical phenomena such as superposition and entanglement to perform computation.” In this article, we explain what quantum computing is, where it can be used, and what challenges might impede its implications. This development has the potential to transform biology, chemistry and material science. Even though the modeling of a molecule does not seem to happen in the near future with classical computing, quantum computing can make it possible by solving equations that impede advances in extracting an exact model of molecules.However, these problems could possibly be solved within minutes with quantum computing. Encryption methods have been designed to take centuries to solve even for supercomputers.Quantum computing has a dynamic nature, acting as a useful solution for complex mathematical models, such as: Quantum computing can be a game-changer in fields such as, cryptography, chemistry, material science, agriculture, and pharmaceuticals once the technology is more mature. ![]()
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