Researchers at a Shanghai Jiao Tong University unveiled a DNA-based supercomputer today. The system runs 100 billion programs at the same time. Scientists use engineered DNA strands to store and process data in the DNA Computers. They design sequences that perform complex computations with chemicals. The team shows that nature can compute at massive scales.
Scientists view this discovery as a leap in technology. They rely on tiny DNA molecules that multiply in a small solution. The approach leverages nature’s own efficiency and speed. The method allows billions of reactions to run concurrently. The breakthrough shifts computing from silicon chips to biology.
DNA sequences serve as data bits
Engineers design the system with careful control over chemical reactions. They create a complex network of DNA sequences that serve as data bits. The team plans to solve problems that conventional computers cannot tackle. They focus on tasks that require high levels of parallel processing. The study excites experts across scientific fields.
Researchers say this computer uses energy more efficiently than electronic devices. The method draws power from natural biochemical reactions. The new system shows promise for many applications in science and industry. The approach may change research in cryptography and drug discovery. The discovery may help solve difficult optimization problems.
UK-based Pragmatic Semiconductor has introduced a flexible chip that costs less than $1.
Scientists report that individual chemical reactions run slower than electronic circuits. They still enjoy massive parallel capabilities with their DNA design. They work to improve reaction speeds and reduce error rates. They tackle challenges such as unintended chemical interactions. The team aims to build a more robust computing platform.
Silicon computers will join DNA processors
Technology experts praise the innovation and foresee hybrid systems in the future. They predict that silicon computers will join DNA processors. They believe each system will excel in specific tasks. The combination may bring energy savings and improved performance. Experts claim that this work opens new research paths.
Researchers already plan future experiments to enhance the system further. They intend to develop better readout methods for digital results. They use techniques like sequencing and fluorescence to decode outputs. The team dreams of practical devices that tackle real-world challenges. The breakthrough paves the way for further interdisciplinary work.
Journalists cover the story with great excitement and urgency. They note that the breakthrough challenges conventional ideas about computation. They report that biology and technology now join forces in one project. The discovery stokes public interest and inspires future scientists. The project proves that innovative thinking can disrupt established fields.
Scientists continue to work on the project with determination and creativity. They create systems that run massive numbers of tasks simultaneously. They shape a future where biology supports digital computation. They push the boundaries of what computing can achieve. They inspire the next generation of researchers and engineers.
