Cracking the Quantum Code: Entanglement Breakthrough in Silicon

Researchers have achieved quantum entanglement between two atomic nuclei across 20 nanometers, a crucial stride toward practical quantum computing. Utilizing electrons as communication channels, this breakthrough paves the way for integrating durable nuclear spin qubits into existing silicon chip infrastructures, heralding a new era in quantum technology.

Devdiscourse News Desk | Sydney | Updated: 20-09-2025 11:53 IST | Created: 20-09-2025 11:53 IST

Cracking the Quantum Code: Entanglement Breakthrough in Silicon — This image is AI-generated and does not depict any real-life event or location. It is a fictional representation created for illustrative purposes only.

Country:
Australia

Quantum entanglement, once dubbed "spooky action at a distance" by Einstein, has moved closer to a practical application, thanks to new research. Scientists have connected two atomic nuclei separated by roughly 20 nanometers, marking a key development toward functional quantum computers.

This connection leverages electrons as a communication channel between nuclei located in silicon chips. The successful entanglement within this tiny scale aligns well with the production methods of current silicon technology, suggesting these quantum properties could potentially be integrated into everyday digital devices.

This innovation, focusing on long-lived, noise-shielded nuclear spins, promises to enhance the reliability of quantum computations. This method might lead the way in adapting electron-based quantum devices for constructing quantum computers in the foreseeable future.

(With inputs from agencies.)