Quantum computing uses the controlled evolution of quantum states to perform data computation and storage. It possesses disruptive parallel computing capabilities and can achieve exponential speedups in computer simulations.
Today's computers work by manipulating bits that exist in one of two states: 0 or 1. Quantum computers are not limited to two states; they encode information as qubits, which can exist in superposition, making them hundreds of thousands of times more powerful than the most powerful supercomputers today. For example, cracking a bank password would take a conventional computer 100 million years, a supercomputer 10,000 years, and a quantum computer just one second.
Our experts are one of the earliest professional teams in the country engaged in quantum computing research. They have mastered the development of ion trap quantum devices and technologies for various needs. Their technical level and research achievements are internationally leading, placing them in the top tier in Asia.
- The first ion-trap quantum computer with quantum entanglement
- Possess independent intellectual property rights
- Capable of multi-qubit quantum computing and the first to achieve simulation of a 360-layer quantum circuit
- Quantum fidelity exceeds 97%
- The quantum coherence time is over 1 second, reaching up to 1.5 hours, which also greatly differentiates it from the superconducting approach.
- 30 normal qubits at room temperature, more than 50 qubits in total, with entanglement of more than 4 qubits, and scalable.
- Leading in both room temperature and chip scalability
Technical barriers
Breaking through the core technology of ion trap quantum computing, achieving high fidelity, long coherence time, and scalable qubits, with patented technology and dual certification protection. It has already received orders from provincial-level computing centers, with high technological maturity and market recognition, and a significant international leading advantage. High-precision non-cyclic non-adiabatic geometric quantum logic gate experiments have been realized, demonstrating that this universal quantum logic gate possesses both fault-tolerant and fast operational characteristics, and is expected to be applied in commercial quantum computers.
Development status
(1)Promote the transition of quantum computers from prototypes to large-scale applications to meet high-end demands
(2)Experienced in integrating with classical supercomputing and AI intelligence computing, as well as in combining algorithms and hardware computing power
(3)Applied to a wide range of fields, such as engineering analysis, product design, financial investment portfolios, defense and military, biochemistry and pharmaceuticals, materials, energy simulation, artificial intelligence and machine learning neural networks, information security, data processing, weather, and so on, with multiple ions stably and distinguishably confined in the chip.
