Key features
- Ability to reach cryogenic temperatures of 1 K (or lower depending on He-3/He-4 configuration), suitable for low temperature and quantum physics research.
- Helium (He-3/He-4) cooling system optimized for experiments requiring ultra-low temperature and high stability environments.
- Integrated measurement system design, supporting electrical – magnetic – physical measurements in cryogenic environments.
- Flexible research platform, suitable for various applications: superconducting materials, quantum computing, and condensed matter physics.
- High thermal stability, ensuring accurate experimental conditions over long periods.
- Optimized for R&D laboratories, easy to integrate with measurement systems and peripheral devices.
- Modular design, allowing configuration customization according to research requirements.
- Supports research on superconducting qubits and quantum devices, meeting the needs for quantum technology development.
Detailed description
- The 1K cryogenic measurement system using helium (LDHe Measurement System) is a low-temperature experimental platform designed for advanced research in the fields of quantum physics, superconducting materials, and quantum computing technology. The system provides a stable ultra-low temperature environment, allowing for high-precision measurements under stringent cryogenic conditions.
- The device uses cooling technology based on a helium-3/helium-4 mixture, allowing it to reach temperature ranges of approximately 1 K or lower, depending on the system configuration. Thanks to its precise temperature control and high stability, the system meets the demands of modern research in solid-state physics and quantum technology.
- The LDHe Measurement System comes with an integrated measurement platform, supporting various types of experiments such as resistance measurement, magnetic properties, material characterization, and testing of semiconductor or superconducting devices in low-temperature environments. The system also allows for flexible integration with external measurement devices such as lock-in amplifiers, current/voltage sources, and data acquisition systems.
- With an optimized design for R&D laboratories, the system offers high flexibility in configuration and operation while ensuring stable cooling performance over extended periods. The modular architecture allows users to easily customize it for specific research applications, from fundamental physics to the development of advanced quantum technology.