LOW TEMPERATURE XYZ PIEZO SCANNER | Low Temperature Scanner
Dimensions : 24x24x9.2mm
Weight : 16 gram
Scan range : 50x50x24µm @ 300K and 30x30x15µm @ < 4K
Materials : Titanium, Piezoelectric & alumina ceramics stainless steel screws, copper wires & FR4
Temperature : 10mK-300K
Magnetic Field : up to 40 Tesla
Operation : Open Loop
Closed Loop : Optional on any axis with
ultra-low power heterodyne fiber interferometers
1- 10µW/axis
Applicable to the following scientific research fields:
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Condensed Matter Physics: The equipment can operate under ultralow-temperature (as low as 10 mK) and high-magnetic-field (up to 40 Tesla) conditions. It is suitable for studying the quantum properties of condensed matter, such as the electronic state changes of high-temperature superconducting materials under low-temperature and high-magnetic-field conditions, and the edge state properties of topological insulators.
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Materials Science: It plays a role in the research of the microstructure and properties of materials. Through scanning at different temperatures (300 K and below 4 K), the thermal stability and lattice structure changes of materials can be analyzed; using high-magnetic-field conditions, it can also explore the magnetoelectric coupling effect of magnetic materials, for example, studying the electrical and optical properties of two-dimensional materials (such as graphene, molybdenum disulfide, etc.) in special environments.
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Quantum Information Science: Ultralow-temperature and high-magnetic-field environments facilitate the preparation and manipulation of quantum bits, enabling experimental research related to quantum computing and quantum communication. For instance, it supports the study of the coherence and decoherence mechanisms of quantum bits based on superconducting Josephson junctions or cold atoms under high-magnetic-field conditions.
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Cryogenic Physics: With its wide temperature range (10 mK – 300 K), the equipment can be used to study cryogenic physical phenomena such as superfluidity and Bose-Einstein condensation, and explore the exotic quantum behaviors of matter when approaching absolute zero.
