Hot and cold stage

Advantages: Rapid temperature rise and fall (50℃/min heating, -40℃/min cooling), support for gas atmosphere/vacuum, compatibility with conventional polarizing microscopes, no need for liquid nitrogen supply, and low cost.

Applicable scenarios: Low-temperature observation of biomedical samples

Advantages: Expanded medium temperature range (180°C meets the requirements for polymer softening point testing), temperature control accuracy of ±0.01°C (document parameter table), suitable for experiments requiring long-term medium temperature stability.

Applicable scenarios: Thermal evolution analysis of geological inclusions (such as determination of homogenization temperature of hydrocarbon inclusions), thermal stability testing of polymer materials (such as thermal deformation temperature of plastics).

Advantages: Extreme temperature range coverage (from cryogenic semiconductor testing to high-temperature mineral melting), temperature control accuracy of ±0.01℃ (document parameter table), airtight cavity for oxidation prevention, suitable for rigorous scientific research-level environments.

Applicable scenarios: Ultra-low temperature quantum material observation (such as superconducting phase transition), high-temperature mineralogy research (such as silicate melting process), cryogenic characteristic analysis of semiconductor materials

Advantages: No liquid nitrogen dependence, fast response in high-temperature range (150℃/min), industrial-grade durability (superalloy material), suitable for continuous high-temperature scenarios.

Applicable scenarios: Observation of cermet sintering process, Thermal stability test of high-temperature resistant coatings, Rapid high-temperature screening in industrial quality inspection