Product Center-Congtical Technology | Temperature‑Cycling Stages

In-situ temperature‑controlled fatigue testing rig

The in-situ variable-temperature fatigue stage is a thermal‑mechanical testing platform specifically designed for material fatigue studies. When coupled with a scanning electron microscope, it enables real-time, in-situ observation of the evolution of a material’s microstructure under combined dynamic temperature and cyclic loading conditions.

Polarizing Microscope Heating and Cooling Stage

The sample stage of the polarizing microscope’s temperature‑controlled stage is movable along the X and Y axes, facilitating convenient sample observation; alternatively, the translation stage can be removed to minimize the overall footprint. This model supports both ambient‑atmosphere and vacuum‑pumping testing and can be equipped with electrical test connectors. Its compact design features a lightweight, thin chamber and a streamlined structure, making it compatible with polarizing microscopes from various manufacturers. It is well suited for analyzing geological inclusions, organic polymers, and other types of samples.

Metallurgical Microscope Heating and Cooling Stage

This temperature‑controlled stage is compatible with mainstream characterization instruments such as metallographic microscopes, PL mapping systems, Raman spectrometers, and confocal microscopes. Specific application scenarios are as follows: When used in conjunction with a metallographic microscope: suitable for research and development of metals and alloys, as well as studies in metallurgy and ceramic processing. When used in conjunction with a PL mapping system: suitable for research on semiconductors (LEDs and photovoltaics), two-dimensional materials, and fluorescent materials.

Microscope In-Situ Tensile Heating and Cooling Stage

Suitable for use with an inverted microscope: after clamping the sample from the front, the stage is inverted onto the specimen holder during microscopic observation. This model’s temperature‑controlled stage employs a specialized threaded clamp mechanism to secure the sample.

Live Cell Workstation

The Live Cell Incubation System is a cutting-edge research instrument designed for studying dynamic cellular processes such as proliferation, differentiation, and drug responses. Featuring precise environmental control and a modular design, it can be seamlessly integrated with various types of microscopes, including confocal and fluorescence microscopes, making it widely applicable in fields like cell biology, cancer research, and regenerative medicine.

Thermoelectric (Peltier) Cooled Spectrometer Heating and Cooling Stage

It can be used in conjunction with a spectrometer, features a compact footprint and rapid temperature‑change capabilities, and is well suited for studying semiconductor materials such as silicon dioxide.

Compact Spectrometer Heating and Cooling Stage

This spectrometer’s cold‑hot stage is compact and offers a wide temperature range. Up to four electrical probes can be added internally, enabling simultaneous optical and electrical signal measurements. Side brackets and atmosphere ports can also be installed, providing exceptional flexibility in use.

Fiber Optic Spectrometer Heating and Cooling Stage

Fiber-optic spectrometers can be used for optical transmission or reflection measurements under variable temperatures, as well as for optical measurements of samples excited by ultraviolet or X-ray radiation. The temperature-control software integrates temperature and spectral data, providing real-time display and storage.

Cryogenic Optical Platform

This model of cryogenic stage features a suspended vibration-isolation design, with sample‑stage vibrations kept below 100 nm. Its compact footprint facilitates seamless integration with microscopes, Raman spectrometers, and other instruments. A wide range of accessories is available, including low‑temperature piezoelectric stages, optical components, electrical connectors, and windows made from various materials, enabling versatile configurations. It is well suited for applications across the semiconductor industry, MEMS, superconductivity, electronics, printed electronics, physics, and materials science.

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