Home
In-situ electron microscopy
TEM in-situ solutions
Spring Series In-Situ Holders
Breeze Series In-Situ Holders
Volcano Series In-Situ Holders
Gravity Series In-Situ Holders
Glacier Series Holders
Accessories Series
Consumable Series
SEM in-situ solutions
Spring Series In-Situ Stages
Breeze Series In-Situ Stages
Volcano Series In-Situ Stages
Gravity Series In-Situ Stages
Glacier Series Stages
Others
Single-Tilt Tomography Holders
On-Axis Rotation Tomography Holders(Automatic Full Angle)
Multiple Samples Holders(4 Holes)
Air-Free Transfer holders
Double-tilt Holders(GRID)
SEM Vacuum Transfer Chamber
High Vacuum Storage Instrument for Sample Holders
Case
Liquid electrochemistry
Catalytic
Nano Materials
Metal Materials
Crystal growth
New Energy
About CHIPNOVA
Company Profile
About Us
Corporate Culture
Development History
Corporate Governance
Qualifications and Honors
News
Company News
Exhibition Events
Industry news
Result sharing
Contact Us
Contact information
Consulting Quotes/Programs
EN
Chinese
English
Breeze Series In-Situ Holders(Optics&Heating)
A multi-field automatic control and feedback measurement system integrating light and thermal fields is constructed within the in-situ sample stage, utilizing light sources introduced via MEMS chips and optical fibers. By combining multiple characterization modes including EDS, EELS, SAED, HRTEM, and STEM, real-time and dynamic monitoring is achieved at the nanoscale or even atomic scale. This monitoring captures key information such as the microstructural evolution, reaction kinetics, phase transitions, elemental valence states, chemical changes, microstress, and atomic-scale structural/compositional evolution at the surfaces/interfaces of the sample in a gaseous environment, as the sample responds to variations in light and thermal fields.
Spring Series In-Situ Holders(Heating&Electrochemistry)
A liquid-environment nanolab is constructed within the in-situ sample stage using MEMS micromachining technology. Thermal fields, electrical signals, and other stimuli are applied to thin-film or nanobattery systems via the MEMS chip. By combining multiple characterization modes including EDS, EELS, SAED, HRTEM, and STEM, real-time and dynamic monitoring is achieved at the nanoscale or even atomic scale. This monitoring covers key information such as the microstructural evolution, reaction kinetics, phase transitions, elemental valence states, chemical changes, microstress, and atomic-scale structural/compositional evolution at the surfaces/interfaces of electrodes, electrolytes, and their interfaces in the liquid environment, as these materials respond to variations in temperature and electrical signals.
Spring Series In-Situ Holders(Heating)
A liquid-environment nanolab is constructed in the in-situ sample stage using MEMS micromachining technology. By heating with an MEMS chip and combining multiple modes such as EDS, EELS, SAED, HRTEM, and STEM, real-time and dynamic monitoring of key information at the nanoscale or even atomic scale is achieved, including the microstructural evolution, reaction kinetics, phase transition, element valence state, chemical changes, microstress, and atomic-scale structural and compositional evolution at the surface/interface of the sample in the liquid environment as it changes with temperature.
Spring Series In-Situ Holders(Electrochemistry)
Using MEMS microfabrication technology to construct a liquid atmosphere nanolaboratory in an in-situ sample holder, electrical signals are applied to thin layers or nano battery systems through MEMS chips. While measuring electrical properties, multiple different modes such as EDS, EELS, SAED, HRTEM, STEM, etc. are combined to achieve real-time and dynamic monitoring of the microstructure evolution, reaction kinetics, phase transition of electrodes, electrolytes, and their interfaces under operating conditions at the nano or even atomic level and Key information such as elemental valence states, chemical changes, microstresses, and atomic level structure and compositional evolution at the surface/interface.
Spring Series In-Situ Holders(Optics)
A liquid-environment nanolab is constructed in the in-situ sample stage using MEMS micromachining technology. Light is introduced as an external field condition via the optical fiber built into the sample stage. Light field stimulation is applied to the sample through the MEMS chip and the light source introduced by the optical fiber. While measuring optical properties, multiple modes such as EDS, EELS, SAED, HRTEM, and STEM are used in combination to realize real-time and dynamic monitoring of key information at the nanoscale or even atomic scale, including the microstructural evolution, reaction kinetics, phase transition, element valence state, chemical changes, microstress, and atomic-scale structural and compositional evolution at the surface/interface of the sample in the liquid environment as it changes with the light field.
Glacier Series Stages(Electric Refrigeration)
It adopts semiconductor refrigeration mode and consists of freezing module, PID temperature control module and cooling cycle module. The sample temperature can be controlled from -50℃ to room temperature.
Volcano Series In-Situ Stages(Heating)
The thermal field control is applied to the sample by MEMS chip, and the thermal field automatic control and feedback measurement system is constructed in the in-situ sample station, combined with EDS, EBSD and other different modes. Realize real-time and dynamic monitoring of key information such as microstructure, phase transition, element valence, microscopic stress, atomic structure and composition evolution of samples at the surface/interface with temperature change under vacuum environment from the nano or even atomic level.
Breeze Series In-Situ Stages(Heating)
The atmosphere nanolaboratory was constructed in the in-situ sample table by MEMS micromachining technology, and the thermal field control was applied to the sample through MEMS chip. While thermal property measurement was carried out, EDS and other different modes were combined. The key information such as microstructure evolution, reaction kinetics, phase transition, element valence, chemical change, microscopic stress, and surface/interface structure and composition evolution of samples under atmospheric environment can be monitored in real time and dynamically at the nano level.