Linkam Scientific Instruments has launched its enhanced HFS600E-PB4 probe stage for use in micro-sized electrical component temperature control applications.
The new design was implemented in partnership with the company's customer, Radiant Technologies, a major player in the design and manufacture of testing equipment for electrical systems. The combination of the HFS600E-PB4 stage with Radiant test platforms has benefited Radiant’s customers for a number of years, allowing them to carry out analysis of macro-scaled electronic components including ferroelectric and piezoelectric materials across a temperature range from < -195 to 600°C.
However, when testing micro-sized electronic components, positioning the probe was previously challenging for Radiant’s customers, as it was locked into a holder that was magnetically secured into the chamber. Taking this feedback on board, Linkam worked on a new spring-loaded probe that resulted in a new positioner, allowing manual probe repositioning so users can fine-tune the position of the probes when testing small electronic components.
Michael McDaniel, Non Linear System Test Engineer, Radiant Technologies, commented: “Previously it could take five to ten minutes to get a probe into position, because it was so difficult to place the probe tip on the tiny contact pad on the sample. Now, thanks to the modification, we can position the probes within a minute or so, due to the smooth action and ergonomics of the positioner design.”
Linkam’s HFS probe systems are based upon the temperature control technology used in the THMS600 heating and freezing stages. Up to four positional probes can be attached to the electrical connectors within the sample chamber, enabling electrical tests to be carried out while changing the temperature inside a gas tight environment. The sample is placed on the heating element and the probes are moved manually to make contact at the appropriate points.
The connectors in the HFS600E-PB4 handle up to 300 V (with a future revision expected to handle 500 V), making it possible to execute electrical measurements of thin ferroelectric and piezoelectric capacitors (as well as bulk ceramic or single-crystal capacitors). Moreover, the Faraday cage effect resulting from the earth-grounding of the device, combined with an additional ceramic insulator, ensures that capacitance measurements can be made down to ultra-low values.
The new enhancements will be implemented in existing stages later this year.
