This mixer allows for stop-flow measurements from -40° to room temperature with simple operations using liquid nitrogen.
- A sample mixing device that enables stop-flow measurements from -60℃ to room temperature. - By incorporating the RSP-1000 rapid scan system and the TSP-1000 nanosecond transient absorption spectrometer, it demonstrates optimal performance.
Inquire About This Product
basic information
This device is a sample mixing apparatus that enables stop-flow measurements at low temperatures. It supports single mixing measurements, double mixing measurements, and flow flash measurements, allowing the observation of various rapid chemical reactions that can only be measured at low temperatures, using probes such as absorption and fluorescence. It consists of the low-temperature mixing device body, mixing control circuit, temperature control circuit, and a liquid nitrogen container, and is used in conjunction with our rapid scan system RSP-1000 and nanosecond time-resolved spectroscopy system TSP-1000. The operability has been significantly improved through automatic cocking.
Price information
-
Delivery Time
Applications/Examples of results
Supports single mixing measurement / double mixing measurement / flow flash measurement.
Company information
Unisoku was established in 1974 with the aim of becoming a creator of unique measuring instruments. It is a manufacturer that primarily develops and sells its own ultra-high vacuum scanning probe microscopes (SPM) to universities, public institutions, and private companies and research institutes. Over the years, it has developed and commercialized advanced measuring instruments such as high-speed spectroscopic measurement devices and scanning tunneling microscopes, delivering them to universities and research institutions both domestically and internationally, and its technological content has received high praise from researchers in the field of basic research. In recent years, scanning probe microscopes have significantly improved in performance and multifunctionality, particularly as a means of observing sample surfaces at the atomic level. Their applications are expanding mainly from the field of physics to chemistry and bio-related fields, making them indispensable tools in nanotechnology and nanoscience.