RudeerTek FURI Series Spectrometer Measurement System Successfully Delivered to University!

Recently, RudeerTek has entered into an in-depth collaboration with a university. As one of the key outcomes of this partnership, the FURI Series Spectrometer Measurement System for University Applications, which is custom-developed for material thermoluminescence spectrum detection, has been successfully delivered and put into research practice, providing precise detection capabilities for the university’s materials science research.

One System, Multi-Dimensional Coverage

The RudeerTek FURI Series Academic System consists of six tightly integrated modules: the FURI Series high-sensitivity spectrometer, a high/low-temperature stage, a measurement bracket, a software system, a water cooling unit, and a communication control cabinet.

Based on thermoluminescence spectroscopy—a key technique for analyzing material properties—the system can meet diverse testing needs, including semiconductor material defect detection, performance characterization of new energy storage materials, thermal stability analysis of inorganic non-metallic materials, optical property studies of nanomaterials, and chronological tracing of archaeological samples.

Detailed Overview of Core Modules

1. Spectrometer + High-Low Temperature Stage + Measurement Stand: The Core Guarantee of Detection Accuracy

As shown in the image below, the high/low-temperature stage is on the left, and on the right is the dedicated measurement bracket for the spectrometer. Connected to the stand is the FURI Series high-sensitivity spectrometer—the “detection core” of the entire system.

The system uses a convenient magnetic fixation method. Simply placing the measurement bracket onto the high-low temperature stage allows for quick assembly and debugging. Once started, it can accurately perform material thermoluminescence spectroscopy measurements without complex operations, significantly improving research efficiency while ensuring the stability and accuracy of measurement data.

2.Software System: Efficient Detection through Data Visualization

The dedicated detection software transforms complex detection data into intuitive and easy-to-understand visual charts, allowing researchers to easily control the entire detection process.

The software interface clearly presents three core charts: ·The top chart is the real-time temperature monitor, showing live temperature changes of the high/low-temperature stage. ·The middle chart is the material thermoluminescence spectrum, accurately capturing details of spectral changes. ·The bottom chart is a dedicated monitor for any selected wavelength of the thermoluminescence spectrum, enabling focused observation of spectral changes at specific wavelengths.

Clicking the “Start” button at the bottom left of the page initiates detection, with full automated data recording. When the detection temperature reaches its peak, the thermoluminescence spectrum also peaks simultaneously. Researchers can analyze spectral data changes at different temperatures to precisely determine the material’s thermoluminescence properties, providing core data support for materials research.

3. Water Cooling Box + Communication Control Box: A Strong Backbone for Detection Stability

The water cooling  box, equipped with dedicated inlet and outlet ports, serves the core function of rapidly cooling the temperature stage, precisely controlling the detection environment temperature to prevent fluctuations from affecting data accuracy.

The connected communication control  box acts as the “command transmission hub.” Through  this, researchers can use the software to remotely control the temperature rise, fall, and communication functions of the temperature stage, enabling automated and intelligent control of the detection process without the need for on-site  personnel , further enhancing research efficiency.

University-Enterprise Collaboration, Building New Momentum for Scientific

The successful delivery of the FURI Series high-sensitivity spectrometer measurement system marks another significant achievement for RudeerTek in deepening its focus on academic research needs and supporting educational and research innovation.

Moving forward, RudeerTek will continue to strengthen industry-academia-research collaboration with universities, guided by research demands, continuously optimizing products and services to jointly advance research capacity building and technological progress in related fields such as materials science and optical detection within higher education.