Temperature measurements possible even on the smallest scale / Molecular ruby for use in materials science, biology, and medicine
14 June 2017
Chemists at Johannes Gutenberg University Mainz (JGU) in cooperation with researchers of the German Federal Institute for Materials Research and Testing (BAM) in Berlin have developed a molecular thermometer. The gemstone ruby served as the source of inspiration. However, the thermometer developed by the team headed by Professor Katja Heinze at the JGU Institute of Inorganic Chemistry and Analytical Chemistry is a water-soluble molecule, not an insoluble solid. Like a ruby, this molecule contains the element chromium that gives it its red color, which is why it has also been dubbed the molecular ruby. This molecular ruby can be used to measure temperature in many different environments thanks to its solubility: it can be introduced into liquids, solids, nano-particles, and micelles. Thus, it has potential applications in the fields of the materials science, biology, and medicine.
Measuring the temperature with the molecular ruby is very straightforward. The relevant site is irradiated with blue light, which is absorbed by the molecular ruby that then emits infrared radiation at two different wavelengths. Depending on the temperature, there is more intense emission of infrared at one of the two wavelengths. The temperature is then determined on the basis of the corresponding ratio of intensity of the two wavelengths. "Anyone with a simple emission spectrometer can undertake this kind of measurement," explained Sven Otto, a doctoral candidate in Heinze's team. "The molecular ruby works at 100 degrees Celsius just as well as at minus 63 degrees Celsius, that is in a range relevant to everyday practice," added Otto.
The principle of optical ratiometric temperature measurement is not new. However, it was previously impossible to take measurements using only a single type of photoactive agent. To date, scientists always needed two dyes, i.e., one that produced emission dependent on temperature and another reference dye with emission independent of temperature. That made synthesis and calibration a lot more difficult. "Our molecular ruby, on the other hand, is simply made from inexpensive raw materials and no additional reference substances are required to measure temperature," said Professor Katja Heinze. "It can be employed whenever we want to measure temperature without having to contact the object directly as with a conventional thermometer."
The research findings have been published in a special edition of Chemistry designed to mark the 150th anniversary of the German Chemical Society (GDCh) and featuring contributions from eminent German researchers.
The research work is being funded by the German Research Foundation (DFG) within the framework of, inter alia, the Graduate School of Excellence Materials Science in Mainz (MAINZ). The DFG recently approved a new priority program entitled "Light-controlled reactivity of metal complexes" that is coordinated by Professor Katja Heinze.