An Infrared Spectrometer Compact Enough to Fit on a Computer Chip

Posted Oct 17, 2019 by ETHZurich

The researchers at ETHZurich, have developed a compact infrared spectrometer. It’s small enough to fit on a computer chip but can still open up interesting possibilities – in space and in everyday life. Nowadays, a mobile phone can do almost anything: take photos or video, send messages, determine its present location, and of course transmit telephone conversations. With these versatile devices, it might even be possible to ascertain a beer’s alcohol content or how ripe a piece of fruit is.

At first glance, the idea of using mobile phones for chemical analyses seems a daring one. After all, the infrared spectrometers used for such analyses today generally weigh several kilograms and are difficult to integrate into a handheld device. Now researchers at ETH have taken an important step towards turning this vision into reality. David Pohl and Marc Reig Escalé, in the group headed by Rachel Grange, Professor of Optical Nanomaterials in the Department of Physics, collaborated with other colleagues to develop a chip about 2 square centimeters in size. With it, they can analyze infrared light in the same way as they would with a conventional spectrometer.

Waveguides Instead of Mirrors

A conventional spectrometer splits the incident light into two paths before reflecting it off two mirrors. The reflected light beams are recombined and measured with a photodetector. Moving one of the mirrors creates an interference pattern, which can be used to determine the proportion of different wavelengths in the incoming signal. Because chemical substances create characteristic gaps in the infrared spectrum, scientists can use the resulting patterns to identify what substances occur in the test sample and in what concentration.

This same principle is behind the mini-spectrometer developed by the ETH researchers. However, in their device, the incident light is no longer analyzed with the help of moveable mirrors; instead, it makes use of special waveguides with an optical refractive index that can be adjusted externally via an electric field. Pohl said that varying the refractive index has an effect similar to what happens when we move the mirrors, so this set-up let us disperse the spectrum of the incident light in the same way.

A Challenging Structuring Process

Depending on how the waveguide is configured, researchers can examine different parts of the light spectrum. According to Escalé, in theory, our spectrometer lets you measure not only infrared light, but also visible light, provided the waveguide is properly configured. In contrast to other integrated spectrometers that can cover only a narrow range of the light spectrum, the device developed by Grange’s group has a major advantage in that it can easily analyze a broad section of the spectrum. Alongside its compact size, the ETH physicists’ innovation offers two other advantages: the ‘spectrometer on a chip’ has to be calibrated only once, compared to conventional devices that needs recalibration over and over again; and because it contains no moving parts, it requires less maintenance.

For their spectrometer, the ETH researchers employed a material that is also used as a modulator in the telecommunications industry. This material has many positive properties, but as a waveguide, it confines the light to the inside. This is less than ideal, as a measurement is possible only if some of the guided light can get out. For this reason, the scientists attached delicate metal structures to the waveguides that scatter the light to the outside of the device.

Perfect for Space

Until the current mini-spectrometer can actually be integrated into a mobile or other electronic device, however, there is still some technological progress to be made. Originally the physicists were aiming, not at chemical analyses, but at a completely different application: in astronomy, infrared spectrometers provide valuable information about distant celestial objects. Because the earth’s atmosphere absorbs a high amount of infrared light, it would be ideal to station these instruments on satellites or telescopes in space. A compact, lightweight and stable measurement device that can be launched into space relatively inexpensively would naturally offer a substantial benefit.