Japanese and Dutch Researchers Develop an Innovative Radio Receiver for Cosmic Rays

An international group of researchers from Japan and the Netherlands, have developed an originative radio receiver that has the ability to detect a wide frequency ranges of cosmic radio waves and to disperse them into different frequencies. The radio is called DESHIMA (Deep Spectroscopic High-redshift Mapper). DESHIMA demonstrated its unique power to efficiently measure the distances to the remotest objects as well as to map the distributions of various molecules in nearby cosmic clouds.

The name "DESHIMA" (or, Dejima) was a Dutch trading post in Japan built in the mid-17th century. For 200 years, it was Japan's precious window to the world. Now, the two nations have opened up another window to a new world, the vast Universe, with innovative nanotechnology. According to Akira Endo, a researcher at the Delft University of Technology in Netherlands and the leader of the project, DESHIMA is a completely new type of astronomical instrument with which a 3D map of the early universe can be constructed.

The uniqueness of DESHIMA is that it can disperse the wide frequency range of radio waves into different frequencies. Its instantaneous frequency width (332 - 377 GHz) is more than five times wider than that of the receivers used in the Atacama Large Millimeter/submillimeter Array (ALMA). Dispersing the cosmic radio waves in different frequencies, or spectroscopy, is an important technique to extract information about the universe. Since different molecules emit radio waves in different frequencies, spectroscopic observations tell us the composition of the celestial objects. Also, the cosmic expansion decreases the measured frequencies, and measuring the frequency shift from the native frequency provides us the distances to remote objects.

According to Yoichi Tamura, an associate professor at Japan’s Nagoya University, there are many existing radio receivers with spectroscopic capability, however, the covered frequency range in one observation is quite limited. On the other hand, DESHIMA achieves an ideal balance between the width of frequency range and spectroscopic performance. Behind this unique capability is the innovative nanotechnology. The research team developed a special superconducting electric circuit, a filter-bank, in which radio waves are dispersed into different frequencies, like a sorting conveyor in a fulfillment center. At the end of the "signal conveyors," sensitive Microwave Kinetic Inductance Detectors (MKIDs) are located and detect the dispersed signals.

DESHIMA is the world's first instrument to combine these two technologies on a chip to detect radio waves from the Universe.

As its first test observation, DESHIMA was installed on a 10-m sub millimeter telescope, the Atacama Submillimeter Telescope Experiment (ASTE) operated by the National Astronomical Observatory of Japan (NAOJ) in Northern Chile. The first target was the active Galaxy VV114. The distance to the galaxy has been already measured to be 290 million light-years. DESHIMA successfully detected the signal from the carbon monoxide (CO) molecules in the galaxy at the right frequency expected from the expansion of the Universe.

When astronomers try to detect radio emission from a remote object with unknown distance, usually they sweep a certain range of frequency. Using conventional radio receivers with narrow bandwidth, they need to repeat observations while slightly shifting the frequency. By contrast, the wide-band DESHIMA greatly improves the efficiency of the emission search and helps researchers to produce maps of distant galaxies. Its high performance has also been proven for observations of nearby molecular clouds. It simultaneously captured and imaged the distribution of the emission signals from three molecules, CO, formyl ion (HCO+), and hydrogen cyanide (HCN) in the Orion nebula.

The research team is aiming to further improve the capability of DESHIMA. According to Kotaro Kohno, a professor of The University of Tokyo, their goal is to expand the frequency width, improve sensitivity, and develop a radio camera with 16 pixels. The future DESHIMA will be an important point of departure in various astronomy fields.

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