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New Radio Receiver Opens Wider Window to Radio Universe

Researchers have used the latest wireless technology to develop a new radio receiver for astronomy. The receiver is capable of capturing radio waves at frequencies over a range several times wider than conventional ones, and can detect radio waves emitted by many types of molecules in space at once. This is expected to enable significant progresses in the study of the evolution of the Universe and the mechanisms of star and planet formation.

Interstellar molecular clouds of gas and dust provide the material for stars and planets. Each type of molecule emits radio waves at characteristic frequencies and astronomers have detected emissions from various molecules over a wide range of frequencies. By observing these radio waves, we can learn about the physical properties and chemical composition of interstellar molecular clouds. This has been the motivation driving the development of a wideband receiving system.

In general, the range of radio frequencies that can be observed simultaneously by a radio telescope is very limited. This is due to the characteristics of the components that make up a radio receiver. In this new research, the team of researchers in Osaka Prefecture University (OPU) and the National Astronomical Observatory of Japan (NAOJ) has widened the bandwidth of various components, such as the horn that brings radio waves into the receiver, the waveguide (metal tube) circuit that propagates the radio waves, and the radio frequency converter. By combining these components into a receiver system, the team has achieved a range of simultaneously detectable frequencies several times larger than before. Furthermore, this receiver system was mounted on the OPU 1.85-m radio telescope in NAOJ’s Nobeyama Radio Observatory, and succeeded in capturing radio waves from actual celestial objects. This shows that the results of this research are extremely useful in actual astronomical observations.

Newly developed radio receiving system

Newly developed radio receiving system. The radio waves collected by the antenna are directed to the receiver through the horn at the lower left of the photo and follow the path indicated by the arrow to be output.
Credit: Osaka Prefecture University

Six radio emission lines

Six radio emission lines from isotopologues of carbon monoxide observed simultaneously by the newly developed broadband receiver. The observed object is a region called “Orion KL” in the Orion Nebula.
Credit: Osaka Prefecture University/NAOJ

Distribution of CO isotopologues in the Orion molecular cloud

Distribution of CO isotopologues in the Orion molecular cloud observed simultaneously with the newly developed broadband receiver. The C18O (J=3-2) emission line was also observed, but is not shown because the radio signal strength was too weak to obtain an image.
Credit: Osaka Prefecture University/NAOJ

“It was a very emotional moment for me to share the joy of receiving radio waves from the Orion Nebula for the first time with the members of the team, using the receiver we had built,” comments Yasumasa Yamasaki, an OPU graduate student and the lead author of the paper describing the development of the wideband receiver components. “I feel that this achievement was made possible by the cooperation of many people involved in the project.”

When compared to the receivers currently used in the Atacama Large Millimeter/submillimeter Array (ALMA), the breadth of frequencies that can be simultaneously observed with the new receivers is striking. To cover the radio frequencies between 211 and 373 GHz, ALMA uses two receivers, Band 6 and 7, but can use only one of them at a given time. In addition, ALMA receivers can observe two strips of frequency ranges with widths of 5.5 and 4 GHz using the Band 6 and 7 receivers, respectively. In contrast, the new wideband receiver can cover all the frequencies with a single unit. In addition, especially in the higher frequency band, the receiver can detect radio waves in a frequency range of 17 GHz at a time.

Schematic diagram of the observable frequency bands

Schematic diagram of the observable frequency bands of the newly developed broadband receiver system (top) and the ALMA Band 6 and Band 7 receivers (bottom). The darker areas indicate the frequency bands that can be observed simultaneously. The ALMA Band 6 receiver can observe two 5.5 GHz bands, and the Band 7 receiver can observe two 4 GHz bands at the same time. The newly developed wideband receiver system is capable of observing two 4-GHz bands and one 17-GHz band; thus six carbon monoxide emission lines can be observed simultaneously.
Credit: Osaka Prefecture University/NAOJ

Paper Information

Journal: Publications of the Astronomical Society of Japan

S. Masui et al. “Development of a new wideband heterodyne receiver system for the Osaka 1.85-m mm–submm telescope: Receiver development and the first light of simultaneous observations in 230-GHz and 345-GHz bands with an SIS-mixer with 4–21 GHz IF output”
Y Yamasaki et al. “Development of a new wideband heterodyne receiver system for the Osaka 1.85-m mm-submm telescope — Corrugated horn & Optics covering 210–375 GHz band —

Funding Information

This research was supported by MEXT/JSPS KAKENHI (JP18H05440, JP20J23670, JP15K05025, and JP26247026).

Original Article

URL: https://www.osakafu-u.ac.jp/english-news/pr20210708e/

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