- Arecibo Celebrates National Engineers Week 06 Apr, 2022
- The Arecibo Observatory at the Upcoming 240th American Astronomical Society Meeting06 Apr, 2022
- The Arecibo Observatory Survey Salvage Committee Report06 Apr, 2022
- Facilities and Operations Update06 Apr, 2022
- PRISMA Meteor Radar Arrives at AO04 Apr, 2022
- The Grand Reopening of the Angel Ramos Science and Visitor Center at the Arecibo Observatory01 Apr, 2022
- Orbital stability analysis and photometric characterization of the second Earth Trojan asteroid 2020 XL531 Mar, 2022
- Arecibo Celebrates International Women’s Day31 Mar, 2022
- A Letter from the Director Eng. Francisco Cordova31 Mar, 2022
- The History of Arecibo’s Legacy Telescope to Impact the Future, Thanks to the AO Salvage Survey Committee31 Mar, 2022
- Announcing AO/GBT Single Dish Summer School May 16th - 20th, 2022 30 Mar, 2022
- NSF REU program at Arecibo receives funding for next 3 years23 Mar, 2022
- A Parkes "Murriyang" Search for Pulsars and Transients in the Large Magellanic Cloud23 Mar, 2022
- Noise analysis in the European Pulsar Timing Array data release 2 and its implications on the gravitational-wave background search23 Mar, 2022
- Arecibo S-band Radar Characterization of Local-scale Heterogeneities within Mercury's North Polar Deposits23 Mar, 2022
- Arecibo’s Eye on the Sun21 Mar, 2022
Beating the Noise: Arecibo and Green Bank Telescopes Detect Faint Signals from Cold Clouds in our Galaxy
Byadmin15 December 2021 Astrophysics
Sensitive measurements conducted at the Arecibo Observatory and the Green Bank Observatory may have probed cold regions in our galaxy where molecules are actively being formed from atoms. These regions are the birthplace of molecular clouds, which eventually produce stars.
The telescopes were able to detect weak carbon recombination lines, which are signatures of electrons making transitions at high quantum states within carbon atoms. Scientists used these observations, in combination with measurements made at other radio frequencies, to determine the densities of the cold clouds.
“These unique observations can provide stringent constraints on the properties of the cold clouds, including the rate of molecule formation, which is not well understood,” says Dr. Anish Roshi, Head of Astronomy at the Arecibo Observatory and lead author of the study to appear in the Astrophysical Journal.
“These unique observations can provide stringent constraints on the properties of the cold clouds, including the rate of molecule formation, which is not well understood,” - Dr. Anish Roshi, Head of Astronomy at the Arecibo Observatory
What makes these detections particularly exciting is how difficult they were to achieve. The telescopes were operating at a radio frequency that is often contaminated by noise from everyday radio devices, like cell phones and televisions. This noise is referred to as Radio Frequency Interference, or RFI. Observers have to deal with RFI even if the telescope is located at a radio coordinate zone (like the Arecibo Observatory site) or at a radio quiet zone (like the Green Bank Observatory site). Special techniques to excise or mitigate RFI are essential for detecting weak astronomical signals outside the allocated bands for radio astronomy. A new RFI excision technique developed at Arecibo Observatory was used to detect the weak carbon recombination lines for the study.
The detections demonstrate that the use of multiple, large telescopes in conjunction with RFI excision algorithms is highly effective for observing weak astronomical signals at frequencies below 1 GHz, where the RFI environments are expected to be particularly bad. Without these excision algorithms, the RFI would be too intense to observe recombination lines at the necessary radio frequencies.
To detect the weak recombination lines, it was also essential to use two of the most sensitive radio telescopes: the 305 meter William E. Gordon telescope at the Arecibo Observatory and the Robert C. Byrd Green Bank Telescope.
The combination of these facilities was even more advantageous for this study because the two telescopes were perfectly complementary: the angular resolution of the Arecibo Observatory at 327 MHz is very similar to the angular resolution of the Green Bank Telescope at 750 MHz.
“The matched angular resolution is very important when constraining the properties of the molecular cloud formation regions,” explains Dr. Roshi. “It allows us to observe an identical region of the sky at two different radio frequencies.”
Dr. Roshi and his team will continue the investigation in early 2022 using the Green Bank Telescope to study the well-known molecular cloud forming region called the Heeschen-Riegel-Crutcher cloud.
Keywords: Green, bank, telescope, rfi, roshi, Heeschen-Riegel-Crutcher, galaxies, arecibo, observatory