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Paul O’Connor

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Paul O'Connor. Photo by Roger Stoutenburgh/ BNL

By Daniel Dunaief

The Earth is way too noisy.

The far side of the moon, however, can act like enormous noise cancellation headphones, serving as a barrier to the kinds of signals from sources including Earth’s ionosphere, which carries electromagnetic noises from lightning, solar flares, radio signals, among others to look or, perhaps more appropriately, listen deep into the past.

On Wednesday, May 7, at Napper Tandy’s in Smithtown, three Brookhaven National Laboratory scientists will speak with the public about an unnamed mission expected to take off next year. The free event is part of BNL’s PubSci science café series (www.bnl.gov/pubsci/).

Paul O’Connor. Photo by Roger Stoutenburgh/ BNL

Senior Scientist Paul O’Connor, Mechanical Engineer Connie-Rose Deane and Physicist Anže Slosar will discuss a project called LuSEE-Night, which, like so many other efforts at BNL, is an acronym. LuSEE stands for Lunar Surface Electromagnetic Experiment-Night.

The Department of Energy project manager is Sven Hermann at Brookhaven National Laboratory. Slosar is the science lead, while O’Connor coordinated technical and systems aspects of the instrument development.

The scientists collaborated with researchers at the National Aeronautics and Space Administration and the Department of Energy and included scientists at the University of Minnesota and at the University of California, Berkeley.

The Space Science Laboratory at the University of California, Berkeley is leading the project. BNL is a collaborating member responsible for delivering hardware components of the payload.

LuSEE-Night, which is a radio telescope, is designed to gather information about the Dark Ages of the universe. This time period, from about 380,000 to 400 million years ago after the Big Bang, occurred before the first luminous stars and galaxies. 

Connie-Rose Deane. Photo by David Rahner/ BNL

As the only signals measurable from the Dark Ages, radio waves, recorded through LuSEE-Night provide a chance to learn how the first non-luminous matter evolved into stars and galaxies.

Over the last several years, scientists at the Department of Energy and NASA have shared their excitement about seeing something they had never seen before.

David Rapetti, Senior Researcher with Universities Space Research Association (USRA) at NASA’s Ames Research Center in California’s Silicon Valley, suggested the instrument was a “trailblazer for subsequent potential single telescope experiments for the global signal, also including the Cosmic Down signal at a somewhat higher frequency range.”

Rapetti, who has been with the project since its inception, suggested that this instrument could help with plenty of other science.

“In addition to studies of the sun, planets and exoplanets, the roadmap ahead for low frequency observations from the lunar surface represents a crucial resource to further our understanding of the evolution, content and first luminous objects of the early Universe,” Rapetti explained.

A potential measurement of the global Dark Ages signal could in principle reveal “undiscovered new physics or indeed further validate the current standard model of cosmology,” Rapetti added.

Challenging conditions

When looking for a landing site, the team searched for a flat, level surface that was free of large rocks and craters and that had an unobstructed view of the sky in all directions.

Anže Slosar. Photo by Roger Stoutenburgh/ BNL

They chose the Schrodinger Basin, which is about 250 miles south of the lunar equator at a point “almost exactly opposite the Earth-facing direction,” O’Connor explained. This will keep the telescope as “free as possible from electromagnetic interference from Earth,” he added.

Sending the telescope to the far side of the moon created particular challenges. For starters, the telescope had to endure the forces experienced during launch and landing. Once it was on the moon, it had to tolerate the harsh temperature that could drop as low as minus 280 degrees Fahrenheit, and radiation environment, while staying within the mass and power budgets. The instrument mass is less than 282 pounds.

While the landing site is ideal for minimizing electromagnetic noise, it’s difficult to send the information back to Earth with the moon blocking the communication.

Indeed, the ill-fated Apollo 13 mission, which was led by Commander James Lovell and that orbited the moon without landing, was out of communication for about 25 minutes while it was on the far side of the moon.

To gather data from the telescope, the group is sending a satellite that will orbit the moon, enabling communication that has a 1.3 second time delay in each direction as the signal travels to the moon.

The signal processing chain required a state-of-the-art digital chip that could crunch the data as it comes through small antennas and produces a reduced data set small enough to send back to Earth, explained O’Connor, who worked with a core BNL team of six senior scientists and engineers and about a dozen other engineers, technicians and project staff on a final design that took about 16 months to complete

Additionally, the telescope will only generate solar energy during 14 Earth days a month. During another 14 days, the instrument needs to run without recharging its battery.

To protect the telescope against the harsh, cold environment of the moon, the scientists are wrapping the instrument in many layers of an insulating blanket. The heat from its operation should provide enough energy to prevent damage from the cold.

When the radio telescope launches, the four antennas are coiled into a compact spool the size of a soda can. After landing, the latch is released, allowing the antenna to deploy into self-supporting booms three meters long using their own spring force. At this point, several research and development missions are underway to learn more about the moon in preparation for the Artemis 3 manned mission currently planned for the middle of 2027.

LSST/ Rubin Observatory

O’Connor has also been involved for over two decades with the development of a project called the Large Synoptic Survey Telescope that is now called the Vera C. Rubin Observatory in Cerro Pachón, Chile.

Rubin was an astronomer who provided the first evidence of the existence of dark matter.

The much anticipated activation of this observatory, which will allow researchers to look into billions of galaxies, asteroids and even dark matter, will start producing data in July.

O’Connor, who helped with the film part of the observatory’s camera, suggested that the BNL science team is “most interested in what LSST/ Rubin will tell us about the nature of dark energy and dark matter. This will come from analyzing the camera’s images which, paradoxically, reveal the location of dark matter as it ‘bends’ the light traveling towards us from distant regions in the universe.”

More information about the event on May 7 can be found here.

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In foreground, from left, senior scientist Paul O’Connor holding an electronic board, and Science Raft Subsystem manager Bill Wahl holding a mock raft assembly. Behind O’Connor, on the left, is Sean Robinson, a technical associate, who is working on a raft in the clean room, and to the left is mechanical engineer Connor Miraval, whose image is reflected on the focal plane. Photo from BNL

By Daniel Dunaief

What’s out there? It’s a question that occurs to everyone from parents sleeping at night who hear a noise in the front yard to tourists aboard a whale watching cruise off the coast of Montauk to anyone looking up at the night sky.

Scientists at Brookhaven National Laboratory recently took a milestone step in a long journey to understanding objects and forces deep in space when they completed shipment of the last of 21 rafts that will become a part of the Large Synoptic Survey Telescope, or LSST, in the Cerro Pachón ridge in north central Chile.

The rafts will serve as the film in a camera that will take images that cover 40 times the area of the moon in a single exposure.

The telescope, which will be the world’s largest digital camera for astronomy, will allow researchers and the general public to view asteroids at great distances. It will also provide information about dark energy and dark matter, changes in the night sky over the course of a decade of collecting data, and data that can build on knowledge about the formation and structure of the Milky Way.

Paul O’Connor, a senior scientist at BNL’s Instrumentation Division who has worked on the LSST for 17 years, expressed appreciation for the efforts of people ranging from area high schoolers to senior scientists on the project.

“It was just a joy to see the dedication from everyone to get what needed to be done,” he said in an email. “It takes a team like that to complete a project like this.”

The LSST, which is funded in part by the National Science Foundation and the Department of Energy, involves researchers from institutions all over the world who have each played a role in moving the unique telescope toward completion.

While the rafts that will function as the film for the 3.2-gigapixel sensor array are completed, O’Connor will continue to work on commissioning the telescope, which should occur gradually until it begins providing data in October of 2022.

O’Connor said the construction of the 21 raft modules containing a total of 200 16-megapixel sensors involved “moments of drama, both good and bad.”

The first time the team brought the system into its operating temperature range of about 100 degrees below zero Celsius, some of the cool-down behavior “differed from our predictions,” he explained.

That required quick thinking to make sure the equipment wasn’t damaged. This was especially important not only because the operation needed to stay on schedule but also because the rafts are expensive and the team was operating on a budget. “Each of these rafts has an enormous cash value” and involved considerable labor to build, O’Connor added.

Bill Wahl, the science raft subsystem manager of the LSST project since 2015, described how one of the challenges involved packing and shipping such sensitive electronic materials.

“We came up with a very elegant and somewhat low-cost approach,” he said, which involved shipping these rafts in a pressurized vessel that avoided damage during any shocks in transit.

The rafts, which each weighs about 25 pounds, had a shipping weight that included protective fixtures of over 100 pounds.

Additionally, the BNL team had to deal with cleanliness, as particulates can and did cause problems. Some of the rafts didn’t function the way they should have after shipping. The BNL team went through a complete refurbishing over six months, where they took all the rafts apart and cleaned them. They upgraded the design to limit the amount of particulates, Wahl said.

While BNL built the requisite rafts, it has an additional two rafts that can replace any of those in the telescope if necessary.

These extra rafts will be stored at the observatory.

Along with the challenges and some anxiety from building such sensitive equipment, the instrumentation unit also had several high points.

In January of 2017, BNL tested one of the rafts in the clean room. Scientists constructed an image projector and projected that onto the raft with enough detail to show that every pixel was functioning correctly. O’Connor made a printout of that image and taped it to his office door.

The day of the successful test was one that the team had been anticipating for “over 10 years. When the first image was delivered, it was very gratifying to see the system was working,” he said.

While O’Connor isn’t a cosmologist, he is particularly interested in the search for dark energy. “It has been puzzling the theorists and as experimentalists, we hope to take measurements that will one day lead to a resolution of this fundamental question,” he explained.

Several teams are working on the LSST in different locations. One of them is constructing the telescope in Chile, while another is assembling the camera in California.

At this point, technicians have installed about half the rafts into the main camera cryostat. Researchers will conduct a preliminary test before populating the rest of the focal plane with all the rafts later this year, O’Connor explained.

As the LSST catalogues four billion galaxies, it will “literally be impossible” to look at these areas item by item. Informatics tools will be necessary to extract all the information, O’Connor said.

Wahl suggested that the LSST could become an important educational tool for budding astronomers.

“I’m not an astronomer or physicist,” said Wahl, who will become the chief operating officer of an instrumentation group at BNL on Oct. 1, “but from my point of view, what I find absolutely amazing is that everyone relies heavily on Google Earth to look at where they are going. In a similar way, [people] are going to do that in the sky. It’s going to give them the opportunity to be junior astronomers unlike they’ve ever been able to do.”

Indeed, the LSST will help people figure out what’s out there.

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