Hunting Ghost Particles Beneath the World’s Deepest Lake

ON LAKE BAIKAL, Russia — A glass orb, the size of a beach ball, plops into a hole in the ice and descends on a metal cable toward the bottom of the world’s deepest lake.

Then another, and another.

These light-detecting orbs come to rest suspended in the pitch-dark depths down as far as 4,000 feet below the surface. The cable carrying them holds 36 such orbs, spaced 50 feet apart. There are 64 such cables, held in place by anchors and buoys, two miles off the jagged southern coast of this lake in Siberia with a bottom that is more than a mile down.

This is a telescope, the largest of its kind in the Northern Hemisphere, built to explore black holes, distant galaxies and the remnants of exploded stars. It does so by searching for neutrinos, cosmic particles so tiny that many trillions pass through each of us every second. If only we could learn to read the messages they bear, scientists believe, we could chart the universe, and its history, in ways we cannot yet fully fathom.

“You should never miss the chance to ask nature any question,” said Grigori V. Domogatski, 80, a Russian physicist who has led the quest to build this underwater telescope for 40 years.

After a pause, he added: “You never know what answer you will get.”

It is still under construction, but the telescope that Dr. Domogatski and other scientists have long dreamed of is closer than ever to delivering results. And this hunt for neutrinos from the far reaches of the cosmos, spanning eras in geopolitics and in astrophysics, sheds light on how Russia has managed to preserve some of the scientific prowess that characterized the Soviet Union — as well as the limitations of that legacy.

The Lake Baikal venture is not the only effort to hunt for neutrinos in the world’s most remote places. Dozens of instruments seek the particles in specialized laboratories all over the planet. But the new Russian project will be an important complement to the work of IceCube, the world’s largest neutrino telescope, an American-led, $279 million project that encompasses about a quarter of a cubic mile of ice in Antarctica.

Using a grid of light detectors similar to the Baikal telescope, IceCube identified a neutrino in 2017 that scientists said almost certainly came from a supermassive black hole. It was the first time that scientists had pinpointed a source of the rain of high-energy particles from space known as cosmic rays — a breakthrough for neutrino astronomy, a branch that remains in its infancy.

The field’s practitioners believe that as they learn to read the universe using neutrinos, they could make new, unexpected discoveries — much as the lensmakers who first developed the telescope could not have imagined that Galileo would later use it to discover the moons of Jupiter.

“It’s like looking at the sky at night, and seeing one star,” Francis L. Halzen, an astrophysicist at the University of Wisconsin, Madison, and the director of IceCube, said in a telephone interview, describing the current state of the hunt for the ghostly particles.

Early work by Soviet scientists helped inspire Dr. Halzen in the 1980s to build a neutrino detector in the Antarctic ice. Now, Dr. Halzen says his team believes it may have found two additional sources of neutrinos arriving from deep in space — but it is difficult to be certain, because no one else has detected them. He hopes that will change in the coming years as the Baikal telescope expands.

“We have to be superconservative because nobody, at the moment, can check what we are doing,” Dr. Halzen said. “It’s exciting for me to have another experiment to interact with and to exchange data with.”

In the 1970s, despite the Cold War, the Americans and the Soviets were working together to plan a first deep water neutrino detector off the coast of Hawaii. But after the Soviet Union invaded Afghanistan, the Soviets were kicked out of the project. So, in 1980, the Institute for Nuclear Research in Moscow started its own neutrino-telescope effort, led by Dr. Domogatski. The place to try seemed obvious, although it was about 2,500 miles away: Baikal.

The project did not get far beyond planning and design before the Soviet Union collapsed, throwing many of the country’s scientists into poverty and their efforts into disarray. But an institute outside Berlin, which soon became part of Germany’s DESY particle research center, joined the Baikal effort.

Christian Spiering, who led the German team, recalls shipping hundreds of pounds of butter, sugar, coffee and sausage to sustain the annual winter expeditions onto the Baikal ice. He also brought to Moscow thousands of dollars’ worth of cash to supplement the Russians’ meager salaries.

Dr. Domogatski and his team persisted. When a Lithuanian electronics maker refused to accept rubles as payment, one of the physicists negotiated to pay with a train car full of cedar wood, Dr. Spiering recalls.

In a conversation with Dr. Spiering, Dr. Domogatski once compared his scientists to the frog in a Russian proverb that fell in a vat of milk and had only one way to survive: “It’s got to keep moving, until the milk turns to butter.”

By the mid 1990s, the Russian team had managed to identify “atmospheric” neutrinos — those produced by collisions in Earth’s atmosphere — but not ones arriving from outer space. It would need a bigger detector for that. As Russia started to reinvest in science in the 2000s under President Vladimir V. Putin, Dr. Domogatski managed to secure more than $30 million in funding to build a new Baikal telescope as big as IceCube.

The lake is as much as a mile deep, with some of the clearest fresh water in the world, and a czarist-era railroad conveniently skirts the southern shore. Most important, it is covered by a three-foot-thick sheet of ice in the winter: nature’s ideal platform for installing an underwater photomultiplier array.

“It’s as if Baikal is made for this type of research,” said Bair Shaybonov, a researcher on the project.

Construction began in 2015, and a first phase encompassing 2,304 light-detecting orbs suspended in the depths is scheduled to be completed by the time the ice melts in April. (The orbs remain suspended in the water year-round, watching for neutrinos and sending data to the scientists’ lakeshore base by underwater cable.) The telescope has been collecting data for years, but Russia’s minister of science, Valery N. Falkov, plunged a chain saw into the ice as part of a made-for-television opening ceremony this month.

The Baikal telescope looks down, through the entire planet, out the other side, toward the center of our galaxy and beyond, essentially using Earth as a giant sieve. For the most part, larger particles hitting the opposite side of the planet eventually collide with atoms. But almost all neutrinos — 100 billion of which pass through your fingertip every second — continue, essentially, on a straight line.

Yet when a neutrino, exceedingly rarely, hits an atomic nucleus in the water, it produces a cone of blue light called Cherenkov radiation. The effect was discovered by the Soviet physicist Pavel A. Cherenkov, one of Dr. Domogatski’s former colleagues down the hall at his institute in Moscow.

If you spend years monitoring a billion tons of deep water for unimaginably tiny flashes of Cherenkov light, many physicists believe, you will eventually find neutrinos that can be traced back to cosmic conflagrations that emitted them billions of light-years away.

The orientation of the blue cones even reveals the precise direction from which the neutrinos that caused them came. By not having an electrical charge, neutrinos are not affected by interstellar and intergalactic magnetic fields and other influences that scramble the paths of other types of cosmic particles, such as protons and electrons. Neutrinos go as straight through the universe as Einsteinian gravity will allow.

That is what makes neutrinos so valuable to the study of the universe’s earliest, most distant and most violent events. And they could help elucidate other mysteries, such as what happens when stars far more massive than the sun collapse into a superdense ball of neutrons roughly 12 miles across — emitting huge quantities of neutrinos.

“It travels the universe, colliding with practically nothing and no one,” Dr. Domogatski said of the neutrino. “For it, the universe is a transparent world.”

Because it essentially looks through the planet, the Baikal telescope studies the sky of the Southern Hemisphere. That makes it a complement to IceCube in Antarctica, along with a European project in the Mediterranean that is at an earlier phase of construction.

“We need an equivalent to IceCube in the Northern Hemisphere,” said Dr. Spiering, who remains involved in both the IceCube and Baikal projects.

Dr. Domogatski says that his team is already exchanging data with neutrino hunters elsewhere, and that it has found evidence backing up IceCube’s conclusions about neutrinos arriving from outer space. Still, he acknowledges that the Baikal project is lagging far behind others in developing the computer software necessary to identify neutrinos in close to real time.

Despite the project’s significance, it is still operating on a shoestring budget — almost all of the roughly 60 scientists working on the telescope usually spend February and March at their camp in Baikal, installing and repairing its components. IceCube, by contrast, involves some 300 scientists, most of whom have never been to the South Pole.

These days, Dr. Domogatski no longer joins the annual winter expeditions to Baikal. But he still works out of the same Soviet-era institute where he kept his neutrino dream afloat through Communism, the chaotic 1990s and more than two decades of Mr. Putin's rule.

“If you take on a project, you must understand that you have to realize it in any conditions that come up,” Dr. Domogatski said, banging on his desk for emphasis. “Otherwise, there’s no point in even starting.”

Oleg Matsnev contributed research.

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