Nobel Prize in Physics goes to 3 scientists for revealing the 'secrets of exotic matter'
British-born researchers' work will help in 'future applications in both materials science and electronics'
British-born scientists David Thouless, Duncan Haldane and Michael Kosterlitz were awarded this year's Nobel Prize in physics on Tuesday for discoveries on unusual states of matter that could result in improved materials for electronics or quantum computers.
The Royal Swedish Academy of Sciences said the laureates' work in the 1970s and '80s opened the door to a previously unknown world where matter takes unusual states or phase and helped "reveal the secrets of exotic matter".
"Thanks to their pioneering work, the hunt is now on for new and exotic phases of matter," the academy said. "Many people are hopeful of future applications in both materials science and electronics."
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It cited the three for "theoretical discoveries of topological phase transitions and topological phases of matter."
Topology is a branch of mathematics that describes properties of objects.
The judges said that there is now hope that "topological materials will be useful for new generations of electronics and superconductors or in future quantum computers."
Nobel judges often award discoveries made decades ago to make sure they withstand the test of time.
Thouless, 82, is a professor emeritus at the University of Washington. Haldane, 65, is a physics professor at Princeton University in New Jersey. Kosterlitz, 73, is a physics professor at Brown University in Providence, Rhode Island.
Speaking by a phone link to a news conference in Stockholm, Haldane said he was "very surprised and very gratified" by the award, adding the laureates stumbled onto the discoveries.
"Most of the big discoveries are really that way," he said. "At least in theoretical things, you never set out to discover something new. You stumble on it and you have the luck to recognize what you've found is something very interesting."
Kosterlitz, a dual U.K.-U.S. citizen, said he got the news while heading to lunch in Helsinki, where he is currently a visiting professor at Aalto University.
"I'm a little bit dazzled. I'm still trying to take it in," he told The Associated Press.
While most people are familiar with objects in three dimensions, the Nobel laureates analyzed materials so thin they have only two dimensions, or even one.
Scientists had once been skeptical that any interesting atomic-scale behaviour takes place in these settings, but the Nobel laureates proved them wrong, said Phillip Schewe, a physicist and writer at the University of Maryland in College Park.
For example, Kosterlitz and Thouless showed that, against expectations, two-dimensional materials could conduct electricity without any loss to resistance. That property is called superconductivity.
'Complete ignorance' an advantage
Kosterlitz said he was in his 20s at the time and that his "complete ignorance" was an advantage in challenging the established science.
"I didn't have any preconceived ideas," he said. "I was young and stupid enough to take it on."
Their analysis relied on topology, which is the mathematical study of properties that don't change when objects are distorted. A doughnut and a coffee cup are equivalent topologically because they each have exactly one hole. In topology, properties change only in whole steps; you can't have half a hole.
Prize committee member Thor Hans Hansson explained the concept by holding up a cinnamon bun, a bagel and a pretzel with two holes in it to reporters in Stockholm.
Member of the Nobel committee for physics explains topology using a cinnamon bun, a bagel and a pretzel <a href="https://t.co/gORO04UYam">https://t.co/gORO04UYam</a>—@NobelPrize
Thouless was able to explain an experiment conducted with a very thin layer of material. Its electrical resistance varied in response to changes in a magnetic field, but while the strength of the field was changed smoothly, the resistance changed in sharply defined steps. This effect is so precise that it is now used to define the unit of electrical resistance, the ohm.
Phase transition occurs when phases of matter transition between each other, such as when ice melts and becomes water <a href="https://twitter.com/hashtag/NobelPrize?src=hash">#NobelPrize</a> <a href="https://t.co/zpC20Ipgwo">pic.twitter.com/zpC20Ipgwo</a>—@NobelPrize
Nobel committee member David Haviland said this year's prize was more about theoretical discoveries even though they may result in practical applications.
"Topology is a very abstract branch of mathematics which isn't used so frequently in physics," Haviland said. "But these theoreticians have come up with a description of these materials using topological ideas, which have proven very fruitful and has led to a lot of ongoing research about material properties."
The most common phases of matter are gas, liquid & solid. In extremely high or low temperatures matter assumes more exotic states <a href="https://t.co/ZpwAuDfeYT">pic.twitter.com/ZpwAuDfeYT</a>—@NobelPrize
This year's Nobel Prize announcements started Monday with the medicine award going to Japanese biologist Yoshinori Ohsumi for discoveries on autophagy, the process by which a cell breaks down and recycles content.
The chemistry prize will be announced on Wednesday and the Nobel Peace Prize on Friday. The economics and literature awards will be announced next week.
'At least in theoretical thing, you never set out to discover something new. You stumble on it and you have the luck to recognize what you've found is something very interesting.- Duncan Haldane, Nobel Prize winner
Each prize has a purse of 8 million kronor ($1.2 million Cdn). The winners also collect a medal and a diploma at the award ceremonies on Dec. 10, the anniversary of prize founder Alfred Nobel's death in 1896.
Last year, Canadian scientist Arthur McDonald was awarded the prize for physics.
McDonald, a native of Sydney, N.S., and a retired professor from Queen's University in Kingston, Ont., shared the prize with Takaaki Kajita of the University of Tokyo. They were recognized for the discovery of neutrino oscillations and their contributions to experiments showing that neutrinos change identities.
With files from CBC News and Associated Press