狐狸视频

U of T physicists discovered a way to increase the resolution of microscopes and telescopes

Photo of Edwin Tham and Hugo Ferretti
U of T PhD students Edwin (Weng Kian) Tham and Hugo Ferretti are part of the team that helped develop a way to look at other properties of light (photo by Diana Tyszko)

狐狸视频 researchers have found a way to increase the resolution of microscopes and telescopes beyond long-accepted limitations by tapping into previously neglected properties of light.

The method allows observers to distinguish very small or distant objects that are so close together they normally meld into a single blur.

The research appears in the journal .

Because of the laws of physics, which cause light to spread out or 鈥渄iffract,鈥 telescopes and microscopes are great for observing lone subjects. With an object like a binary star on the other hand, two stars that are close together may appear at a distance as one blurry dot, and their individual information is irrevocably lost.

Part of the problem is circumventing the limitations of what is referred to as the 鈥淩ayleigh Criterion.鈥

More than 100 years ago, British physicist John William Strutt 鈥 better known as Lord Rayleigh 鈥 established the minimum distance between objects necessary for a telescope to pick out each individually. The 鈥淩ayleigh Criterion鈥 has stood as an inherent limitation of the field of optics ever since.

Telescopes, though, only register light鈥檚 鈥渋ntensity鈥 or brightness. Light has other properties that now appear to allow one to circumvent the Rayleigh Criterion.

鈥淭o beat Rayleigh鈥檚 curse, you have to do something clever,鈥 says Professor Aephraim Steinberg, a physicist at U of T鈥檚 Centre for Quantum Information and Quantum Control and senior fellow in the quantum information science program at the Canadian Institute for Advanced Research. 

鈥淲e measured another property of light called 鈥榩hase.鈥 And phase gives you just as much information about sources that are very close together as it does those with large separations.鈥

Light travels in waves, and all waves have a phase. Phase refers to the location of a wave鈥檚 crests and troughs. Even when a pair of close-together light sources blurs into a single blob, information about their individual wave phases remains intact. You just have to know how to look for it.

This realization was published by National University of Singapore researchers Mankei Tsang, Ranjith Nair, and Xiao-Ming Lu last year in Physical Review X. Researchers like Steinberg and his team immediately set about devising a variety of ways to put it into practice.

鈥淲e tried to come up with the simplest thing you could possibly do,鈥 Steinberg says. 鈥淭o play with the phase, you have to slow a wave down, and light is actually easy to slow down.鈥

His team, including PhD students Edwin (Weng Kian) Tham and Hugo Ferretti, split test images in half. Light from each half passed through glass of a different thickness, which slowed the waves for different amounts of time, changing their respective phases. When the beams recombined, they created distinct interference patterns that told researchers whether the original image contained one object or two 鈥 at resolutions well beyond the Rayleigh Criterion.

So far, Steinberg鈥檚 team has tested the method only in artificial situations involving highly restrictive parameters.

鈥淚 want to be cautious 鈥 these are early stages,鈥 Steinberg says. 鈥淚n our laboratory experiments, we knew we just had one spot or two, and we could assume they had the same intensity. That鈥檚 not necessarily the case in the real world. But people are already taking these ideas and looking at what happens when you relax those assumptions.鈥

The advance has potential applications both in observing the cosmos, and also in microscopy, where the method can be used to study bonded molecules and other tiny, tight-packed structures.

Regardless of how much phase measurements ultimately improve imaging resolution, Steinberg says the experiment鈥檚 true value is in shaking up physicists鈥 concept of 鈥渨here information actually is.鈥

Steinberg鈥檚 鈥渄ay job鈥 is in quantum physics 鈥 this experiment was a departure for him. He says work in the quantum realm provided key philosophical insights about information itself that helped him beat 鈥淩ayleigh鈥檚 curse.鈥

鈥淲hen we measure quantum states, you have something called the Uncertainty Principle, which says you can look at position or velocity, but not both,鈥 he says. 鈥淵ou have to choose what you measure. Now we鈥檙e learning that imaging is more like quantum mechanics than we realized. When you only measure intensity, you鈥檝e made a choice, and you鈥檝e thrown out information. What you learn depends on where you look.鈥

Support for the research was provided by by the Natural Sciences and Engineering Research Council of Canada, the Canadian Institute for Advanced Research, and Northrop-Grumman Aerospace Systems NG Next.

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