Using the strange properties of tiny particles of gold, researchers have concentrated light down smaller than a single atom, letting them look at individual chemical bonds inside molecules, and opening up new ways to study light and matter.
Single gold atoms behave just like tiny metallic ball bearings in our experiments, with conducting electrons roaming around, which is very different from their quantum life.
Jeremy Baumberg
For centuries, scientists believed that light, like all waves, couldn’t be focused down smaller than its wavelength, just under a millionth of a metre. Now, researchers led by the University of Cambridge have created the world’s smallest magnifying glass, which focuses light a billion times more tightly, down to the scale of single atoms.
In collaboration with European colleagues, the team used highly conductive gold nanoparticles to make the world’s tiniest optical cavity, so small that only a single molecule can fit within it. The cavity – called a ‘pico-cavity’ by the researchers – consists of a bump in a gold nanostructure the size of a single atom, and confines light to less than a billionth of a metre. The results, reported in the journal Science, open up new ways to study the interaction of light and matter, including the possibility of making the molecules in the cavity undergo new sorts of chemical reactions, which could enable the development of entirely new types of sensors.
According to the researchers, building nanostructures with single atom control was extremely challenging. “We had to cool our samples to -260°C in order to freeze the scurrying gold atoms,” said Felix Benz, lead author of the study. The researchers shone laser light on the sample to build the pico-cavities, allowing them to watch single atom movement in real time.
“Our models suggested that individual atoms sticking out might act as tiny lightning rods, but focusing light instead of electricity,” said Professor Javier Aizpurua from the Center for Materials Physics in San Sebastian in Spain, who led the theoretical section of this work.
“Even single gold atoms behave just like tiny metallic ball bearings in our experiments, with conducting electrons roaming around, which is very different from their quantum life where electrons are bound to their nucleus,” said Professor Jeremy Baumberg of the NanoPhotonics Centre at Cambridge’s Cavendish Laboratory, who led the research.
The findings have the potential to open a whole new field of light-catalysed chemical reactions, allowing complex molecules to be built from smaller components. Additionally, there is the possibility of new opto-mechanical data storage devices, allowing information to be written and read by light and stored in the form of molecular vibrations.
Learn more: World’s ‘smallest magnifying glass’ makes it possible to see individual chemical bonds between atoms
The Latest on: Interaction of light and matter
[google_news title=”” keyword=”interaction of light and matter” num_posts=”10″ blurb_length=”0″ show_thumb=”left”]
via Google News
The Latest on: Interaction of light and matter
- Mie voids could bring about control of light in airon January 30, 2023 at 11:44 am
Resonant optical phenomena in metals and dielectrics have profound applications in many fields. The nanoscale confinement allows for unpreceded control of light-matter interaction at surfaces and ...
- Dark matter particle that may finally shed light on cosmic mystery the 'best of both worlds,' scientists sayon January 26, 2023 at 9:45 pm
The only way dark matter can be inferred currently is through its interaction with gravity ... How 'hyperactive' can light dark matter be?" McGehee told Space.com. "More technically, how ...
- Is all matter made up of both particles and waves?on December 27, 2022 at 1:04 pm
In 1924, French physics doctoral student Louis de Broglie proposed that matter has a wave-like property. De Broglie was inspired by the discovery of wave-particle duality in light. For centuries ...
- Modeling the Interaction of Light and Materialson December 23, 2022 at 12:18 am
Transmitted: if the surface is transparent, there may be light from a light soruce or another object that has been transmitted through the object. In ray tracing, we treat these three cases separately ...
via Bing News
