1. K-State home
  2. »DCM
  3. »K-State News
  4. »News
  5. »Physicists use lasers to capture first snapshots of rapid chemical bonds breaking

K-State News

K-State News
Kansas State University
128 Dole Hall
1525 Mid-Campus Dr North
Manhattan, KS 66506

785-532-2535
785-532-7355 fax
media@k-state.edu

Physicists use lasers to capture first snapshots of rapid chemical bonds breaking

Friday, Oct. 21, 2016

laser illustration

An intense laser, represented in red, is used to affect an acetylene molecule — composed of two hydrogen atoms, represented as white balls, and two carbon atoms, represented as black balls — to strip out an electron and initiate the break up of the molecule. After nine femtoseconds, the laser drives the free electron back to the elongated molecule to create an image. Kansas State University researchers were able to decode the image and create the first real-time observation of a molecule breaking up.
Illustration courtesy of ICFO-The Institute of Photonic Sciences and Scixel. | Download this photo.

 

MANHATTAN — Lasers have successfully recorded a chemical reaction that happens as fast as a quadrillionth of a second, which could help scientists understand and control chemical reactions.


The idea for using a laser to record a few femtoseconds of a molecule's extremely fast vibrations as it breaks apart came from Kansas State University physicists. Chii-Dong Lin, university distinguished professor of physics, and Anh-Thu Le, research associate professor in James R. Macdonald Laboratory, are part of an international collaborative project published in the Oct. 21 issue of Science.

"If you want to see something that happens very, very fast, you need a tool that can measure a very, very tiny time period," Lin said. "The only light available in femtosecond measurements is a laser."

A femtosecond is one-millionth of a billionth of a second, which is a million times shorter than a nanosecond. Until recently, there was no way to measure what happens during a chemical reaction in that short of a period.

Lin's research group made its first molecular movie of an oxygen molecule using lasers in 2012, but to record a larger molecule — such as the four-atom acetylene molecule — they needed a more advanced laser. After five years of collaboration with Jens Biegert's group from ICFO-The Institute of Photonic Sciences, a member of The Barcelona Institute of Science and Technology, Lin's idea became reality.

The international team used the molecule's own electrons to scatter the molecule — a process called mid-infrared laser-induced electron diffraction, or LIED — and capture snapshots of acetylene as it is breaking apart. An intense laser is used to affectan acetylene molecule — composed of two hydrogen atoms and two carbon atoms — to strip out an electron and initiate the breakup of the molecule. After nine femtoseconds, the laser drives the free electron back to the elongated molecule to create an image.

"Scientists will eventually be able to apply this tool in chemistry, biology and other physical sciences to look at different types of molecules and processes," Lin said.

According to Lin, acetylene's four-atom chemical structure provides multiple possibilities where the bonds could break. Being able to measure where and when those breaks occur can help researchers better understand chemical reactions, which Lin said will lead to better control of a reaction and is applicable to multiple areas of science.

"In order to control something, you have to know where it is first," Lin said. "If you throw a ball over a house, you can't see what happens to it, so you can't control it anymore. But if you have a way to see each second of the ball in the air, you can figure out why it ends up where it does and potentially change the way you throw it to control the outcome or to influence it in real time."

Lin's research group started working with Kansas State University distinguished professor emeritus Lew Cocke's research group in 2008 to conduct the first LIED experiment, which led to the current development. The initial experiments enabled the researchers to apply their theory to decode signals from electrons that produce the image. By decoding the image, the researchers accurately measured the molecule's new bond distances, which are smaller than one hundred-millionth of a centimeter.

"Since the snapshots, which are taken by the electrons, occur in a very strong laser field, it was thought to be nearly impossible to decode the electron information and measure the small distances," said Le, who provided critical decoding of the molecule's structure in the snapshot from Barcelona. "This is the first real-time observation of the breakup of a molecule within nine femtoseconds."

The international collaborators are from the ICFO-The Institute of Photonic Sciences, The Barcelona Institute of Science and Technology, and Catalan Institution for Research and Advanced Studies, all in Spain; the Leiden University in The Netherlands; The University of Kassel, the Center for Free-Electron Laser Science, Max Planck Institute for Nuclear Physics, Physikalisch-Technische Bundesanstalt and University of Jena, all in Germany; and Aarhus University in Denmark.



Sources

Chii-Dong Lin
785-532-1617
 cdlin@k-state.edu

Thu Anh Le
785-532-1635
tle@k-state.edu

Website

James R. Macdonald Laboratory

Photo

Download the following photo.

Professors Lin and Le

Kansas State University's Chii-Dong Lin, university distinguished professor of physics, left, and Anh Thu Le, research associate professor in James R. Macdonald Laboratory, are part of an international team that has recorded a molecule as it breaks apart.

Written by

Stephanie Jacques
785-532-3452
sjacques@k-state.edu

At a glance

Kansas State University researchers are part of an international team that has used a molecule's own electrons to scatter the molecule — a process called mid-infrared laser-induced electron diffraction, or LIED — and capture snapshots of acetylene as it is breaking apart.

Notable quote

"In order to control something, you have to know where it is first. If you throw a ball over a house, you can't see what happens to it, so you can't control it anymore. But if you have a way to see each second of the ball in the air, you can figure out why it ends up where it does and potentially change the way you throw it to control the outcome or to influence it in real time."

— Chii-Dong Lin, university distinguish professor of physics