Scientists combine existing technologies to build new ultrafast electron microscope – Phys.org
Click here to sign in with or
Forget Password?
Learn more
share this!
128
15
Share
Email
November 8, 2022
by Nagoya University
Using a unique combination technology, a team of researchers from Nagoya University in Japan has analyzed the mechanisms of the light-matter interaction in nanomaterials at the smallest and fastest levels.
Nanomaterials, materials sized at the nanoscale between 1 and 100 nm, are increasingly important in both industry and everyday living. Their extraordinarily small size gives them unique properties not found in larger materials. These properties are also specific to the nature and environment of the material. To expand the library of nanomaterials that can be applied effectively, safely, and sustainably in products and manufacturing processes, we require a deeper understanding of even the smallest events occurring on and inside the nanoparticles.
To measure nanomaterials, scientists use a subfield of metrology known as nanometrology. Nanometrology measures length scales at the nanoscale. To give this some context, a human hair is about 100,000 times wider. When particles are this small, scientists must also measure events that occur within mere fractions of a second. For example, a phenomenon called photoexcitation normally takes place in picoseconds, or one trillionth of a second. Specialized devices, therefore, are necessary to measure these almost instantaneous events.
A research group led by Nagoya University faculty members, Associate Professor Makoto Kuwahara from the Institute of Materials and Systems for Sustainability (IMaSS) and Lira Mizuno, Rina Yokoi, and Hideo Morishita of the Graduate School of Engineering, investigated whether they could study such photoexcitation processes occurring on single nanoparticles.
In collaboration with senior researchers at Hitachi Hightech Ltd., they developed an ultrafast electron microscope by combining a semiconductor photocathode with a ‘Negative Electron Affinity’ surface, pioneered by Nagoya University, with a general-purpose electron microscope. With the resulting microscope created by combining these technologies, we can observe events at the nanoscale. The researchers published their findings in Applied Physics Letters.
For the nanoparticles, the group used chemically synthesized gold nanotriangles. Gold is suitable for such experiments because it is a noble metal. This means it is stable under a range of conditions. Electrons in gold nanoparticles exhibit a phenomenon called ‘plasmon resonance‘.
When a gold nanoparticle undergoes photoexcitation with a specific wavelength of light, the electrons in the nanoparticle start moving, or oscillating. This intensifies the light, turning the gold nanoparticle into a bright antenna. For this reason, surface plasmons on gold are regularly used for sensing applications and are of great interest in energy conversion.
The plasmons in gold nanoparticles can be photoexcited using the ultrafast laser in the new custom-built ultrafast electron microscope while simultaneously allowing scientists to observe single gold nanoparticles. The researchers investigated two different plasmon phenomena by applying their new technique.
They first observed the relaxation of the plasmons on the surface, which is a well-studied process. However, their new technique also allowed them to view the change in the plasmons inside the gold nanoparticles, even though the light only reached the surface of the nanoparticles.
This is the first time a technique has revealed the relaxation process of these plasmons inside the gold nanoparticles, with important implications for the preparation of light-harvesting materials for energy conversion. The newly developed technique should help analyze potential materials by exposing ultrafast light-matter interactions.
“By understanding phenomena such as photoexcitation and relaxation processes and energy transport, we can improve photoresponsive properties and increase efficiency,” explains Kuwahara.
“In particular, it can be a powerful tool to capture individual time changes in small structural materials with spatial resolution (such as those that exceed sub-micrometers). This has been difficult to achieve with conventional analytical methods using pulsed lasers as probes,” he continued.
“We expect this achievement to enable the analysis of photoelectric and thermoelectric conversion materials and their applied devices that contribute to energy conservation. Our research should be useful for the development of light energy conversion, biosensors, and thermoelectric conversion devices.”
More information: Makoto Kuwahara et al, Transient electron energy-loss spectroscopy of optically stimulated gold nanoparticles using picosecond pulsed electron beam, Applied Physics Letters (2022). DOI: 10.1063/5.0108266
Journal information: Applied Physics Letters
Provided by Nagoya University
More information: Makoto Kuwahara et al, Transient electron energy-loss spectroscopy of optically stimulated gold nanoparticles using picosecond pulsed electron beam, Applied Physics Letters (2022). DOI: 10.1063/5.0108266
Journal information: Applied Physics Letters
Journal information: Applied Physics Letters
Provided by Nagoya University
Explore further
Facebook
Twitter
Email
Feedback to editors
16 hours ago
0
16 hours ago
0
16 hours ago
0
17 hours ago
0
Nov 08, 2022
9
6 hours ago
9 hours ago
10 hours ago
10 hours ago
10 hours ago
10 hours ago
10 hours ago
11 hours ago
11 hours ago
11 hours ago
Apr 27, 2016
Oct 18, 2022
Aug 26, 2021
Sep 10, 2018
Aug 12, 2022
Jun 22, 2022
12 hours ago
10 hours ago
13 hours ago
17 hours ago
Nov 08, 2022
Nov 08, 2022
Use this form if you have come across a typo, inaccuracy or would like to send an edit request for the content on this page. For general inquiries, please use our contact form. For general feedback, use the public comments section below (please adhere to guidelines).
Please select the most appropriate category to facilitate processing of your request
Thank you for taking time to provide your feedback to the editors.
Your feedback is important to us. However, we do not guarantee individual replies due to the high volume of messages.
Your email address is used only to let the recipient know who sent the email. Neither your address nor the recipient’s address will be used for any other purpose. The information you enter will appear in your e-mail message and is not retained by Phys.org in any form.
Get weekly and/or daily updates delivered to your inbox. You can unsubscribe at any time and we’ll never share your details to third parties.
More information Privacy policy
Medical research advances and health news
The latest engineering, electronics and technology advances
The most comprehensive sci-tech news coverage on the web
This site uses cookies to assist with navigation, analyse your use of our services, collect data for ads personalisation and provide content from third parties. By using our site, you acknowledge that you have read and understand our Privacy Policy and Terms of Use.