Tuesday, August 16, 2022
SCIENMAG: Latest Science and Health News
No Result
View All Result
  • Login
  • HOME PAGE
  • BIOLOGY
  • CHEMISTRY AND PHYSICS
  • MEDICINE
    • Cancer
    • Infectious Emerging Diseases
  • SPACE
  • TECHNOLOGY
  • CONTACT US
  • HOME PAGE
  • BIOLOGY
  • CHEMISTRY AND PHYSICS
  • MEDICINE
    • Cancer
    • Infectious Emerging Diseases
  • SPACE
  • TECHNOLOGY
  • CONTACT US
No Result
View All Result
Scienmag - Latest science news from science magazine
No Result
View All Result
Home SCIENCE NEWS Social & Behavioral Science

X-ray light catchers for space just got a whole lot lighter

July 16, 2022
in Social & Behavioral Science
0
Share on FacebookShare on Twitter

Tokyo, Japan – A team led by scientists from Tokyo Metropolitan University have created unprecedentedly lightweight optics for X-ray space telescopes, breaking the traditional trade-off between angular resolution and weight. They used Micro Electro-Mechanical System (MEMS) technology, creating intricate patterns into silicon wafers that could direct and collect X-rays. By annealing and polishing, they realized ultra-sharp features that could rival the performance of existing telescopes for a fraction of the weight, costing significantly less to launch.

Effect of annealing on surface roughness.

Credit: Tokyo Metropolitan University

Tokyo, Japan – A team led by scientists from Tokyo Metropolitan University have created unprecedentedly lightweight optics for X-ray space telescopes, breaking the traditional trade-off between angular resolution and weight. They used Micro Electro-Mechanical System (MEMS) technology, creating intricate patterns into silicon wafers that could direct and collect X-rays. By annealing and polishing, they realized ultra-sharp features that could rival the performance of existing telescopes for a fraction of the weight, costing significantly less to launch.

X-ray astronomy provides a vital tool which helps scientists study and classify the wide range of celestial bodies which emit and interact with X-rays, including our planet. But there’s a catch: most X-ray radiation is absorbed in our atmosphere, meaning that telescopes and detectors have to be launched into space. With this comes a whole range of limitations, in particular, how heavy the device can be.

One of the key features of all astronomical observation optics is its angular resolution, or the angle that two light sources can make with a detector and still be told apart. The problem with conventional X-ray optics is that, to reach higher resolutions, devices get heavier and heavier. This makes launching them into space very costly. Even for the Hitomi telescope launched in 2016, considered groundbreakingly light, the effective weight was 600 kg per square meter of effective area.

Now, a team led by Associate Professor Yuichiro Ezoe and Aoto Fukushima have broken this trade-off by engineering a high-performance unit weighing only 10 kg per square meter. They used Micro Electro-Mechanical Systems (MEMS) technology, a technique designed to make microscopic mechanical actuators, to pattern sharp, intricate designs into silicon wafers which can direct and collect X-rays. The design itself follows the Wolter I geometry of existing X-ray telescopes, a concentric array of tree-ring-like slits which can nudge X-rays entering via a narrow range of angles and collect them to a point. What’s unique about the team’s work is how they refined the patterning itself. After etching the slits using a technique called deep reactive ion etching (DRIE), they found that there was a surface roughness to the patterns that could smear out the collection of X-rays, effectively decreasing the resolution. So, they “annealed” the pattern, applying heat in a special device for unprecedentedly long times. With progressively longer annealing, the silicon atoms at the surface of the patterns were able to move about more, rounding out any roughness and improving the angular resolution of the telescope. This was followed by grinding and chemical polishing to straighten out the rounded edges of the slits themselves.

Importantly, the performance reported by the team matches that of telescopes which are already in action. Its weight makes it particularly suitable for the GEO-X mission, a satellite designed to visualize the magnetosphere of the Earth. The team are aiming for the staggeringly low total weight of 50kg, a technological breakthrough which may see future missions sent into orbit at incomparably lower cost.

This work was supported by the Japan Society for the Promotion of Science (Grant Numbers 19J20910, 20H00177, 21H04972, 21J12023) and the Toray Science Foundation.



Journal

Optics Express

DOI

10.1364/OE.459774

Article Title

Improvement of imaging performance of silicon micropore X-ray optics by ultra long-term annealing

Article Publication Date

27-Jun-2022

Tags: catcherslightlighterlotspaceXray
Share26Tweet17Share5ShareSendShare
  • Allison Institute announces formation of scientific advisory board

    91 shares
    Share 36 Tweet 23
  • How quinine caused World War I (hyperbolic title alert) (video)

    80 shares
    Share 32 Tweet 20
  • University of Arizona College of Engineering welcomes three new department heads

    70 shares
    Share 28 Tweet 18
  • Reinvigorating ‘lost cause’ exhausted T cells could improve cancer immunotherapy

    141 shares
    Share 56 Tweet 35
  • New chip could make treating metastatic cancer easier and faster

    65 shares
    Share 26 Tweet 16
  • The best way to take pills according to science

    66 shares
    Share 26 Tweet 17
ADVERTISEMENT

About us

We bring you the latest science news from best research centers and universities around the world. Check our website.

Latest NEWS

Reinvigorating ‘lost cause’ exhausted T cells could improve cancer immunotherapy

Experts optimistic about converting coal plants to production of clean geothermal energy

Allison Institute announces formation of scientific advisory board

Subscribe to Blog via Email

Enter your email address to subscribe to this blog and receive notifications of new posts by email.

Join 193 other subscribers

© 2022 Scienmag- Science Magazine: Latest Science News.

No Result
View All Result
  • HOME PAGE
  • BIOLOGY
  • CHEMISTRY AND PHYSICS
  • MEDICINE
    • Cancer
    • Infectious Emerging Diseases
  • SPACE
  • TECHNOLOGY
  • CONTACT US

© 2022 Scienmag- Science Magazine: Latest Science News.

Welcome Back!

Login to your account below

Forgotten Password?

Retrieve your password

Please enter your username or email address to reset your password.

Log In