How to design a sail that won't tear or melt on an interstellar voyage
Light sails need to billow if they are to survive travel at relativistic speeds
Date:
February 16, 2022
Source:
University of Pennsylvania
Summary:
Breakthrough Starshot plans to send microscopic probes to Alpha
Centauri using lightsails. Previous conceptions of these structures
have imagined them being passively pushed by light from the sun,
but Starshot's laser- based approach requires rethinking the sail's
shape and composition so it won't melt or tear during acceleration
to relativistic speeds.
FULL STORY ========================================================================== Astronomers have been waiting decades for the launch of the James Webb
Space Telescope, which promises to peer farther into space than ever
before. But if humans want to actually reach our nearest stellar neighbor,
they will need to wait quite a bit longer: a probe sent to Alpha Centauri
with a rocket would need roughly 80,000 years to make the trip.
==========================================================================
Igor Bargatin, Associate Professor in the Department of Mechanical
Engineering and Applied Mechanics, is trying to solve this futuristic
problem with ideas taken from one of humanity's oldest transportation technologies: the sail.
As part of the Breakthrough Starshot Initiative, he and his colleagues
are designing the size, shape and materials for a sail pushed not by wind,
but by light.
Using nanoscopically thin materials and an array of powerful lasers,
such a sail could carry a microchip-sized probe at a fifth of the speed
of light, fast enough to make the trip to Alpha Centauri in roughly 20
years, rather than millennia.
"Reaching another star within our lifetimes is going to require
relativistic speed, or something approaching the speed of light,"
Bargatin says. "The idea of a light sail has been around for some time,
but we're just now figuring out how to make sure those designs survive
the trip." Much of the earlier research in the field has presumed that
the sun would passively provide all of the energy that light sails would
need to get moving.
However, Starshot's plan to get its sails to relativistic speeds requires
a much more focused source of energy. Once the sail is in orbit, a
massive array of ground-based lasers would train their beams on it,
providing a light intensity millions of times greater than the sun's.
========================================================================== Given that the lasers' target would be a three-meter-wide structure
a thousand times thinner than a sheet of paper, figuring out how to
prevent the sail from tearing or melting is a major design challenge.
Bargatin, Deep Jariwala, Assistant Professor in the Department of
Electrical and Systems Engineering, and Aaswath Raman, Assistant Professor
in the Department of Materials Science and Engineering at the UCLA Samueli School of Engineering, have now published a pair of papers in the journal
Nano Letters that outline some of those fundamental specifications.
One paper, led by Bargatin, demonstrates that Starshot's light sails -
- proposed to be constructed out of ultrathin sheets of aluminum oxide
and molybdenum disulfide -- will need to billow like a parachute rather
than remain flat, as much of the previous research assumed.
"The intuition here is that a very tight sail, whether it's on a sailboat
or in space, is much more prone to tears," Bargatin says. "It's a
relatively easy concept to grasp, but we needed to do some very complex
math to actually show how these materials would behave at this scale."
Rather than a flat sheet, Bargatin and his colleagues suggest that a
curved structure, roughly as deep as it is wide, would be most able to withstand the strain of the sail's hyper-acceleration, a pull thousands
of times that of Earth's gravity.
========================================================================== "Laser photons will fill the sail much like air inflates a beach ball,"
says Matthew Campbell, a postdoctoral researcher in Bargatin's group
and lead author on the first paper. "And we know that lightweight,
pressurized containers should be spherical or cylindrical to avoid tears
and cracks. Think of propane tanks or even fuel tanks on rockets."
The other paper, led by Raman, provides insights into how nanoscale
patterning within the sail could most efficiently dissipate the heat that
comes along with a laser beam a million times more powerful than the sun.
"If the sails absorb even a tiny fraction of the incident laser light,
they'll heat up to very high temperatures," Raman explained. "To make
sure they don't just disintegrate, we need to maximize their ability
to radiate their heat away, which is the only mode of heat transfer
available in space." Earlier light-sail research showed that using
a photonic crystal design, essentially studding the sail's "fabric"
with regularly spaced holes, would maximize the structure's thermal
radiation. The researchers' new paper adds another layer of periodicity: swatches of sail fabric lashed together in a grid.
With the spacing of the holes matching the wavelength of light and the
spacing of the swatches matching the wavelength of thermal emission,
the sail could withstand an even more powerful initial push, reducing
the amount of time the lasers would need to stay on their target.
"A few years ago, even thinking or doing theoretical work on this type of concept was considered far-fetched," Jariwala says. "Now, we not only have
a design, but the design is grounded in real materials available in our
labs. Our plan for the future would be to make such structures at small
scales and test them with high-power lasers." Pawan Kumar, a postdoctoral researcher in Jariwala's lab, as well as John Brewer and Sachin Kulkarni, members of Raman's lab at UCLA Samueli, contributed to this research.
Breakthrough Starshot is part of the Breakthrough Initiatives, a suite
of space science programs investigating the fundamental questions of
life in the Universe. These philanthropic initiatives are funded by the Breakthrough Foundation, established by Yuri Milner and his wife Julia.
========================================================================== Story Source: Materials provided by University_of_Pennsylvania. Original written by Evan Lerner. Note: Content may be edited for style and length.
========================================================================== Related Multimedia:
* An_artist's_conception_of_the_Starshot_Lightsail_spacecraft ========================================================================== Journal Reference:
1. Matthew F. Campbell, John Brewer, Deep Jariwala, Aaswath P. Raman,
Igor
Bargatin. Relativistic Light Sails Need to Billow. Nano Letters,
2021; 22 (1): 90 DOI: 10.1021/acs.nanolett.1c03272 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2022/02/220216130325.htm
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