Researchers using NASA’s James Webb Space Telescope have detected evidence for quartz nanocrystals in the high-altitude clouds of WASP-17 b, a hot Jupiter exoplanet 1,300 light-years from Earth. The detection, which was uniquely possible with MIRI (Webb’s Mid-Infrared Instrument), marks the first time that silica (SiO2) particles have been spotted in an exoplanet atmosphere.
This artist concept shows what the exoplanet WASP-17 b
could look like.
Graphics: NASA, ESA, CSA, and R. Crawfor, d
(STScI)Science: Nikole Lewis (Cornell University), David Grant (University of
Bristol), Hannah Wakeford (University of Bristol) Crawford (STScI)
“We were thrilled!” said David Grant, a researcher at the University of
Bristol in the UK and first author on a paper being published today in
the Astrophysical Journal Letters. “We knew from Hubble observations that there must be
aerosols—tiny particles making up clouds or haze—in WASP-17 b’s atmosphere, but
we didn’t expect them to be made of quartz.”
Silicates (minerals rich in silicon
and oxygen) make up the bulk of Earth and the Moon as well as other rocky
objects in our solar system, and are extremely common across the galaxy. But
the silicate grains previously detected in the atmospheres of exoplanets and
brown dwarfs appear to be made of magnesium-rich silicates like olivine and
pyroxene, not quartz alone – which is pure SiO2.
The result from this team, which
also includes researchers from NASA’s Ames Research Center and NASA’s Goddard
Space Flight Center, puts a new spin on our understanding of how exoplanet
clouds form and evolve. “We fully expected to see magnesium silicates,” said
co-author Hannah Wakeford, also from the University of Bristol. “But what we’re
seeing instead are likely the building blocks of those, the tiny ‘seed’ particles
needed to form the larger silicate grains we detect in cooler exoplanets and
brown dwarfs.”
Detecting Subtle Variations
With a volume more than seven times
that of Jupiter and a mass less than one-half Jupiter, WASP-17 b is one of the
largest and puffiest known exoplanets. This, along with its short orbital
period of just 3.7 Earth-days, makes the planet ideal for transmission spectroscopy : a technique that involves measuring the
filtering and scattering effects of a planet’s atmosphere on starlight.
Webb observed the WASP-17 system
for nearly 10 hours, collecting more than 1,275 brightness measurements of 5-
to 12-micron mid-infrared light as the planet crossed its star. By subtracting
the brightness of individual wavelengths of light that reached the telescope
when the planet was in front of the star from those of the star on its own, the
team was able to calculate the amount of each wavelength blocked by the
planet’s atmosphere.
What emerged was an unexpected “bump” at 8.6 microns, a feature that would not be expected if the clouds were made of magnesium silicates or other possible high temperature aerosols like aluminum oxide, but which makes perfect sense if they are made of quartz.
A transmission spectrum of the hot gas giant exoplanet
WASP-17 b captured by Webb’s Mid-Infrared Instrument (MIRI) on March 12-13,
2023, reveals the first evidence for quartz (crystalline silica, SiO2) in the
clouds of an exoplanet.
The spectrum was made by measuring the change in brightness of 28
wavelength-bands of mid-infrared light as the planet transited the star. Webb
observed the WASP-17 system using MIRI’s low-resolution spectrograph for nearly
10 hours, collecting more than 1,275 measurements before, during, and after the
transit.
For each wavelength, the amount of light blocked by the planet’s atmosphere
(white circles) was calculated by subtracting the amount that made it through
the atmosphere from the amount originally emitted by the star.
The solid purple line is a best-fit model to the Webb (MIRI), Hubble, and
Spitzer data. (The Hubble and Spitzer data cover wavelengths from 0.34 to 4.5
microns and are not shown on the graph.) The spectrum shows a clear feature
around 8.6 microns, which astronomers think is caused by silica particles
absorbing some of the starlight passing through the atmosphere.
The dashed yellow line shows what that part of the transmission spectrum would
look like if the clouds in WASP-17 b’s atmosphere did not contain SiO2.
This marks the first time that SiO2 has been identified in an exoplanet, and
the first time any specific cloud species has been identified in a transiting
exoplanet.
Graphics: NASA, ESA, CSA, and R. Crawfor, d
(STScI)Science: Nikole Lewis (Cornell University), David Grant (University of
Bristol), Hannah Wakeford (University of Bristol) Crawford (STScI)
Download full resolution images for this article from
the Space Telescope Science Institute (STScI)
Crystals, Clouds, and Winds
While these crystals are probably
similar in shape to the pointy hexagonal prisms found in geodes and gem shops
on Earth, each one is only about 10 nanometers across—one-millionth of one
centimeter.
“Hubble data actually played a key
role in constraining the size of these particles,” explained co-author Nikole
Lewis of Cornell University, who leads the Webb Guaranteed Time Observation
(GTO) program designed to help build a three-dimensional view of a hot Jupiter
atmosphere. “We know there is silica from Webb’s MIRI data alone, but we needed
the visible and near-infrared observations from Hubble for context, to figure
out how large the crystals are.”
Unlike mineral particles found in
clouds on Earth, the quartz crystals detected in the clouds of WASP-17 b are
not swept up from a rocky surface. Instead, they originate in the atmosphere
itself. “WASP-17 b is extremely hot—around 1,500 degrees Celsius (2,700°F)—and
the pressure where they form high in the atmosphere is only about
one-thousandth of what we experience on Earth’s surface,” explained Grant. “In
these conditions, solid crystals can form directly from gas, without going
through a liquid phase first.”
Understanding what the clouds are
made of is crucial for understanding the planet as a whole. Hot Jupiters like
WASP-17 b are made primarily of hydrogen and helium, with small amounts of
other gases like water vapor (H2O) and carbon dioxide (CO2). “If we only
consider the oxygen that is in these gases, and neglect to include all of the
oxygen locked up in minerals like quartz (SiO2), we will significantly
underestimate the total abundance,” explained Wakeford. “These beautiful silica
crystals tell us about the inventory of different materials and how they all
come together to shape the environment of this planet.”
Exactly how much quartz there is,
and how pervasive the clouds are, is hard to determine. “The clouds are likely
present along the day/night transition (the terminator), which is the region
that our observations probe,” said Grant. Given that the planet is tidally locked
with a very hot day side and cooler night side, it is likely that the clouds
circulate around the planet, but vaporize when they reach the hotter day side.
“The winds could be moving these tiny glassy particles around at thousands of
miles per hour.”
WASP-17 b is one of three planets
targeted by the JWST-Telescope Scientist Team’s Deep Reconnaissance of Exoplanet Atmospheres
using Multi-instrument Spectroscopy (DREAMS) investigations, which are designed
to gather a comprehensive set of observations of one representative from each
key class of exoplanets: a hot Jupiter, a warm Neptune, and a temperate rocky
planet. The MIRI observations of hot Jupiter WASP-17 b were made as part of GTO
program 1353.
The James Webb Space Telescope is the world’s premier space science observatory. Webb is solving mysteries in our solar system, looking beyond to distant worlds around other stars, and probing the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and the Canadian Space Agency.
Source: Webb Detects Tiny Quartz Crystals in the Clouds of a Hot Gas Giant - NASA
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