Tag Archives: Makemake

Webb Discovers Methane Gas on the Dwarf Planet Makemake

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Astronomers utilizing the NASA/ESA/CSA James Webb Space Telescope have discovered evidence of gaseous methane on the remote dwarf planet Macemeiki. This finding is detailed in a paper published in the Astrophysics Journal Letter. This discovery challenges the conventional perception of Makemake as a stable, frozen entity. Following Pltune, where gas presence was confirmed, it is now only the second Transneptune object to display this characteristic.

Protopapa et al. Methane gas was detected with Makemake using Webb observations (white). A sharp radiation peak near 3.3 microns reveals methane in the gas phase on the surface of Makemake. The continuum model (CYAN) is overlaid for comparison. An observable spectrum above the continuum indicates a gas emission peak. Image credit: S. Protopapa/I. Wong/SWRI/STSCI/NASA/ESA/CSA/WEBB.

Makemake, also referred to as FY9 and (136472), was identified in 2005 by a team of astronomers at the California Institute of Technology, led by Mike Brown.

This planet of War is situated in a region beyond Neptune, home to a small solar system.

Its radius measures approximately 715 km (444 miles), making it a dimmer and slightly smaller body than Pluto.

It takes around 305 Earth years for this dwarf planet to complete one orbit around the Sun.

Previously observed stellar occultations indicated that Makemake likely lacked a significant global atmosphere, although thin atmospheres could not be completely dismissed.

Meanwhile, infrared observations suggested mysterious thermal anomalies and peculiar characteristics of its methane ice, hinting at the possibility of local hotspots and potential outgassing on its surface.

“Makemake is one of the largest and brightest icy worlds in the outer solar system, with its surface predominantly comprised of frozen methane,” stated Dr. Sylvia Protopapa, an astronomer at the Southwest Institute.

“Webb has revealed that methane is also present in the gas phase above the surface, making Makemake an even more intriguing subject of study.”

“This indicates that Makemake is not an inert remnant of the outer solar system; rather, it is a dynamic body where methane ice is actively evolving.”

The detected methane spectral emission is interpreted as solar absorbing fluorescence, which occurs when sunlight is re-emitted after being absorbed by methane molecules.

The research team posited that this could either indicate a tenuous atmosphere in equilibrium with surface ice, akin to Pluto, or more transient activities such as comet-like sublimation or cryovolcanic processes.

Both scenarios are plausible and align with current data, given the signal-to-noise ratios and limited spectral resolution.

“The inclination to connect Makemake’s various spectra with thermal anomalies is compelling, but identifying mechanisms that enable volatile activities remains essential to interpreting these observations cohesively.”

“Future Webb observations at higher spectral resolutions will aid in determining whether methane originates from thin atmospheres or outgassing processes like plumes.”

“This discovery opens up the possibility that Makemake has a very thin atmosphere supported by methane sublimation,” noted Dr. Emmanuel Lelouch, an astronomer at the Paris Observatory.

“Our best model estimates a surface pressure around 40 K (minus 233 degrees Celsius) and about 10 picobars, which is a hundred billion times less than Earth’s atmospheric pressure, indicating a dilute surface pressure about ten billion times that of Pluto.”

“If this hypothesis is validated, Makemake will join a select group of outer solar system bodies where surface mass exchanges are still actively occurring today.”

“Another scenario proposes that methane is being expelled in plume-like eruptions,” Dr. Protopapa added.

“In this case, our model indicates that methane may be released at a rate of several hundred kilograms per second, comparable to the intense water plumes seen on Enceladus, Saturn’s moon, and significantly larger than the faint steam observed on Ceres.”

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Silvia Protopapa et al. 2025. JWST detection of hydrocarbon ice and methane gas on Makemake. apjl in press; Arxiv: 2509.06772

Source: www.sci.news

Webb discovers evidence of hydrothermal activity within Ellis and Makemake

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Methane ice of unknown origin exists on the surfaces of the icy dwarf planets Eris and Makemake. Analysis of data from the NASA/ESA/CSA James Webb Space Telescope shows that Ellis and Makemake have rocky cores that have undergone significant radiation heating and are still hot/hot enough to produce methane. There is a possibility.

grain other. Researchers have discovered evidence of hydrothermal or metamorphic activity deep within the icy dwarf planets Eris and Makemake. Image courtesy of Southwest Research Institute.

“We're seeing some interesting signs of a hot period in a cool place,” said Dr. Christopher Grein, a planetary researcher at the Southwest Research Institute.

“I approached this project thinking that because the cold surfaces of large Kuiper Belt Objects (KBOs) can store volatile materials like methane, they should have ancient surfaces with material inherited from the proto-solar nebula. I participated.”

“Instead, Webb had a surprise for us! We found evidence of a thermal process producing methane from inside Ellis and Makemake.”

Dr. Grein and his colleagues used the Webb to observe isotope molecules on the surfaces of Ellis and Makemake for the first time.

These so-called isotopologues are molecules containing atoms with different numbers of neutrons. These provide data that helps us understand the evolution of planets.

The astronomers measured the composition of the dwarf planet's surface, specifically the ratio of deuterium (deuterium, D) to hydrogen (H) in methane.

Deuterium is thought to have formed in the Big Bang, and hydrogen is the most abundant atomic nucleus in the universe.

The D/H ratio of planetary bodies provides information about the origin, geological history, and formation routes of hydrogen-containing compounds.

“The moderate D/H ratio observed by Mr. Webb discredits the existence of primordial methane on the ancient Earth's surface. The D/H ratio of primordial methane would be much higher,” Dr. Grein said. I did.

“Instead, the D/H ratio indicates the geochemical origin of the methane produced deep inside. The D/H ratio is like a window. You can use it to look into the subsurface.”

“Our data suggest that temperatures in the cores of these world rocks could increase and methane could be cooked.”

“Nitrogen molecule (N2) may be generated as well, and this has also been confirmed in Eris. ”

“Hot cores may also indicate a potential source of liquid water beneath the surface of the ice.”

“If Eris and Makemake harbored, or perhaps still harbor, warm or hot geochemistry in their rocky cores, then the surface of these planets is probably geologically recent, due to cryogenic volcanic activity. could be supplied with methane,” said Dr. Will Grundy. Astronomer at Lowell Observatory.

“We discovered the carbon isotope ratio (13C/12C) suggests that the surface has been resurfaced relatively recently. ”

“Following NASA's New Horizons flyby of the Pluto system, and with this discovery, the Kuiper Belt turns out to be much more alive than we imagined in terms of hosting a dynamic world.” said Dr. Grein.

“It's not too early to start thinking about sending spacecraft to fly close to other of these objects to put Webb's data into geological context. I'm sure we'll see the surprises that lie ahead. I think you’ll be surprised!”

of study It was published in the magazine Icarus.

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Christopher R. Grein other. 2024. Moderate D/H ratios in the Ellis and Makemake methane ices indicate evidence of hydrothermal or metamorphic processes in the interior: a geochemical analysis. Icarus 412: 115999; doi: 10.1016/j.icarus.2024.115999

Source: www.sci.news