2019-08-01_Sky_and_Telescope

NEWS NOTES

10 AUGUST 2019 • SKY & TELESCOPE

ASTRONOMERS OBSERVING NEARBY

interstellar space have fi nally detected

helium hydride (HeH+), the fi rst mol-

ecule to form in the early universe. Rolf

Güsten (Max Planck Institute for Radio

Astronomy, Germany) and colleagues

report the fi nd in the April 18th Nature.

The early universe contained mostly

hydrogen and helium, so it’s perhaps

unsurprising that its fi rst molecule

would be helium hydride. But of all the

elements, helium requires the most

energy to remove an electron — it’s no

easy feat for it to combine with another

atom. Indeed, the ion didn’t survive

long even in the unique conditions of

the early universe, but it played a brief

but important role. Its destruction gave

rise to molecular hydrogen (H 2 ), which

eventually permeated galaxies and

star-forming reservoirs. The existence of

HeH+ is thus instrumental to under-

standing early chemical evolution.

Yet for years, astronomers tried —

and failed — to detect the molecule.

Although it was created in a lab in 1925,

its fragility makes it rare in the natural

world. Astronomers in the 1970s real-

ized they might fi nd the molecule newly

created in nearby plasmas, but a defi ni-

tive detection eluded them.

So Güsten and colleagues took to the

skies. They fl ew with the Stratospheric

Observatory for Infrared Astronomy

aboard a modifi ed Boeing 747, soar-

ing above the infrared-absorbing lower

atmosphere (S&T: Apr. 2015, p. 60)

to observe a planetary nebula named

NGC 7027. The nebula is an ideal target

because the blazingly hot 600-year-old

white dwarf at its center emits ultra-

violet radiation that strips electrons off

hydrogen and helium atoms alike. The

spherical region where helium is ion-

ized is slightly larger than where both

hydrogen and helium are ionized; in

this outer region, ionized helium is able

to bond with neutral hydrogen to make

helium hydride in a thin shell around

the star. Using the German Receiver

for Astronomy at Terahertz Frequen-

cies instrument, Güsten and colleagues

detected radiation from the ion at

149.137 microns.

Having fi nally discovered HeH+, the

team also studied the formation and

destruction mechanisms of the mole-

cule that kick-started cosmic chemistry.

■ MONICA YOUNG

u Astronomers found helium hydride mol-

ecules (inset) in the heated gas of the planetary

nebula NGC 7027.

pLeft: A new image of LkCa 15 reveals two arcs of light. Middle: A theoretical model with an inner

and outer disk reproduces the arcs. Right: Another theoretical model shows what the image would

look like if the innermost arc were actually multiple planets.

EXCEPTIONAL NEW IMAGES of the LkCa 15 system, a young, Sun-like star once

thought to host multiple gas giant protoplanets, show that these particular planets

probably don’t exist after all.

LkCa 15 has excited astronomers ever since interferometry and direct observa-

tions of hydrogen gas fl ows turned up evidence of up to three gas giants being born

in the protoplanetary disk of gas and dust around the star (S&T: Aug. 2012, p. 20).

These putative planets orbit inside the large outer disk, having presumably cleared

out the inner region. Since LkCa 15 is only a couple million years old, the same

age as our Sun was when Jupiter and Saturn took shape, the discovery promised

insights into the birth of a solar system.

But Thayne Currie (NASA Ames Research Center) and colleagues are throwing

those claims into question with a new study to be published in the Astrophysical

Journal Letters. The team used the Subaru Coronagraphic Extreme Adaptive Optics

system at the Subaru Telescope to take a sharper image of the LkCa 15 system than

ever before obtained.

The resulting view doesn’t show any baby Jupiters; instead, it shows an inner

disk in addition to the outer one. Starlight scattered off the inner disk has the same

brightness as the signals previously attributed to protoplanets.

Keck Observatory images taken in 2009 and 2017 confi rm that this bright arc

remained in the same place over the years. If the light were coming from unre-

solved planets, the arc would have rotated around the star.

Nevertheless, Kate Follette (Amherst College), who was not involved in the new

study, thinks the data still support the existence of at least one protoplanet, and

Currie agrees: “I think it’s very clear that there are planets around the star. They’re

just fainter than we previously thought.” Distinguishing infant planets from the

disk they’re born in will continue to be a challenge.

■ STEVEN MURRAY

COSMOLOGY

Astronomers Find Universe’s First Type of Molecule

EXOPLANETS

Solar System “Twin” Is Missing Infant Jupiters

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