Four hundred light-years from
Earth in the constellation Ophiuchus—known as the snake bearer
because it resembles a man grasping a serpent—floats an interstellar
dust cloud. This relatively dense gathering of molecules and particles
holds the makings of two future stars. Made mostly of hydrogen gas,
the cloud also contains helium molecules and frozen dust grains of
carbon and silicon sometimes coated with ice. The list of ingredients
making up this star nursery is interesting, but perhaps pedestrian,
to chemists on Earth. That is, until you get to the part of the list
that mentions trihydrogen, or H3+. This unearthly
molecule consists of three protons arranged in an equilateral triangle,
sharing two electrons among them.The cloud’s temperature
hovers a few tens of degrees above
absolute zero. In this environment, atoms and molecules occasionally
collide and then bounce apart unchanged because they don’t
have enough energy to react. The highly reactive H3+, however, is primed to donate a proton to anything it stumbles
into. The little molecule enriches the chemistry of the cloud by launching
chains of reactions that make larger and more diverse molecules involving
mostly carbon, hydrogen, and oxygen. This extreme reactivity, a boon
for interstellar chemistry, also means that in a dense molecular environment,
such as that found on Earth, H3+’s existence
is so short-lived, it’s rarely observed. As a result, it’s
a relative unknown among chemists.Astronomers, who are more familiar with the simple molecule, have exploited
it as a temperature gauge and a cosmological clock, using it as a
tool to understand conditions around planets in our solar system and
beyond. “Every time we look at H3+, it
helps us uncover some cool, crazy physics,” says James O’Donoghue,
a planetary scientist at the Japan Aerospace Exploration Agency. Meanwhile, scientists
here on Earth are using new technology to generate the triangular
molecule and learn the atomic details of how it forms. H3+ is helping unravel the mysteries of planets, outer
space, star formation, and fundamental chemical processes.
Discovery
in Space
British physicist J. J. Thomson first discovered
H3+ in 1911 in a plasma tube in his lab using
an early form of
mass spectrometry. By the 1960s, scientists speculated that H3+ might be found in space, but it was 1989 before
researchers spotted its characteristic signal coming from Jupiter.A special form of H3+ allowed scientists
to estimate the age of one of these clouds in the star-forming region
of the constellation Ophiuchus. Credit: NASA/JPL-Caltech/WISE Team.The discovery of H3+ in
space hinged on a description of the
molecule’s spectrum, parts of which had been defined
in 1980 by the University of Chicago’s Takeshi Oka. The molecule
emits infrared light at signature wavelengths that can penetrate the
vast distances of space, arriving unimpeded at detectors here on Earth.
Importantly, the ion unleashes its strongest emissions in a set of
wavelengths rarely given off by other molecules, making it a relatively
easy molecule to spot, even light-years away.Jupiter has spectacular
auroras—colorful clouds of charged
gas—but in the 1980s little was known of their chemistry, says Steve
Miller, a planetary scientist at University College London.
So Pierre Drossart of the Paris Observatory, Miller, and their colleagues focused
an infrared telescope on the auroras hovering over Jupiter’s
poles. With a sensitive new spectrometer hooked up to the telescope,
they expected to see evidence of lots of hydrogen gas, H2, the most abundant molecule on the gas giant. Indeed, they did.
But the spectrometer also picked up another set of unexpected IR wavelengths;
Miller and colleagues realized that their predicted IR spectrum of
H3+, which they had built from Oka’s
work, was a perfect match for the mysterious light emissions coming from
Jupiter. The unexpected first-time discovery of H inspired scientists to search
for it elsewhere in the universe. In the past 30 years, researchers
have found H3+ nearly everywhere in outer space
that they have looked. Its presence has given them a tool to directly
observe processes in space that had previously been only theorized
about.“It’s not just that we can see H3+ in the upper atmospheres of planets like Jupiter, Saturn,
and Uranus, but we can derive properties such as the temperature and
density of H3+,” which telegraphs the
temperature and density of the molecule’s surroundings, O’Donoghue
says.Out in space, when sunlight strikes H3+ or
molecules bang into it, the ion absorbs energy and then releases light
at particular IR wavelengths. The intensity of the energy emitted at each wavelength
varies according to the molecule’s temperature, allowing H3+ to act as a virtual thermometer of outer space.Models can also predict the amount of light that a single molecule
of H3+ should emit at various temperatures.
Because of this ability, measuring the light intensity that reaches their
detectors enables researchers to derive the concentration of H3+ above planets’ surfaces. Knowing this
allows scientists to infer the density of other molecules, such as
the water in Saturn’s upper atmosphere.These kinds of
measurements allowed O’Donoghue and colleagues
this year to confirm a long-held hypothesis about the rings of Saturn.
The rings are made of chunks and particles of ice, held in orbit by
the balance between the planet’s gravity and the spinning rings’
centrifugal force. Scientists have long suspected that sometimes these
particles rain down onto the planet. They proposed that ice particles
might get charged by collisions with micrometeors rocketing across
space or by ultraviolet light from the sun. These charged particles
could then get captured by Saturn’s magnetic field and be drawn
into the planet’s upper atmosphere, where they could sublimate
into gaseous, neutrally charged water vapor, the scientists hypothesized.
Neutral water reduces the density of electrons in the atmosphere, which
in turn prolongs the life span of H3+, so areas
of the planet receiving such ring rain should have higher densities
of H3+.Studies of H3+ emissions from Saturn had
observed high concentrations of the molecule encircling the planet
right where water should be coming out of the rings and into the atmosphere.
But a detailed analysis of temperature and density at different latitudes
was missing, O’Donoghue says. After carrying out such analyses,
he and his team not only confirmed that H3+ was
present in patterns that backed up the ring rain theory but also calculated that the entire ring system
will be gone in less than 300 million years, a blink of
an eye in cosmological time, he says.Measurements of H3+ near Saturn show that the material in Saturn’s rings is
raining onto the planet and that the entire ring system will be gone in less than 300 million years. Credit: NASA/JPL-Caltech/Space Science Institute.The H3+ ion has also helped solve
a mystery
about Jupiter’s upper atmosphere. Jupiter is five times as
far from the sun as Earth is, so its upper atmosphere should be extremely
cold. And yet scientists have measured it to be about as warm as Earth’s
upper atmosphere. Why?Earlier modeling studies had suggested
that sound waves emanating
from the surface of Jupiter could be warming the upper atmosphere.
Acoustic waves produced above thunderstorms are known to travel upward
and heat Earth’s atmosphere. Jupiter’s famous Great Red Spot
hosts the largest storm in our solar system, with winds gusting to
over 600 km/h, so it would stand to reason that it might play a part
in warming the planet’s atmosphere.Using wavelengths
emitted by H3+, O’Donoghue
and his team reported in 2016 that they had mapped the temperature
of Jupiter’s upper atmosphere for the first time, finding that
the maximum temperatures occurred right over the Great Red Spot. The team
determined that the pattern of planetary temperatures was consistent
with researchers’ hypothesis that sound waves from the Great Red Spot are heating the atmosphere. The sound waves travel upward, breaking
at the outer layer of the atmosphere like waves on a beach, causing
H3+ and other molecules there to vibrate and
rotate more than normal. This increased kinetic energy means a heated atmosphere.Such findings can help scientists understand more terrestrial
matters, too. Building on these results has revealed that the low
sound frequencies of ocean waves crashing into each other could be heating Earth’s
upper atmosphere.
Beyond the Solar System
O’Donoghue
is looking to find H3+ in
the atmosphere of an exoplanet, a planet outside our solar system.
Seeing the characteristic light emissions of H3+ around an exoplanet would indicate the presence of an ionosphere,
a layer of charged particles in its upper atmosphere. By probing the ionosphere, scientists could learn about conditions on the planet, including whether it might harbor life.In certain situations, a special form of H3+ can also act as a chemical clock, helping astronomers determine how long processes take far beyond our solar system. For instance,
scientists have many questions about how long it takes to make a star, says Olli Sipilä, an astrochemist at the Max Planck Institute for Extraterrestrial
Physics. Star formation occurs over tens of thousands of years, so
conventional clocks can’t track them. But the relative concentrations
of two types of hydrogen molecules—ortho- and para-H2, each with a characteristic IR spectrum—change in a predictable
way as a dust cloud ages, allowing scientists to derive the passage
of time.Sipilä and his colleagues had trained their
sights on the
cold, dense dust cloud in Ophiuchus, hoping to measure its age. The
star-forming process underway there is analogous to the one that birthed
our solar system, right? not our sun? so researchers are naturally keen to know how long
it takes. Models have made predictions ranging from 100,000 years
to more than 1 million years.Marcos Dantus directs molecular
movies using ultrafast laser pulses.
Credit: Kevin W. Fowler/dharmabumphotos.com.The scientists considered using the ortho
and para forms of hydrogen
to judge the age of the cloud. “But the problem is that this
interstellar cloud is too cold to allow us to directly measure H2” from IR emissions, Sipilä says. On the other hand, H3+ is easy to detect, but the problem is that “H3+ itself is not a good chemical clock,”
Sipilä says. There is no straightforward connection to the
ratios of ortho- and para-H2 in H3+. Fortunately, in cold interstellar space, H3+ sometimes substitutes a deuterium ion—a proton and neutron—for
a hydrogen ion, forming H2D+. The ortho and
para forms of H2D+ emit light in different IR
wavelengths. But until recently this ratio could not be used to determine the age of these distant clouds: while the light from ortho-H2D+ will reach a ground-based IR telescope, Earth’s
atmosphere obstructs the IR wavelengths released from para-H2D+. Now, however, thanks to a new telescope onboard an
airplane flying 14 km above Earth, unobscured by the atmosphere,
the researchers measured the IR light emitted from para-H2D+ for the first time in 2014. Using these measurements, Sipilä and his team estimate the cloud core to be 1 million
years old. The finding marks the first confirmed detection
of .
An Atomic View
of H3+
The world of H3+ is not limited to the cold
reaches of outer space. Under the right conditions, scientists can
create the ion in earth-bound chemistry laboratories, says Marcos Dantus, a chemical physicist at Michigan State
University. Dantus and his team specialize in using ultrafast lasers
to make molecular movies, exciting atoms with strobe-like light pulses
and watching how they change on a femtosecond scale. They thought
they might learn more about the dynamics of H3+’s behavior by filming how it forms, timing how long it takes
to break and form bonds, and determining where the atoms go. The 2017
project started from sheer curiosity, Dantus says.Earlier studies
observed that intense laser fields trained on small
organic molecules such as methanol would cause H3+ to form, so Dantus and his team thought they could use this tactic
to make H3+ for their molecular movies. Even
so, the scientists predicted that making H3+ wouldn’t be easy.
“Starting from methanol, the formation of H3+ requires us to doubly ionize the molecule; three chemical
bonds need to break, and three new chemical bonds need to form,”
he says. And all this needs to occur faster than the time it takes for atoms to fly away
from each other and lose their chance to react.To capture what
really happens as H3+ forms,
the scientists injected a thin beam of gaseous methanol into a vacuum.
Then they zapped the methanol with an intense laser beam to trigger
the reaction. As they applied femtosecond laser pulses, which recur
in less time than it takes a C−H bond to vibrate, time-of-flight
mass spectrometry provided measurements of the energy state of the
molecules. A computer simulation translated the data into a molecular
movie of the reaction.The researchers found that the reaction
proceeds by forming a neutral
H2 molecule from two hydrogen atoms on methanol, which
becomes doubly charged under the strong-field laser. But instead of
flying away, the H2 roams around—it liberates itself
from the CHOH2+ and then comes back to snatch a proton to form
H3+. The entire reaction takes about 100 fs.
“Our measurements are providing the first dynamic information
at the molecular level for H3+ chemistry,”
Dantus says. This is the first documented
case of a so-called roaming H, which
is significant because roaming mechanisms are a budding research area
of chemistry, he says.These methanol-based reactions are also
relevant to astrochemistry,
Dantus says. “Most of the galaxies have molecular clouds that
contain methanol and small amounts of larger organic molecules. All
those molecules are being bombarded by radiation and high-energy particles,
both of which cause
the formation of H,” he
says. The reactions are likely similar to the ones
he created in the laboratory. They also matter here on Earth in situations
where high-energy beams are used: “Next time we have an X-ray,
or when we have laser eye surgery we will know that H3+ is being formed,” even if it sticks around for only
a short while, he says. What that means for situations like these,
if anything, is yet unknown because the chemistry is just being discovered.Meanwhile, H3+ continues to hurl its emitted
wavelengths out into the universe for earth-bound scientists to detect.
These scientists hope to probe more areas of the cosmos for the molecule’s
reactive presence. H3+ was there at the beginning, University
College London’s Miller says, and it will be there at the end.Janet Pelley is a freelance contributor to, the weekly newsmagazine of the American Chemical
Society.