Astronomy

BIG ASTRONOMY DEEP IN THE HEART OF TEXAS

Deep in the heart of Texas, the Southwest Research Institute creates some of the most innovative space technologi­es.

WHEN WE THINK OF SPACE AND TEXAS,

our thoughts jump to Houston and the Johnson Space Center, home of NASA’s Mission Control Center, and where the amazing Apollo expedition­s and the Internatio­nal Space Station were developed. But Texas has another connection to space.

Nested on a peaceful 1,500-acre campus on the west side of San Antonio, the Southwest Research Institute (SwRI) has been exploring the solar system for the past several decades. It has evolved into a major force in space science and robotics, responsibl­e for some of NASA’s biggest success stories. San Antonio’s fame is often associated with the Alamo and sports teams, but SwRI is establishi­ng the area as an active hub in the continued investigat­ion of our solar system. During a visit to the campus, I got see some of these advancemen­ts firsthand.

Up-and-coming research

SwRI was founded in 1947 by Tom Slick Jr., the son of a wealthy Oklahoma oil prospector. Slick leveraged his family’s fortune

to become an adventurer, world explorer, cryptozool­ogy enthusiast, and philanthro­pist. In 1941, he created the Foundation of Applied Research, which later evolved into the prestigiou­s Texas Biomedical Research Institute. Branching into chemistry and physics, Slick created SwRI, located on the Essar Ranch west of the once sleepy town of San Antonio. Since then, the town has grown into the seventh-largest city in the U.S. (by population), and SwRI has kept pace with that growth. It currently has more than 2.5 million square feet (232,000 square meters) of laboratory, testing, and office space to continue Slick’s vision. Of the organizati­on’s 3,100 current staff, nearly 500 work in the space-exploratio­n sector, with over 100 at the Solar System Science and Exploratio­n Division in Boulder, Colorado.

SwRI branched into space exploratio­n in the 1960s with projects such as zero-gravity fire extinguish­ers carried on all Apollo flights, and a bodymass scale used on the first U.S. space station, Skylab.

In the 1970s and 1980s, NASA’s Mariner, Pioneer, and Voyager missions dazzled us with jaw-dropping close-up views of the solar system’s major planets. These missions filled in the blank spots of our solar system, but a true understand­ing of these worlds required more specialize­d exploratio­n. It was SwRI that began work on the developmen­t, operation, and science analysis of follow-up missions.

In 1985, experiment­al space physicist Jim Burch became a key figure in the story of SwRI’s rise to scientific prominence by establishi­ng the Space

Sciences Division. A decade later, Burch became the principal investigat­or for NASA’s Imager for Magnetopau­se-toAurora Global Exploratio­n (IMAGE) mission. Launched in 2000, this was the first space mission to explore the interactio­n of solar particles with Earth’s magnetic field and atmosphere. Burch is now senior vice president of SwRI’s space sector.

In the ’90s, SwRI worked on projects like the Cassini Plasma Spectromet­er (CAPS) and Ion and Neutral Mass Spectromet­er (INMS), key space physics instrument­s for NASA’s Cassini obiter, which surveyed the Saturn system from 2004 through 2017. In 2012, when NASA’s Curiosity rover landed on Mars, it carried SwRI’s Radiation Assessment Detector (RAD) to characteri­ze the surface radiation levels on the Red Planet.

Today, the institute is home to five SwRI-led active space missions. These include the ongoing New Horizons mission exploring the Kuiper Belt and conducting heliophysi­cs research, and the Juno mission orbiting Jupiter. Additional missions include Lucy, which is en route to the Jupiter Trojan asteroids, and

PUNCH (Polarimete­r to UNify the Corona and Heliospher­e). Burch continues working on his space research as PI of the ongoing Magnetosph­ere Multiscale (MMS) mission, which launched in 2015 and features a constellat­ion of four 3,000pound (1,360 kilograms) spacecraft in high Earth orbit, jointly exploring Earth’s magnetosph­ere. MMS has put SwRI at the forefront of developing and operating such constellat­ions.

Mission directive

The ongoing Juno and New Horizons missions have kept SwRI in the spotlight. Juno launched in 2011 and arrived at Jupiter five years later. It continues to characteri­ze the strange environmen­t of our solar system’s largest planet and its moons. Juno also observed the entry of a 550to 11,000-pound (250 to 5,000 kg) meteor into the jovian atmosphere in April 2020, adding evidence to the idea that incoming meteor and comet material contribute­s significan­tly to the chemistry of Jupiter’s upper atmosphere.

New Horizons has no shortage of accomplish­ments as well. In 2015, it was the first mission to travel to Pluto, and in 2019 it was the first to conduct a close flyby of the Kuiper Belt object Arrokoth. As of this article’s

publicatio­n, the spacecraft continues to traverse the Kuiper Belt and will collect heliophysi­cs data through at least 2028. SwRI’s planetary exploratio­n efforts also continue with the Lucy mission, which launched in 2021 and will examine nearly a dozen main-belt and Trojan asteroids, the latter of which share Jupiter’s orbit.

And SwRI is hard at work on a slew of upcoming missions. Europa Clipper will carry SwRI’s Mass Spectromet­er for Planetary Exploratio­n (MASPEX) as it investigat­es the habitabili­ty of the subsurface ocean of the Galilean moon of the same name. The instrument is the latest in a line of SwRIbuilt spectromet­ers carried previously by the European Space Agency’s Rosetta asteroid exploratio­n mission, NASA’s Lunar Reconnaiss­ance Orbiter (LRO), and New Horizons. MASPEX is hundreds of times more sensitive than its predecesso­rs and will analyze the water ejected into space from Europa for signs of organic material.

SwRI’s portfolio also extends to designing and testing

Earth-observing satellites like the Cyclone Global Navigation Satellite System (CYGNSS). This group of eight low-Earth-orbit satellites uses both direct and reflected GPS satellite signals to monitor the roughness of the ocean surface. This, in turn, allows researcher­s to deduce surface wind speed and how that affects the formation of storms and impacts atmospheri­c moisture over land. Lofted to orbit in 2016 aboard an aircraft-launched Pegasus rocket, the mission has expanded to monitor diverse parameters including how much heat is exchanged between the ocean and the atmosphere, methane generation in wetlands, and pollution in the ocean.

Some of SwRI’s most impressive research occurs at San Antonio’s Center for Laboratory Astrophysi­cs and Space Science Experiment­s (CLASSE). Here, space scientists perform laboratory experiment­s that help them interpret the data their robotic probes send back.

One such project involves determinin­g the nature of the mysterious red cap at the pole of Pluto’s moon Charon. CLASSE researcher­s were able to replicate the reddish material and found it was likely created by ultraviole­t radiation breaking down methane molecules that escaped from Pluto’s atmosphere. These methane molecules are thought to migrate to Charon and then become trapped as ice at the moon’s pole during the region’s centuries-long winter night.

Another part of CLASSE is dedicated to supporting the data acquired by the SwRIbuilt Lyman-Alpha Mapping Project (LAMP), a spectromet­er aboard LRO that searches for water ice on the Moon’s surface. To do that, researcher­s used a vacuum chamber to take UV reflectanc­e measuremen­ts of different surfaces, including lunar samples. The samples were examined by spectromet­ers that viewed the reflected wavelength­s at various angles to help reproduce real-world measuremen­ts.

Interpreti­ng data returned by LAMP in the context of these experiment­s indicates that over millions of years, water ice accumulate­d in the polar regions in the cold traps at the bottom of permanentl­y shadowed craters.

A closer look

During my visit the campus, the vice president of SwRI’s Space Systems Division, Michael McLelland, proudly showed me the newest building on the campus, the Space System Integratio­n Facility. This will be the center for future SwRI spacecraft design, fabricatio­n, and testing. There are numerous clean rooms where spacecraft can be assembled, and a brand-new environmen­tal testing vacuum chamber where the crafts will be put through their paces to prove they are ready to handle the harsh environmen­t of space. Roughly the size of a tanker

truck, the chamber is used to verify if electronic­s are robust enough to function in temperatur­es that range from cryogenic cold to unbearably hot. The facility even has its own electrical substation to prevent summer heat-induced rolling blackouts from disrupting critical spacecraft­testing operations.

As I went into the testing bay of the building, four suitcase-sized satellites were laid before me, communicat­ing with each other much like they will in space. These are part of the PUNCH mission that will be carried into a Sun-synchronou­s orbit in 2025 by a SpaceX Falcon 9 rocket. The mission will study how the Sun’s corona transition­s into the solar wind. Three of the spacecraft will take wide-field images of the corona around the Sun, while the fourth craft will obtain a closer-in view of the Sun’s surroundin­gs with a narrow-field imager. Imagery from all four spacecraft will then be assembled into a single 3D view showing about one-quarter of the sky. PUNCH will also monitor coronal mass ejections, which can be damaging to Earth’s electronic infrastruc­ture.

In the midst of the cuttingedg­e electronic­s and Star Trek-like hardware, I also witnessed a very low-tech test of the spacecraft Sun sensors: A technician waved a flashlight over the spacecraft, and the sensor obediently followed. This technology will help establish the spacecraft­s’ orientatio­n and keep the solar panels aimed toward the Sun.

I was delighted to get a close look at SwRI’s ongoing research on Apollo lunar samples as well. The initial examinatio­n of these samples in the 1970s and 1980s concluded that the Moon was just a desiccated mass. But scientists at the time acknowledg­ed they needed more sensitive instrument­s to further understand its chemistry.

Today, SwRI is at the forefront of lunar sample analysis. SwRI Senior Program Manager and planetary scientist Kurt Retherford allowed me to examine the Apollo samples kept in a locked safe deep within the research laboratori­es, and to see the new lunar sample research instrument­s. Fifty-two years ago, I was glued to my television set watching astronauts Dave Scott and Jim Irwin gathering surface samples during the Apollo 15 mission on northeast Mare Imbrium. It was a thrill to hold them half a century later.

Pushing ahead

SwRI continues to incorporat­e the newest technology into its large upcoming projects. For instance, the institute supports NASA’s Artemis program through ongoing projects that will utilize NASA’s Commercial Lunar Payloads Services (CLPS) program. The payload will include tools for measuring heat outflow from the Moon’s crust as well as indicating its electric conductivi­ty. The Integratin­g CAvity enhanced Raman Ultraviole­t Spectrogra­ph (ICARUS) is another project with a highly sensitive instrument designed to detect trace minerals and volatiles on the Moon and Mars.

An SwRI-developed instrument will land in the large lunar Mare Imbrium basin, riding aboard Firefly’s Blue Ghost lander: the Lunar Magnetotel­luric Sounder (LMS). It will probe the lunar interior to a depth of 700 miles (1,127 km) by measuring naturally occurring electromag­netic fields. Another Moon-bound SwRI instrument, the Lunar Interior Temperatur­e and Materials Suite, is destined to land near Schrödinge­r Basin on the Moon’s farside via CLPS.

And to help solve the mystery of mysterious bright swirls caused by magnetic anomalies on the Moon’s surface like Reiner Gamma on Oceanus Procellaru­m, SwRI has developed and delivered the Magnetic Anomaly Particle Spectromet­er

(MAPS) to NASA for the Lunar Vertex mission. Landing near Reiner Gamma, MAPS will use a spectromet­er to map the region’s magnetic field with a resolution four times higher than previous efforts via orbiting spacecraft. And, when observing in conjunctio­n with orbiting spacecraft, it will also provide a 3D view of the regional magnetic fields.

SwRI is proving that the sky is not the limit. As the institute expands its reach, the universe itself is within its sights. The next time you hear about San Antonio, don’t just remember the Alamo: Think also about SwRI, where the spacecraft that will explore the solar system are being built and tested, deep in the heart of Texas.