University of Houston names first group of Chevron-backed fellows

meet the chosen ones

The PhD and doctoral students will each receive a one-year $12,000 fellowship, along with mentoring from experts at UH and Chevron. Photo via UH.edu

The University of Houston has named eight graduate students to its first-ever cohort of UH-Chevron Energy Graduate Fellows.

The PhD and doctoral students will each receive a one-year $12,000 fellowship, along with mentoring from experts at UH and Chevron. Their work focuses on energy-related research in fields ranging from public policy to geophysics and math. The fellowship is funded by Chevron.

“The UH-Chevron Energy Fellowship program is an exciting opportunity for our graduate students to research the many critical areas that impact the energy industry, our communities and our global competitiveness,” Ramanan Krishnamoortil UH's Vice President for Energy and Innovation says in a statement.

“Today’s students not only recognize the importance of energy, but they are actively driving the push for affordable, reliable, sustainable and secure energy and making choices that clearly indicate that they are meaningfully contributing to the change,” he continues.

“We love that Chevron is sponsoring this group of fellows because it’s a fantastic way for us to get involved with the students who are working on some of the biggest problems we’ll face in society,” Chevron Technology Ventures President Jim Gable adds.

The 2023 UH-Chevron Energy Graduate Fellows are:

Kripa Adhikari, a Ph.D. student in the Department of Civil and Environmental Engineering in the Cullen College of Engineering. Her work focuses on thermal regulation in enhanced geothermal systems. She currently works under the mentorship of Professor Kalyana Babu Nakshatrala and previously worked as a civil engineer with the Nepal Reconstruction Authority.

Aparajita Datta, a researcher at UH Energy and a Ph.D. candidate in the Department of Political Science. Her work focuses on the federal Low-Income Home Energy Assistance Program (LIHEAP), a redistributive welfare policy designed to help households pay their energy bills. She holds a bachelor’s degree in computer science and engineering from the University of Petroleum and Energy Studies in India, and master’s degrees in energy management and public policy from UH. She also recently worked on a paper for UH about transportation emissions.

Chirag Goel, a Ph.D. student in materials science and engineering at UH. His work focuses on using High Temperature Superconductors (HTS) to optimize manufacturing processes, which he says can help achieve carbon-free economies by 2050. The work has uses in renewable energy generation, electric power transmission and advanced scientific applications.

Meghana Idamakanti, a third-year Ph.D. student in the William A. Brookshire Department of Chemical and Biomolecular Engineering. Her work focuses on using electrically heated steam methane for cleaner hydrogen production. She received her bachelor’s degree in chemical engineering from Jawaharlal Nehru Technological University in India in 2020 and previously worked as a process engineering intern at Glochem Industries in India.

Erin Picton, an environmental engineering Ph.D. student in the Shaffer Lab at UH. Her work focuses on ways to increase the sustainability of lithium processing and reducing wasted water and energy. “I love the idea of taking waste and turning it into value,” she said in a statement. She has previously worked in collaboration with MIT and Greentown Labs, as chief sustainability officer of a Houston-based desalination startup; and as a visiting graduate researcher at Argonne National Lab and at INSA in Lyon, France.

Mohamad Sarhan, a Ph.D. student and a teaching assistant in the Department of Petroleum Engineering. His work focuses on seasonal hydrogen storage and the stability of storage candidates during hydrogen cycling. He holds a bachelor’s degree and a master’s degree in petroleum engineering from Cairo University

Swapnil Sharma, a Ph.D. student in the William A. Brookshire Department of Chemical and Biomolecular Engineering. His work has been funded by the Department of Energy and focuses on thermal modeling of large-scale liquid hydrogen storage tanks. He works with Professor Vemuri Balakotaiah. He holds bachelor's and master’s degrees in chemical engineering from the Indian Institute of Technology (IIT). He also developed one of the world’s highest fiber-count optical fiber cables while working in India and founded CovRelief, which helped millions of Indians find resources about hospital beds, oxygen suppliers and more during the pandemic.

Larkin Spires, who's working on her doctoral research in the Department of Earth and Atmospheric Sciences in the College of Natural Sciences and Mathematics. Her work focuses on a semi-empirical Brown and Korringa model for fluid substitution and the ties between geophysics and mathematics. She works under Professor John Castagna and holds a bachelor’s degree in math from Louisiana State University and a master’s degree in geophysics from UH.

Earlier this month Evolve Houston also announced its first-ever cohort of 13 microgrant recipients, whose work aims to make EVs and charging infrastructure more accessible in some of the city's more underserved neighborhoods.

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$524M Texas Hill Country solar project powered by Hyundai kicks off

powering up

Corporate partners—including Hyundai Engineering & Construction, which maintains a Houston office—kicked off a $524 million solar power project in the Texas Hill Country on Jan. 27.

The 350-megawatt, utility-scale Lucy Solar Project is scheduled to go online in mid-2027 and represents one of the largest South Korean-led investments in U.S. renewable energy.

The solar farm, located on nearly 2,900 acres of ranchland in Concho County, will generate 926 gigawatt-hours of solar power each year. That’s enough solar power to supply electricity to roughly 65,000 homes in Texas.

Power to be produced by the hundreds of thousands of the project’s solar panels has already been sold through long-term deals to buyers such as Starbucks, Workday and Plano-based Toyota Motor North America.

The project is Hyundai Engineering & Construction’s largest solar power initiative outside Asia.

“The project is significant because it’s the first time Hyundai E&C has moved beyond its traditional focus on overseas government contracts to solidify its position in the global project financing market,” the company, which is supplying solar modules for the project, says on its website.

Aside from Hyundai Engineering & Construction, a subsidiary of automaker Hyundai, Korean and U.S. partners in the solar project include Korea Midland Power, the Korea Overseas Infrastructure & Urban Development Corp., solar panel manufacturer Topsun, investment firm EIP Asset Management, Primoris Renewable Energy and High Road Energy Marketing.

Primoris Renewable Energy is an Aurora, Colorado-based subsidiary of Dallas-based Primoris Services Corp. Another subsidiary, Primoris Energy Services, is based in Houston.

High Road is based in the Austin suburb of West Lake Hills.

“The Lucy Solar Project shows how international collaboration can deliver local economic development and clean power for Texas communities and businesses,” says a press release from the project’s partners.

Elon Musk vows to put data centers in space and run them on solar power

Outer Space

Elon Musk vowed this week to upend another industry just as he did with cars and rockets — and once again he's taking on long odds.

The world's richest man said he wants to put as many as a million satellites into orbit to form vast, solar-powered data centers in space — a move to allow expanded use of artificial intelligence and chatbots without triggering blackouts and sending utility bills soaring.

To finance that effort, Musk combined SpaceX with his AI business on Monday, February 2, and plans a big initial public offering of the combined company.

“Space-based AI is obviously the only way to scale,” Musk wrote on SpaceX’s website, adding about his solar ambitions, “It’s always sunny in space!”

But scientists and industry experts say even Musk — who outsmarted Detroit to turn Tesla into the world’s most valuable automaker — faces formidable technical, financial and environmental obstacles.

Feeling the heat

Capturing the sun’s energy from space to run chatbots and other AI tools would ease pressure on power grids and cut demand for sprawling computing warehouses that are consuming farms and forests and vast amounts of water to cool.

But space presents its own set of problems.

Data centers generate enormous heat. Space seems to offer a solution because it is cold. But it is also a vacuum, trapping heat inside objects in the same way that a Thermos keeps coffee hot using double walls with no air between them.

“An uncooled computer chip in space would overheat and melt much faster than one on Earth,” said Josep Jornet, a computer and electrical engineering professor at Northeastern University.

One fix is to build giant radiator panels that glow in infrared light to push the heat “out into the dark void,” says Jornet, noting that the technology has worked on a small scale, including on the International Space Station. But for Musk's data centers, he says, it would require an array of “massive, fragile structures that have never been built before.”

Floating debris

Then there is space junk.

A single malfunctioning satellite breaking down or losing orbit could trigger a cascade of collisions, potentially disrupting emergency communications, weather forecasting and other services.

Musk noted in a recent regulatory filing that he has had only one “low-velocity debris generating event" in seven years running Starlink, his satellite communications network. Starlink has operated about 10,000 satellites — but that's a fraction of the million or so he now plans to put in space.

“We could reach a tipping point where the chance of collision is going to be too great," said University at Buffalo's John Crassidis, a former NASA engineer. “And these objects are going fast -- 17,500 miles per hour. There could be very violent collisions."

No repair crews

Even without collisions, satellites fail, chips degrade, parts break.

Special GPU graphics chips used by AI companies, for instance, can become damaged and need to be replaced.

“On Earth, what you would do is send someone down to the data center," said Baiju Bhatt, CEO of Aetherflux, a space-based solar energy company. "You replace the server, you replace the GPU, you’d do some surgery on that thing and you’d slide it back in.”

But no such repair crew exists in orbit, and those GPUs in space could get damaged due to their exposure to high-energy particles from the sun.

Bhatt says one workaround is to overprovision the satellite with extra chips to replace the ones that fail. But that’s an expensive proposition given they are likely to cost tens of thousands of dollars each, and current Starlink satellites only have a lifespan of about five years.

Competition — and leverage

Musk is not alone trying to solve these problems.

A company in Redmond, Washington, called Starcloud, launched a satellite in November carrying a single Nvidia-made AI computer chip to test out how it would fare in space. Google is exploring orbital data centers in a venture it calls Project Suncatcher. And Jeff Bezos’ Blue Origin announced plans in January for a constellation of more than 5,000 satellites to start launching late next year, though its focus has been more on communications than AI.

Still, Musk has an edge: He's got rockets.

Starcloud had to use one of his Falcon rockets to put its chip in space last year. Aetherflux plans to send a set of chips it calls a Galactic Brain to space on a SpaceX rocket later this year. And Google may also need to turn to Musk to get its first two planned prototype satellites off the ground by early next year.

Pierre Lionnet, a research director at the trade association Eurospace, says Musk routinely charges rivals far more than he charges himself —- as much as $20,000 per kilo of payload versus $2,000 internally.

He said Musk’s announcements this week signal that he plans to use that advantage to win this new space race.

“When he says we are going to put these data centers in space, it’s a way of telling the others we will keep these low launch costs for myself,” said Lionnet. “It’s a kind of powerplay.”

$21.5 billion merger will create Houston-based energy powerhouse

Major Merger

Oklahoma City, Oklahoma-based Devon Energy has agreed to buy Houston-based Coterra Energy in a $21.5 billion all-stock deal, forming an energy powerhouse that will be headquartered in Houston. The combined company, boasting an enterprise value of $58 billion, will adopt the Devon brand name.

Revenue for the two publicly traded companies totaled nearly $18.8 billion in the first nine months of 2025. Devon is a Fortune 500 company, but Coterra doesn’t appear in the most recent ranking.

The deal, already approved by the boards of both companies, is expected to close in the second quarter of 2026. Once the transaction is completed, Devon shareholders will own about 54 percent of the combined company and Coterra shareholders will own 46 percent.

“This transformative merger combines two companies with proud histories and cultures of operational excellence, creating a premier shale operator,” says Clay Gaspar, Devon’s president and CEO.

The combined company will be one of the world’s largest shale producers, with third-quarter 2025 production exceeding 550 thousand barrels of oil per day and 4.3 billion cubic feet of gas per day. A significant presence in the Delaware Basin, encompassing hundreds of thousands of acres, will anchor the company’s operations. The 10,000-square-mile Delaware Basin is in West Texas and southeastern New Mexico.

The new Devon also will operate in the Permian Basin, located in West Texas and New Mexico; Marcellus Shale, located in five states in the East; and Anadarko Basin, located in the Texas Panhandle, Colorado, Kansas, and Oklahoma.

Gaspar will be president and CEO of the combined company, and Tom Jorden, chairman, president, and CEO of Coterra, will be non-executive chairman.

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