Gautam Phanse of Chevron Technology Ventures answers questions about this unique program. Photo courtesy

A new program from Houston-based Chevron Technology Ventures is rethinking how best to commercialize research-based technology.

This spring, Chevron Studio announced its second cohort of its program that matches entrepreneurs with promising technologies coming out of universities and labs. The overall goal of the studio — a collaboration between Chevron and the National Renewable Energy Laboratory, or NREL — is to scale up and commercialize early-stage technologies that have the potential to impact the future of energy.

Once selected, there are three phases of the program. After the entrepreneur applications closed in March, the first step was matching the selected entrepreneurs with the inventors of the selected intellectual properties, which will occurs over three to four months. The next phase includes scaling up the product — something that will take one to two years, depending on the tech. The last step would be a trial or a pilot program that includes rolling out a minimum viable product at commercial scale at Chevron or an affiliate. The next cohort application period will open next month.

Gautam Phanse is the strategic relationship manager for Chevron Technology Ventures. He joins InnovationMap for a Q&A to explain more about the opportunity.

What types of technologies is Chevron looking to bring into commercialization through this program? How is the program different from existing accelerators/incubators/etc.?

Gautam Phanse: Chevron Technology Ventures brings external innovation to Chevron. Key focus areas for CTV are industrial decarbonization, emerging mobility, energy decentralization, and the growing circular carbon economy. Chevron Studio is one of the tools to achieve this goal. The current focus areas for Chevron Studio are: carbon utilization, hydrogen and renewable energy, energy storage systems, and solutions for circular economy. These focus areas will be reviewed every year and additional areas could be brought into the mix.

The goal of Chevron Studio is to scale up and commercialize technology developed in the Universities and National Labs. We curate the intellectual property developed at universities and national labs and provide a platform to match entrepreneurs with the IP. The program provides seed funding and a pathway through incubation, pilot and field trials to scale up the technologies. The uniqueness of this program is its target and the breadth of its scope — all the way from incubation to field trials.

How does Chevron Technology Ventures and the National Renewable Energy Laboratory collaborate on this project? What role does each entity play?

GP: CTV has a long history of supporting innovation and the startup community. And over the years we’ve seen the consistent gaps and the struggles that the startup companies have in scaling up technologies. We also have a long history of working with national labs and universities and have seen the challenges in getting these technologies out of the labs. The idea for Chevron Studio grew out of these challenges.

NREL’s Innovation and Entrepreneurship Center manages Chevron Studio, working closing with entrepreneurs and guiding them through the program while leveraging capabilities at the lab and activating the IEC’s network of cleantech startups, investors, foundations, and industry partners.

What are you looking for from the entrepreneur applicants? Who should apply?

GP: We are looking for entrepreneurs who are seeking their next opportunity. They should have a passion in lower carbon solutions and the patience to work on early-stage technologies to see them through scale up and commercialization. Aspiring entrepreneurs with demonstrated passion are also welcome to apply. The entrepreneurs are expected to build a team, raise funds and grow the business providing competitive solutions to the industry.

Tell me about cohort 1. How did it go and what were the participants able to accomplish?

GP: We were really excited about the response we got from both the entrepreneur community and the universities and national labs. We had a strong pool of entrepreneurs and a great mix of IP and frankly had a tough time making the selection. The first cohort had four entrepreneurs in the initial discovery phase. Some of them have now graduated, and we will be announcing the participants in the next phase — for scaling up — shortly.

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This conversation has been edited for brevity and clarity. This article originally ran on InnovationMap.

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Houston energy expert discusses why hydrogen still has a future

Guets Column

Not long ago, hydrogen was hailed as the next big thing in clean energy. Investors poured in, and countries from Japan to Germany built ambitious hydrogen strategies. It wasn’t a new discovery; hydrogen has been used for over a century in refineries and fertilizers, but it suddenly found itself reborn as the world began working toward decarbonization.

When hydrogen burns, the only byproduct is water. Green hydrogen, produced with renewable power, could replace fossil fuels in everything from trucks to ships to steel mills. But the momentum has cooled. Costs remain stubbornly high, several projects have been delayed or canceled, and policy support has wavered. In the U.S., a change in administration has created uncertainty. In Europe, some governments are slowing funding or revising hydrogen mandates. Even the International Maritime Organization (IMO) recently postponed a key vote on fuel-carbon standards.

Yet as Mike Graff , former Chairman and CEO of American Air Liquide, said in an Energy Forum episode with Ed Emmett at Rice University’s Baker Institute, “The world is always looking to make sure that energy is first available, it’s affordable, and then it’s clean. And I see hydrogen over time evolving in that manner.” He also noted that “companies have produced hydrogen and utilized hydrogen for over 100 years, and they’ve done that very safely… I think we can continue that moving forward.”

China has doubled down on hydrogen as part of its industrial strategy, building massive electrolyzer manufacturing capacity and funding dozens of pilot projects across transportation and heavy industry. Japan and South Korea also stand out as examples of how sustained policy support can drive hydrogen progress.

Where Hydrogen Fits Today

To understand hydrogen’s role now, it helps to remember what it actually does. About 76 percent of global hydrogen is produced from natural gas and used in refineries, fertilizer plants, and chemical production. This so-called “gray hydrogen” is essential but carbon-intensive.

What’s new is the rise of low-carbon hydrogen, “blue” hydrogen made from natural gas with carbon capture, and “green” hydrogen produced by splitting water with renewable electricity. These methods are expensive, but they’re growing. According to the International Energy Agency, global low-emissions hydrogen output rose about 10 percent in 2024.

Hydrogen is also expanding beyond industry. As Graff explained, it already powers thousands of forklifts in warehouses across the U.S. and is beginning to appear in commercial trucking, locomotives, and even aviation prototypes. “You can now drive 600 to 800 miles on a hydrogen fuel-cell truck,” he noted, “and refuel in 30 minutes, just like you would refill for diesel.”

The Cost Challenge and a Gulf Coast Opportunity

So why the slowdown? One word: economics.

Even with generous tax credits, green hydrogen can cost two to three times more than conventional fuels. Electrolyzers are still expensive, though costs are falling as Chinese suppliers introduce low-cost alternatives.

Infrastructure is another hurdle. Pipelines, storage, and fueling networks need to be built from scratch.

But those same challenges point to opportunity, especially along the U.S. Gulf Coast. The region already has one of the world’s largest hydrogen pipeline systems and a well-established energy infrastructure. Texas, in particular, has a head start. It already hosts nearly 1,000 miles of hydrogen pipelines, about 64 percent of the U.S. total, and some of the world’s largest hydrogen storage sites at Moss Bluff, Spindletop, and Clemens. Out of 140 hydrogen plants operating nationwide, 43 are in Texas, supported by extensive refining and natural gas infrastructure. This combination of assets gives the Gulf Coast an unmatched foundation to scale low-carbon hydrogen and integrate production, storage, and end use across industries.

As Ken Medlock , Senior Director of the Center for Energy Studies at Rice University’s Baker Institute, explains in his report: Developing a Robust Hydrogen Market in Texas, Texas has all the critical elements needed to lead in a low-carbon hydrogen economy, including existing infrastructure, a skilled workforce, and proximity to industrial demand centers. That combination gives it a distinct advantage in scaling up hydrogen production and use.

Governments around the world are showing renewed confidence in hydrogen. The European Commission awarded nearly €3 billion to 13 major projects, while Japan and South Korea continue expanding fueling networks. China is leading one of the most ambitious buildouts, with more than 50 planned hydrogen projects and a rapidly growing fleet of fuel-cell vehicles. Despite recent setbacks, global investment has surpassed $100 billion, and projects in places such as Chile, where strong renewables and low-cost Chinese equipment help make projects feasible, are moving toward final investment decisions.

What Comes Next

Hydrogen’s future won’t depend on replacing every fuel, but on filling the gaps where batteries and biofuels fall short.

Transportation: This is where momentum is strongest today. Batteries dominate cars, but hydrogen fuel cells excel in heavy trucks, ships, and planes. As Graff noted, “You can design a commercial vehicle with the same utility as diesel but powered by hydrogen.” Airbus and Boeing are testing hydrogen propulsion concepts, and several ports are experimenting with hydrogen bunkering for cargo ships.

Industry: Steel, cement, and chemicals account for a quarter of global emissions. Hydrogen-based direct-reduced-iron (DRI) steelmaking is being piloted in Europe and Asia and could transform how these materials are produced at scale.

Storage: Hydrogen can store energy for days or weeks, serving as backup for renewables like wind and solar. But storage remains very costly and may only prove viable for the “last mile” of greenhouse gas reduction or grid stability.

These uses may sound niche, but that’s how technologies scale. They start small, gain an economic foothold, and expand as costs decline.

Conclusion

Hydrogen's early, perhaps irrational, exuberance may have cooled, but amidst the rubble of cancelled projects are the beginnings of an industry that could play a vital niche role on the journey towards a lower carbon intensity energy future. As costs fall and infrastructure around the world expands, hydrogen's role will expand into the nooks and crannies of the energy industry.

It won't replace every fuel, but it doesn't have to. Success will come from steady, project-by-project progress.

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Scott Nyquist is a senior advisor at McKinsey & Company and vice chairman, Houston Energy Transition Initiative of the Greater Houston Partnership. The views expressed herein are Nyquist's own and not those of McKinsey & Company or of the Greater Houston Partnership. This article originally appeared on LinkedIn.

Houston energy startup launches to power AI data centers with Microsoft agreement

power move

Buoyed by a purchase agreement from Microsoft, Houston-based Joulent recently launched to build power plants that meet the electricity demands of AI data centers and other computing-heavy industries.

Joulent builds dedicated power-generating facilities that feed directly into data centers and other power-dependent facilities, eliminating the need for companies to siphon power from grids. Joulent’s plants combine generation, storage and smart controls in a modular, scalable setup, according to a news release.

Investment firm Engine No. 1 established Joulent in collaboration with energy technology company GE Vernova.

Joulent’s first project, the Project Kilby natural gas facility in West Texas, will be co-located with a Microsoft data center. It’ll deliver about 2.67 gigawatts of power under a 20-year deal between Microsoft and Energy Forge One, a subsidiary of Houston-based Chevron. Engine No. 1 and Chevron teamed up to build the plant.

GE Vernova will supply most of the plant’s power capacity, with additional capacity coming from Solar Turbines, a subsidiary of Irving-based construction and mining equipment manufacturer Caterpillar.

“Leadership in the AI era will be determined by who can deliver energy and compute the fastest, most reliably, and at the lowest cost,” Chris James, founder and CEO of Engine No. 1 and Joulent, said in a news release.

“By building new power-generating facilities, Joulent enables customers across industries to power the next chapter of American innovation, while reducing pressure on existing grids and maintaining affordability for ratepayers.”