Texas hydrogen research hub brings on new corporate partner

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Overall, the project is one of the largest collections of renewable hydrogen production, onsite storage, and end-use technologies that are all located at the same site. Photo via utexas.edu

A Texas US Department of Energy initiative has added a new corporate player.

Hitachi Energy has joined the DOE's H2@Scale in Texas and Beyond initiative with GTI Energy, Frontier Energy, The University of Texas Austin, and others. The initiative, which opened earlier this year, plans to assist in “integrating utility-scale renewable energy sources with power grids and managing and orchestrating a variety of energy sources” according to a news release.

Most of the ‘H2@Scale project’s activities take place at University of Texas JJ Pickle Research Center in Austin. The project is part of a larger one to expand hydrogen’s role and help to decarbonize Texas. The ‘H2@Scale' project consists of multiple hydrogen production options like a vehicle refueling station alongside a fleet of hydrogen fuel cell vehicles.

Overall, the project is one of the largest collections of renewable hydrogen production, onsite storage, and end-use technologies that are all located at the same site.

Another larger goal is to investigate the efficiency and cost-effectiveness of hydrogen generation from renewable resources, which all aligns with the project’s vision of decarbonization efforts.

Hitachi Energy is part of the full hydrogen value chain from early-stage project origination and design. They also work to ensure grid compliance, power conversion systems and asset management solutions.

“Hitachi Energy is proud to be a key partner in the US Department of Energy’s ‘H2@Scale in Texas and Beyond’ project. The initiative comes at a pivotal moment in our commitment to advancing hydrogen production and its role in the evolving clean energy landscape,” Executive Vice President and Region Head of North America at Hitachi Energy Anthony Allard says in a news release. “As hydrogen emerges as a critical element in decarbonizing hard-to-abate industries, Hitachi Energy remains dedicated to drive innovation and sustainability on a global scale.”

Hitachi’s project teams will undertake feasibility studies for scaling up hydrogen production and use, which will aim to benefit the development of a strategic plan and implementation of the H2@Scale project in the Port of Houston and the region of the Gulf Coast. The teams will also seek opportunities to leverage prospective hydrogen users, pre-existing hydrogen pipelines, and large networks of concentrated industrial infrastructure. Then, they will work to identify environmental and economic benefits of hydrogen deployment in the area.

Earlier this year, Hitachi Energy teamed up with teamed up with Houston-based electrical transmission developer Grid United for a collaboration to work on high-voltage direct current technology for Grid United transmission projects. These projects will aim to interconnect the eastern and western regional power grids in the U.S. The Eastern Interconnection east of the Rocky Mountains, the Western Interconnection west of the Rockies and the Texas Interconnection run by the Electric Reliability Council of Texas, make up the three main power grids.

Texas hydrogen research hub opens to support statewide, DOE-backed initiative

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A Texas school has cut the ribbon on a new hydrogen-focused research facility that will play a role in a statewide, Department of Energy-funded energy transition initiative.

The Center for Electromechanics at The University of Texas, Frontier Energy, Inc., and GTI Energy celebrated the grand opening of a hydrogen research and demonstration facility in Austin as part of the “Demonstration and Framework for H2@Scale in Texas and Beyond” project, which is supported by the DOE's Hydrogen and Fuel Cell Technologies Office.

The hydrogen proto-hub is first-of-its-kind and part of Texas-wide initiative for a cleaner hydrogen economy and will feature contributions from organizations throughout the state. The facility will generate zero-carbon hydrogen by using water electrolysis powered by solar and wind energy, and steam methane reformation of renewable natural gas from a Texas landfill.

The hydrogen will be used to power a stationary fuel cell for power for the Texas Advanced Computing Center, and it will also supply zero-emission fuel to cell drones and a fleet of Toyota Mirai fuel cell electric vehicles. This method will mark the first time that multiple renewable hydrogen supplies and uses have been networked at one location to show an economical hydrogen ecosystem that is scalable.

“The H2@Scale in Texas project builds on nearly two decades of UT leadership in hydrogen research and development” Michael Lewis, Research Scientist, UT Austin Center for Electromechanics, say in a news release. “With this facility, we aim to provide the educated workforce and the engineering data needed for success. Beyond the current project, the hydrogen research facility is well-positioned for growth and impact in the emerging clean hydrogen industry.”

Over 20 sponsors and industry stakeholders are involved and include Houston-based partners in Center for Houston’s Future and Rice University Baker Institute for Public Policy. Industry heavyweights like Chevron, Toyota, ConocoPhillips, and the Texas Commission on Environmental Quality are also part of the effort.

Texas hydrogen infrastructure and wind and solar resources position the state for clean hydrogen production, as evident in the recently released study, “A Framework for Hydrogen in Texas.” The study was part of a larger effort that started in 2020 with the H2@Scale project, which aims to develop clearer paths to renewable hydrogen as a “clean and cost-effective fuel” according to a news release. The facility will serve as an academic research center, and a model for future large-scale hydrogen deployments.

Participants in the DOE-funded HyVelocity Gulf Coast Hydrogen Hub will aim to gain insights from the H2@Scale project at UT Austin. The project will build towards a development of a comprehensive hydrogen network across the region. HyVelocity is a hub that includes AES Corporation, Air Liquide, Chevron, ExxonMobil, Mitsubishi Power Americas, Orsted, and Sempra Infrastructure. The GTI Energy administered HyVelocity involves The University of Texas at Austin, the Center for Houston’s Future, and Houston Advanced Research Center.

“H2@Scale isn't just about producing low-carbon energy, it's about creating clean energy growth opportunities for communities throughout Texas and the nation,” Adam Walburger, president of Frontier Energy, says in a news release. “By harnessing renewable energy resources to create zero-carbon hydrogen, we can power homes, businesses, transportation, and agriculture – all while creating jobs and reducing emissions.”

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Greentown Labs adds 6 Texas clean energy startups to Houston incubator

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Greentown Labs announced the six startups to join its Houston community in Q2 of 2025.

The companies are among a group of 13 that joined the climatetech incubator, which is co-located in Houston and Boston, in the same time period. The companies that joined the Houston-based lab specialize in a number of clean energy applications, from long-duration energy storage systems to 3D solar towers.

The new Houston members include:

Encore CO2, a Louisiana-based company that converts CO2 into ethanol, acetate, ethylene and other sustainable chemicals through its innovative electrolysis technology
Janta Power, a Dallas-based company with proprietary 3D-solar-tower technology that deploys solar power vertically rather than flatly, increasing power and energy generation
Licube, an Austin-based company focused on sustainable lithium recovery from underutilized sources using its proprietary and patented electrodialysis technology
Newfound Materials, a Houston-based company that has developed a predictive engine for materials R&D
Pix Force, a Houston-based company that develops AI algorithms to inspect substations, transmission lines and photovoltaic plants using drones
Wattsto Energy, a Houston-based manufacturer of a long-duration-energy-storage system with a unique hybrid design that provides fast, safe, sustainable and cost-effective energy storage at the microgrid and grid levels

Seven other companies will join Greentown Boston's incubator. See the full list here.

Greentown Houston also added five startups to its local lab in Q1. Read more about the companies here.

How Planckton Data is building the sustainability label every industry will need

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There’s a reason “carbon footprint” became a buzzword. It sounds like something we should know. Something we should measure. Something that should be printed next to the calorie count on a label.

But unlike calories, a carbon footprint isn’t universal, standardized, or easy to calculate. In fact, for most companies—especially in energy and heavy industry—it’s still a black box.

That’s the problem Planckton Data is solving.

On this episode of the Energy Tech Startups Podcast, Planckton Data co-founders Robin Goswami and Sandeep Roy sit down to explain how they’re turning complex, inconsistent, and often incomplete emissions data into usable insight. Not for PR. Not for green washing. For real operational and regulatory decisions.

And they’re doing it in a way that turns sustainability from a compliance burden into a competitive advantage.

From calories to carbon: The label analogy that actually works

If you’ve ever picked up two snack bars and compared their calorie counts, you’ve made a decision based on transparency. Robin and Sandeep want that same kind of clarity for industrial products.

Whether it’s a shampoo bottle, a plastic feedstock, or a specialty chemical—there’s now consumer and regulatory pressure to know exactly how sustainable a product is. And to report it.

But that’s where the simplicity ends.

Because unlike food labels, carbon labels can’t be standardized across a single factory. They depend on where and how a product was made, what inputs were used, how far it traveled, and what method was used to calculate the data.

Even two otherwise identical chemicals—one sourced from a refinery in Texas and the other in Europe—can carry very different carbon footprints, depending on logistics, local emission factors, and energy sources.

Planckton’s solution is built to handle exactly this level of complexity.

AI that doesn’t just analyze

For most companies, supply chain emissions data is scattered, outdated, and full of gaps.

That’s where Planckton’s use of AI becomes transformative.

It standardizes data from multiple suppliers, geographies, and formats.
It uses probabilistic models to fill in the blanks when suppliers don’t provide details.
It applies industry-specific product category rules (PCRs) and aligns them with evolving global frameworks like ISO standards and GHG Protocol.
It helps companies model decarbonization pathways, not just calculate baselines.

This isn’t generative AI for show. It’s applied machine learning with a purpose: helping large industrial players move from reporting to real action.

And it’s not a side tool. For many of Planckton’s clients, it’s becoming the foundation of their sustainability strategy.

From boardrooms to smokestacks: Where the pressure is coming from

Planckton isn’t just chasing early adopters. They’re helping midstream and upstream industrial suppliers respond to pressure coming from two directions:

Downstream consumer brands—especially in cosmetics, retail, and CPG—are demanding footprint data from every input supplier.
Upstream regulations—especially in Europe—are introducing reporting requirements, carbon taxes, and supply chain disclosure laws.

The team gave a real-world example: a shampoo brand wants to differentiate based on lower emissions. That pressure flows up the value chain to the chemical suppliers. Who, in turn, must track data back to their own suppliers.

It’s a game of carbon traceability—and Planckton helps make it possible.

Why Planckton focused on chemicals first

With backgrounds at Infosys and McKinsey, Robin and Sandeep know how to navigate large-scale digital transformations. They also know that industry specificity matters—especially in sustainability.

So they chose to focus first on the chemicals sector—a space where:

Supply chains are complex and often opaque.
Product formulations are sensitive.
And pressure from cosmetics, packaging, and consumer brands is pushing for measurable, auditable impact data.

It’s a wedge into other verticals like energy, plastics, fertilizers, and industrial manufacturing—but one that’s already showing results.

Carbon accounting needs a financial system

What makes this conversation unique isn’t just the product. It’s the co-founders’ view of the ecosystem.

They see a world where sustainability reporting becomes as robust as financial reporting. Where every company knows its Scope 1, 2, and 3 emissions the way it knows revenue, gross margin, and EBITDA.

But that world doesn’t exist yet. The data infrastructure isn’t there. The standards are still in flux. And the tooling—until recently—was clunky, manual, and impossible to scale.

Planckton is building that infrastructure—starting with the industries that need it most.

Houston as a launchpad (not just a legacy hub)

Though Planckton has global ambitions, its roots in Houston matter.

The city’s legacy in energy and chemicals gives it a unique edge in understanding real-world industrial challenges. And the growing ecosystem around energy transition—investors, incubators, and founders—is helping companies like Planckton move fast.

“We thought we’d have to move to San Francisco,” Robin shares. “But the resources we needed were already here—just waiting to be activated.”

The future of sustainability is measurable—and monetizable

The takeaway from this episode is clear: measuring your carbon footprint isn’t just good PR—it’s increasingly tied to market access, regulatory approval, and bottom-line efficiency.

And the companies that embrace this shift now—using platforms like Planckton—won’t just stay compliant. They’ll gain a competitive edge.

Listen to the full conversation with Planckton Data on the Energy Tech Startups Podcast:

Hosted by Jason Ethier and Nada Ahmed, the Digital Wildcatters’ podcast, Energy Tech Startups, delves into Houston's pivotal role in the energy transition, spotlighting entrepreneurs and industry leaders shaping a low-carbon future.

Gold H2 harvests clean hydrogen from depleted California reservoirs in first field trial

breakthrough trial

Houston climatech company Gold H2 completed its first field trial that demonstrates subsurface bio-stimulated hydrogen production, which leverages microbiology and existing infrastructure to produce clean hydrogen.

Gold H2 is a spinoff of another Houston biotech company, Cemvita.

“When we compare our tech to the rest of the stack, I think we blow the competition out of the water," Prabhdeep Singh Sekhon, CEO of Gold H2 Sekhon previously told Energy Capital.

The project represented the first-of-its-kind application of Gold H2’s proprietary biotechnology, which generates hydrogen from depleted oil reservoirs, eliminating the need for new drilling, electrolysis or energy-intensive surface facilities. The Woodlands-based ChampionX LLC served as the oilfield services provider, and the trial was conducted in an oilfield in California’s San Joaquin Basin.

According to the company, Gold H2’s technology could yield up to 250 billion kilograms of low-carbon hydrogen, which is estimated to provide enough clean power to Los Angeles for over 50 years and avoid roughly 1 billion metric tons of CO2 equivalent.

“This field trial is tangible proof. We’ve taken a climate liability and turned it into a scalable, low-cost hydrogen solution,” Sekhon said in a news release. “It’s a new blueprint for decarbonization, built for speed, affordability, and global impact.”

Highlights of the trial include:

First-ever demonstration of biologically stimulated hydrogen generation at commercial field scale with unprecedented results of 40 percent H2 in the gas stream.
Demonstrated how end-of-life oilfield liabilities can be repurposed into hydrogen-producing assets.
The trial achieved 400,000 ppm of hydrogen in produced gases, which, according to the company,y is an “unprecedented concentration for a huff-and-puff style operation and a strong indicator of just how robust the process can perform under real-world conditions.”
The field trial marked readiness for commercial deployment with targeted hydrogen production costs below $0.50/kg.

“This breakthrough isn’t just a step forward, it’s a leap toward climate impact at scale,” Jillian Evanko, CEO and president at Chart Industries Inc., Gold H2 investor and advisor, added in the release. “By turning depleted oil fields into clean hydrogen generators, Gold H2 has provided a roadmap to produce low-cost, low-carbon energy using the very infrastructure that powered the last century. This changes the game for how the world can decarbonize heavy industry, power grids, and economies, faster and more affordably than we ever thought possible.”

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