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BASF, the world’s largest chemical producer based in Ludwigshafen, Germany, has partnered with ExxonMobil to develop low-emission hydrogen using methane pyrolysis technology. This collaboration aims to accelerate the production of cost-effective, clean hydrogen for industrial use. The companies have signed a joint development agreement and plan to build a demonstration plant in Baytown, Texas, to test the technology at scale.

BASF has been researching methane pyrolysis for several years with funding from Germany’s Federal Ministry of Research, Technology, and Space (BMFTR). By teaming up with ExxonMobil, the companies hope to combine expertise and bring this promising hydrogen solution closer to commercial reality.

BASF methane pyrolysis test facility at Ludwigshafen site

exxonmobil basf
Source: Exxon

Methane Pyrolysis: Fueling a Low-Carbon Future

Methane pyrolysis is a process that splits methane—a major component of natural gas—into hydrogen and solid carbon using electricity. Unlike traditional hydrogen production methods, such as steam-methane reforming (SMR), methane pyrolysis does not produce CO2 during the reaction.

The process uses about five times less energy than water electrolysis and doesn’t require water, making it more efficient in many situations. Methane pyrolysis also benefits from existing natural gas infrastructure, so it can be deployed in multiple locations without major modifications.

Product costs and CO2 footprint of different hydrogen production technologies

methane pyrolysis carbon emissions
Source: Royal Society of Chemistry https://pubs.rsc.org/en/content/articlehtml/2025/ee/d4ee06191h

Key Benefits and Challenges 

Methane pyrolysis can play an important role in the transition to a low-carbon economy. Hydrogen demand is expected to grow across industries, from chemicals and steel to transportation and energy storage. By producing hydrogen without direct CO2 emissions, methane pyrolysis can help industries meet decarbonization targets.

Hydrogen is a critical energy carrier and feedstock for the chemical industry. Solid carbon, the byproduct of methane pyrolysis, is also valuable. It can be used in steel and aluminum production, construction materials, and advanced carbon products like battery components.

Key advantages of methane pyrolysis include:

  • No direct CO2 emissions during hydrogen production.

  • High-purity solid carbon that can be stored or used commercially.

  • Lower energy demand compared to electrolysis.

  • Compatibility with existing natural gas systems makes deployment easier.

However, the technology isn’t completely emissions-free. Upstream methane leaks—from extraction, processing, or transportation—can significantly increase greenhouse gas emissions. Methane has a global warming potential many times higher than CO2, so minimizing leaks is critical for keeping emissions low.

Thus, the process requires careful management of upstream methane leaks to ensure true low emissions. Also, methane supply chains must be monitored and controlled. Additionally, energy inputs must be optimized to maximize efficiency and minimize lifecycle CO2 emissions.

If successfully deployed, this technology could complement renewable-based hydrogen solutions and provide a scalable, industrial-ready pathway to cleaner hydrogen production. The Baytown demonstration plant will provide critical insights into operational efficiency, emissions management, and the commercial viability of methane pyrolysis.

Methane Pyrolysis vs. Other Hydrogen Methods

Energy Efficiency: Methane pyrolysis requires about 37.5 kJ of energy per mole of hydrogen, compared to 63.4 kJ for SMR and 285.8 kJ for water electrolysis. This shows methane pyrolysis is highly energy-efficient.

Lifecycle Emissions: Studies estimate methane pyrolysis produces 9–12 tons of CO2 equivalent per ton of hydrogen, depending on methane management and energy sources. SMR with carbon capture (CCS) has slightly higher emissions, while electrolysis emissions depend entirely on the electricity source. If powered by renewable electricity, electrolysis can achieve near-zero CO2 emissions, but grid electricity with fossil fuels increases emissions.

Full Lifecycle Benefits: Methane pyrolysis may also avoid some emissions linked to manufacturing and resource use for electrolyzers. Its efficiency and carbon byproduct make it a competitive low-carbon solution.

In summary, methane pyrolysis offers a balance between low emissions, energy efficiency, and economic feasibility. It competes well with SMR + CCS and is generally less energy-intensive than full electrolysis, though renewable-powered electrolysis has the lowest emissions if electricity is green.

BASF and Exxon’s Demonstration Plant to Validate Technology

BASF and ExxonMobil plan to build a demonstration plant at ExxonMobil’s Baytown Complex. This facility will produce up to 2,000 tons of low-carbon hydrogen and 6,000 tons of solid carbon annually. The project will validate the technology at scale and prepare it for commercial deployment.

This plant represents a key step toward making methane pyrolysis a practical solution for industrial hydrogen demand. By combining BASF’s chemical expertise with ExxonMobil’s experience in energy infrastructure, the companies aim to accelerate the global adoption of low-emission hydrogen.

A Strategic Leap for Clean Hydrogen Innovation

Moreover, ExxonMobil brings additional strengths to the partnership. The company owns the largest CO2 pipeline network in the U.S. and has extensive experience in fuels, chemicals, and low-carbon solutions. Combining this with BASF’s innovation in chemical processes makes the collaboration a powerful step forward for sustainable hydrogen production.

Overall, this partnership represents a major step in advancing low-emission hydrogen.

IEA predicts that low-emissions hydrogen production is set to grow significantly by 2030. Projects that are already operational or have reached final investment decisions (FID) are expected to produce 4.2 million tons per year (Mtpa) by 2030. It’s a fivefold increase compared with 2024.

IEA Green hydrogen
Source; IEA

Although this is still below the ambitious targets set by governments and industry earlier in the decade, it would raise the share of low-emissions hydrogen from less than 1% today to around 4% of total hydrogen production by 2030.

This growth is similar to the rapid expansion seen in other clean energy technologies, such as solar PV. In addition, a new assessment of announced projects suggests that another 6 million tons of low-emissions hydrogen could become operational by 2030, provided effective policies are in place to support demand and secure offtake agreements.

As industrial hydrogen demand rises and decarbonization becomes urgent, methane pyrolysis is set to play a key role in the energy transition. By combining their expertise, BASF and ExxonMobil are positioning themselves at the forefront of low-emission hydrogen innovation.

The post BASF and ExxonMobil Team Up to Boost Low-Emission Hydrogen with Methane Pyrolysis appeared first on Carbon Credits.

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How to improve Scope 3 data accuracy for CSRD

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For most businesses, the emissions that matter most sit outside their own walls. Scope 3 emissions, everything generated across your value chain, from the suppliers who make your inputs to the customers who use your products, typically make up the majority of a company’s total carbon footprint. Under the Corporate Sustainability Reporting Directive (CSRD), those value-chain emissions now have to be measured and disclosed with a rigour that spend-based estimates alone struggle to satisfy. This guide sets out how to improve Scope 3 data accuracy for CSRD: the calculation methods open to you, how to move from estimates to verified supplier data, and how to govern that data so it holds up to audit.

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How community stewardship makes carbon credits durable

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A carbon credit is a commitment that extends well into the future. The tonne of CO₂ compensated for today from a nature-based carbon project must remain out of the atmosphere for good, which means the forest behind the credit has to remain standing long after the transaction is complete. For any buyer, this raises a defining question: What ensures that the forest endures?

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Why Conventional Carbon Offsets Are Losing Boardroom Credibility

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What replaced the cheap REDD credit on the boardroom slide deck, and why procurement is leading the rewrite.

Three years ago, a corporate slide showing a portfolio of cheap REDD+ credits could carry a board meeting. The number was big, the price was low, and the press release wrote itself. Today, that same slide gets sent back with questions. The questions are uncomfortable, the answers are unclear, and your general counsel is suddenly in the room.

Conventional carbon offsets are not dead. The voluntary carbon market retired 202 million tonnes in 2025, and the Morgan Stanley Institute for Sustainable Investing survey published in January 2026 confirmed that interest from corporate buyers remains substantial. What changed is the credibility threshold. The integrity floor has risen, the disclosure scrutiny has tightened, and the buyer profile has shifted. This article tracks what changed, what sophisticated buyers now ask before signing, and what serious corporates are putting on the board slide instead.

What boards used to buy, and why it stopped working

The 2020 to 2022 model was simple: buy a large tranche of avoidance credits at low single-digit prices, retire them against the company footprint, announce the carbon-neutral claim, and move on. Most of those credits came from REDD+ projects, renewable energy installations in countries where the renewable energy was already economic, or methane projects with thin documentation.

Several things broke that model. Academic research published in 2023, including a widely cited Science paper, found that the majority of REDD+ credits issued under the most common methodologies did not represent additional reductions when tested against rigorous counterfactuals. The Voluntary Carbon Markets Integrity Initiative published its Claims Code of Practice, which sets requirements for what companies can credibly claim from credit use. The European Union finalised its Green Claims Directive, restricting how companies can describe products as climate-neutral. France’s Décret 2022-539 already restricts carbon neutrality advertising. California’s AB 1305 imposes disclosure requirements on any company making net-zero or carbon-neutral claims while doing business in the state.

The collective effect: the cheap credit no longer buys the announcement, and the announcement now carries litigation risk.

The integrity reset: ICVCM, VCMI, and what changed

The Integrity Council for the Voluntary Carbon Market published the Core Carbon Principles in 2023 and began assessing methodologies against them in 2024. The first methodologies received the CCP label later that year. The point of the label is to give corporate buyers a defensible quality screen they can cite in disclosure.

The Voluntary Carbon Markets Integrity Initiative complements this on the demand side. Its Claims Code of Practice defines what a buyer can say (Silver, Gold, or Platinum claims, with associated requirements) based on the quality of credits used and the underlying decarbonisation strategy. Together, CCP and VCMI build a quality stack: CCP on the supply, VCMI on the claim, with the science-based target sitting underneath both.

The reset is not a ban on offsets. It is a ratchet. Credits that meet the new bar continue to clear; credits that do not, do not. The Morgan Stanley survey found that 61% of current buyers like the CCP label concept but that supply of labelled credits remains limited. That supply constraint is now visible in pricing.

What sophisticated buyers ask before they sign

The questions on the procurement scorecard have changed. A 2022 buyer might have asked about price, vintage, and project type. A 2026 buyer asks five different questions before any of those.

  • What does the counterfactual look like, and who validated it.
  • What is the permanence regime, and what is the buffer pool exposure.
  • What is the leakage risk, and how is it mitigated.
  • What rating has the project received from the independent ratings agencies (Sylvera, BeZero, Calyx Global), and what was the rationale.
  • What is the documentation discipline that survives an audit four years from now when the procurement team that signed the contract has moved on.

If the vendor cannot answer those five questions on a first call, the conversation ends. Conversely, if the vendor can answer them with documented specificity, the conversation often expands beyond a single transaction toward a multi-year engagement.

Where this leaves your near-term commitments

You probably have near-term commitments that pre-date the integrity reset. Public targets to be carbon neutral by 2025 or 2030. Product-level claims that ran in last year’s marketing. Disclosed reduction trajectories that assumed continued access to cheap credits.

You have three workable paths. The first is to re-baseline your strategy, replacing the most exposed credits with higher-quality alternatives and adjusting the public language to match what you can defend. The second is to shift the underlying spend from offsetting outside your value chain to investing inside your value chain, where reductions count against Scope 3 directly and the audit trail is cleaner. The third is to keep the strategy and absorb the risk, which is increasingly the most expensive option once you price in litigation, restatement, and reputational exposure.

Most serious buyers are choosing the second path. It moves the carbon spend from a compliance cost to a procurement and resilience investment, and it removes the central failure point of the legacy model: the disconnect between where the emissions occurred and where the reductions sat. Nature-based supply chain investments, structured under the GHG Protocol Land Sector and Removals Standard and aligned to the SBTi FLAG Guidance, are the asset class that fits this brief. They generate inventory-grade reductions, they produce audit-grade documentation, and they survive the new claim restrictions because the carbon math sits inside the value chain that the disclosure already covers.

If you are reassessing a carbon strategy under the new integrity bar, or rebuilding a board narrative that has to survive a more skeptical audience, the carbon and sustainability experts at Carbon Credit Capital can help. The Dual-Value Model gives you a defensible alternative to legacy offset purchases, with the documentation and operational integration that survives the procurement scorecard and the audit. Schedule a consultation.

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