Nvidia AI Tech Ramps Up Carbon Capture & Storage Predictions 700,000x

Nvidia Corporation, a giant tech company that’s a leading supplier of artificial intelligence (AI) hardware and software, unveiled its new approach to carbon capture and storage (CCS) that scientists and engineers can use to accelerate carbon sequestration.

Carbon capture and storage, also called carbon sequestration, is one way to mitigate climate change by redirecting carbon deep underground. During the process, CCS scientists must prevent fracturing geological formations where carbon is injected, leaking CO2 into aquifers, or worse back into the atmosphere. 

That can happen if there’s too much pressure buildup due to the process of injecting carbon into the rock formations. This, and more, is what Nvidia’s Ai-powered technology addresses to help improve carbon sequestration.

Nvidia AI: Ramping Up Carbon Capture Modeling 700,000x  

CCS is one of few methods that industries like oil and gas, cement, and steel can deploy to decarbonize and meet their net zero targets. More than a hundred CCS facilities are under construction worldwide.

Traditional simulators for carbon sequestration are costly to own and require a lot of time to complete. Machine learning and AI models deliver the same level of accuracy but at reduced cost and time. 

Nvidia introduces its AI approach to carbon sequestration that CCS scientists can readily use in real-world applications through Nvidia Modulus and Nvidia Omniverse.

Nvidia’s AI-powered technology accelerates CCS modeling 700,000x using Fourier Neural Operators (FNO) architecture.

Nvidia’s Approach to CCS Modeling

Source: Nvidia website

FNO architecture provides more accurate predictions of pressure buildup and CO2 saturation. It’s 2x as accurate while needing only a third of the training data compared to other computer models. 

As such, the software helps CCS engineers to choose the best injection sites fast, identify the optimal spacing and depth of wells, as well as determine the best injection pressure and rate for the captured carbon. Moreover, engineers can visualize and optimize the entire inspection process through Nvidia Omniverse

With its superior computing abilities, Nvidia software increases the carbon sequestration simulation speed 700,000 times. A robust assessment for CO2 plume and pressure buildup usually takes about 2 years using numerical simulators. But with Nvidia’s FNO, it may take 2.8 seconds only. 

Trained Nvidia FNO models are available in a web application to provide real-time simulations for carbon capture and storage projects. 

Thus, AI technology enables various tasks vital in making CCS decisions.  

Improving Carbon Sequestration

Scientists use carbon storage simulations or modeling to pick the right CO2 injection sites and rates. Modeling also helps them optimize storage efficiency, control pressure buildup, and make sure that rock formations don’t get fractured. 

CCS engineers must also understand how the injected CO2 will spread through the ground, also called a CO2 plume. 

Nvidia technology was found useful by a study to achieve an AI-powered carbon capture and storage with interactivity at scale. Using it, engineers can interact with the models to guarantee the reliability and safety of a CCS project. A safe and accurate CO2 storage process can help reduce the amount of carbon escaping into the air. 

Here’s a video by Nvidia explaining the CCS process and how its AI technology can help accelerate things. 

FNO allows scientists to simulate how pressure levels build up and where CO2 spreads throughout the 30 years of injection. Acceleration using this AI-powered model speeds up the simulation process from ten minutes to just seconds. 

Without this technology, selecting injection sites for CO2 would seem like a shot in the dark.

AI for Net Zero

Achieving net zero emissions by 2050 requires a combination of different scalable technologies such as CCS. 

As per the International Energy Agency (IEA) report, the global planned carbon storage capacity rose by 80% in 2022. For the same year, there’s also a 30% increase in planned carbon capture capacity.

Recent innovations in AI, with models like Nvidia’s FNO, can help ramp up CCS modeling by orders of magnitude. This is crucial in helping CCS technologies scale up.

There are also other AI innovations used in the industry.

For instance, Ohio-based analytics company Aperture launched its Carbon Capture Space last year. It is an AI-powered platform that offers industry analysts and investors insights into 1,000+ technologies for CCS.

Nvidia’s Earth-2, which will be the world’s first AI digital twin supercomputer, will leverage the FNO models. This tech will further show how AI can help speed up the process of mitigating climate change.

The tech company now tops Tesla as AI revolution pushes its shares to record high, up 200%. ESG investors prefer it to other traditional assets, with over 1,400 ESG funds directly holding Nvidia, according to Bloomberg report.

Nvidia and its AI models will help tackle the climate crisis by contributing to global climate change mitigation efforts. Leveraging the AI revolution would be one way for the world to be on its track to net zero.

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North America’s Largest Biochar Plant Announced In Canada

A consortium of Canadian and French companies, including Airex Energy, Groupe Rémabec, and SUEZ, are investing C$80 million to construct North America’s largest biochar production facility.

This initiative highlights the growing global recognition of biochar’s potential in carbon sequestration and soil enhancement.

The plant will be located along the north shore of the Saint Lawrence River in Port-Cartier, Quebec, Canada.

The Quebec Biochar Plant: A Major Step in Canada’s Decarbonization Efforts

The Port-Cartier facility is Canada’s first industrial-scale biochar production plant, marking a significant milestone in the country’s net zero efforts.

The first phase of the plant will be finalized in 2024. It will focus on transforming forestry waste into biochar, contributing to a circular economy, and playing a crucial role in the fight against climate change.

With an initial production capacity of 10,000 tonnes per year, the plant will triple its annual production capacity by 2026. This makes it the largest biochar plant in North America.

The consortium aims to produce 350,000 tonnes of biochar by 2035.

They have identified locations in Europe and Africa where they can access the input to produce biochar, as well as potential buyers.

The Project’s Impact and Plans

The facility, owned by CARBONITY, a joint venture equally owned by the three partners, will employ 75 people locally. It will produce carbon-rich biochar with high environmental qualities from the residual biomass of Groupe Rémabec’s operations.

The project will sequester 75,000 tonnes of carbon per year.

By sequestering carbon, biochar production will generate guaranteed, certified carbon credits. First Climate will then sell them on the voluntary carbon market.

This project became possible thanks to the financial participation of the Quebec and Canadian governments. A federal official commented on this milestone, the Minister of Sport and Minister responsible for CED, said that:

“Government of Canada has made concrete commitments to demonstrate that a strong economy and a healthy environment go hand-in-hand. That is why Canada Economic Development for Quebec Regions (CED) is granting a repayable contribution of $3M to CARBONITY for its set-up project in Port-Cartier.”

Biochar: A Powerful Tool for Carbon Sequestration and Soil Enhancement

Biochar is a charcoal-like substance produced from plant matter. It’s created through a process called pyrolysis, where organic material is heated in a high-temperature, low-oxygen environment.

The result is a stable form of carbon that resists decomposition, effectively locking away carbon that would otherwise return to the atmosphere. When added to soil, biochar can significantly improve soil health, enhancing water retention, nutrient availability, and microbial activity. All these lead to increased crop productivity.

Moreover, the production of biochar can generate Carbon Dioxide Removal (CDR) carbon credits. These credits can be sold or traded, providing an additional revenue stream for biochar producers and incentivizing further carbon sequestration efforts.

Airex earlier this year raised $38M to increase capacity at another Quebec facility that torrefies biomass.

A Shift in the Carbon Credits Market

The construction of the Quebec biochar plant signifies a shift in the carbon credits market. As countries and corporations strive to achieve their carbon neutrality goals, the demand for effective carbon offsetting solutions is growing.

Biochar production offers a tangible, measurable way to offset carbon emissions. The carbon credits generated from this process can attract significant interest from environmentally conscious investors and corporations.

Used as a soil amendment, biochar offers several benefits, including carbon sequestration, increased nutrient retention, and optimized soil aeration and drainage. Its properties allow it to contribute to soil regeneration, limit the use of fertilizers and sustain water resources.

When added to concrete or asphalt formulations, biochar brings new functionalities to the final material while helping to reduce its carbon footprint, a key issue for the construction sector.

Lastly, the production of biochar at high-temperature and with oxygen-free pyrolysis will generate surplus energy in the form of steam or pyrolysis oil, which is reusable on site.

In summary, here are just some of the potential industrial uses of biochar:

Source: Osman et al. (2022). Environ Chem Lett 20. https://doi.org/10.1007/s10311-022-01424-x

The Future of Biochar and Carbon Management

The emergence of North America’s largest biochar plant in Quebec is a milestone in the world’s journey toward sustainable carbon management. It highlights the potential of biochar as a solution for carbon sequestration, waste management, and soil enhancement.

With the establishment of the Port-Cartier facility, the future of biochar and carbon management looks promising. The project shows the potential of biochar in sequestering carbon while setting a precedent for future initiatives in the sector.

As we continue to grapple with the challenges of climate change, such initiatives offer a beacon of hope, showing us that with innovation and commitment, a sustainable future is within our reach.

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Toyota Reveals Solid-State EV Battery with 745-Mile Range, Cuts Emissions by 39%

Toyota reveals its solid-state EV battery technology which claims to have a 745 mile range and 10 minute charging time. Solid-state batteries can reduce the carbon emissions of electric vehicle (EV) batteries by 39%, but it needs 35% more lithium.

The world’s largest carmaker by sales caught the markets by surprise by announcing its plans to commercialize its solid-state battery technology by 2027. 

Toyota’s Next-Gen EV Battery Technology 

Last month, Toyota announced that as the next-generation EV continues to use new batteries, they’re “determined to become a world leader in battery EV energy consumption.”

This week, the Japanese carmaker, which has been lagging behind rivals in rolling out EVs, unveiled its solid-state battery breakthrough. The automaker said that it was able to simplify ways to produce the materials used in making solid-state batteries. 

Toyota further noted that this discovery will enable it to halve the size, cost, and weight of EV batteries. That also means significantly cutting charging times to 10 minutes or less while increasing the driving range to 1,200 kilometers (745 miles). Currently, the luxury brand Lucid Air holds the longest drive range of 516 miles. 

President of Toyota’s R&D center for carbon neutrality, Keiji Kaita, commented that they’re planning to achieve reductions both in their liquid and solid-state batteries. He further said that this new battery will be simpler to make than a conventional lithium-ion battery. 

The car company has been working on this technology since 2012 and it’s becoming a reality as Toyota now have over 1,000 solid-state battery patents – more than any other carmaker.

Noting Toyota’s announcement, analysts remarked that this could be a game-changer for the industry. And it can also help the Japanese carmaker be closer to the leading EV maker Tesla. Most of Tesla’s EV units are powered by conventional lithium-ion batteries using liquid electrolytes. 

Kaita also said they discovered ways to address the durability problems with EV batteries. And that they now are confident to mass-produce solid-state batteries by 2027 or 2028. 

Ford and BWM also tested these batteries late last year.

What are Solid-State Batteries?

Solid-state batteries are considered by industry experts as the most promising technology to fix major EV battery concerns. These particularly include charging time, driving range, capacity, and safety risks like catching fire.

Some experts call solid-state the “kiss of death” for gasoline- and diesel-powered vehicles.

These batteries replace a liquid electrolyte with a solid material and use lithium metal instead of graphite at the anode. Here’s how Toyota’s solid-state battery differs from the current, liquid-based version and how it can change the industry.



Solid-state batteries offer high energy density, meaning they can store more energy with less materials. They also typically require no toxic materials.

More remarkably, research shows that this new technology can help mitigate the climate impact of EV batteries.  

As shown below, batteries made from most sustainably sourced materials can cut carbon emissions further down by 39%. This emission reduction could probably be due to simplified production processes and faster charging times. 

Moreover, more efficient mining methods such as extracting lithium from geothermal wells can also contribute to lower climate impacts. Solid-state batteries may need up to 35% more lithium than the current lithium-ion technology, but they use far less cobalt and graphite. 

Driving Up the Demand for More Lithium 

Lithium, also called white gold, is the unsung hero of the clean energy transition by powering up the EV revolution. Countries and major EV makers are scrambling to secure lithium. If solid-state batteries dominate the industry, demand for this critical mineral will soar up much higher than is currently projected. 

In the European Union, the bloc’s proposed Batteries Regulation for lithium requires responsible sourcing and recycling of the EV element. The EU policy will ensure that there’s enough lithium supply for solid-state batteries. European governments still need to finalize the regulation. 

In the U.S., the Inflation Reduction Act (IRA) incentivizes EV manufacturers that source their batteries locally or from free-trade partners. But the country needs to ramp up its domestic lithium supply to meet the skyrocketing demand. This is where rare lithium companies like the American Lithium Corporation come to the rescue. The company has two of the largest lithium deposits in the Americas.

According to an industry expert, improving the methods used in extracting and processing the raw materials in solid-state batteries, including lithium, is the key to slashing their climate impact

Toyota’s solid-state battery revelation didn’t disclose key details such as battery performance in cold temperatures, energy density, and raw materials. The giant carmaker aims to manufacture 3 million battery-electric units each year by 2030 — 50% with solid-state batteries.

Will Toyota’s battery breakthrough change its course and make it a leader in the EV revolution? That’s what the industry has to watch out for. 

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Indonesia’s Coal Emissions at Record High, Up 33% in 2022

Indonesia’s coal emissions in 2022 hit a record high, as per preliminary analysis, which makes the country one of the biggest emitters of carbon from fossil fuels worldwide. 

The data analyzed was from the Indonesian Ministry of Energy and Mineral Resources (ESDM), showing that coal consumption in the country is highest ever in 2022 than any year. It jumped by 33%, from 559 million barrels of oil equivalent (BOE) in 2021 to 746 BOE in 2022. 

Highest Ever Growth in Coal Emissions 

As seen in the chart, coal has spiked up with a huge margin in comparison to other energy sources. This increase in coal burning also resulted in skyrocketing greenhouse gas emissions from coal and other fossil fuels. 

According to the Global Carbon Project, the organization that calculated CO2e emissions from Indonesia’s fossil fuel burning, the rise in coal caused the Asian country’s GHG emissions to increase massively by more than 20%.

The top 10 biggest carbon emitters haven’t seen this increase in the last fifteen years, says one senior analyst in the organization. 

Increases in oil and gas, plus coal, emissions bring Indonesia’s total fossil fuel CO2 emissions to 619 million metric tons. 

With these increases, Indonesia will be the world’s 6th-highest fossil polluter in 2022, up from the 9th place in 2021. The top 3 spots go to the U.S., Saudi Arabia, and Russia. 

If this trend continues this year, the Southeast Asian nation will hold the 6th spot, for sure. Still, the country’s CO2e footprint per capita (2.7 tonnes) remains lower than that of the United States (15 tonnes). 

Global average for emissions intensity is 7.5 tonnes per capita.

Indonesia is the 3rd-largest coal producer in the world and is a major coal consumer itself. And with new coal plants on the pipeline, the nation’s coal consumption will grow consistently until 2029. 

There’s also not enough intent and action to slow down coal mining in the country, more so decommission the mines. This is amid Indonesia’s commitment to reach net zero emissions by 2060. 

As per ESDM estimates, the country will produce more coal in 2023, at 694 million tonnes. That’s a 5% increase from the 2022 target of 663 million tonnes. This projection is largely due to the expected high demand from India and China, the country’s major coal export partners. 

Indonesia’s 2022 coal sales to Europe also reached historical highs. This is largely due to a shift to coal among European utilities prompted by high gas prices. The EU embargo on Russian coal because of its conflict with Ukraine enabled Indonesian suppliers to tap the European market. 

Is the Energy Transition Still Possible?

With the growing coal production and its carbon emissions, will Indonesia be able to still reach its energy transition targets?

The answer to this question is crucial as experts said that it significantly impacts the 1.5°C global temperatures threshold. After all, the Southeast Asian largest economy is one of the world’s largest emitters.

The country inked a landmark deal last year called the Just Energy Transition Partnership (JETP) in which developed nations (G7) will invest $20 billion in Indonesia to help it ramp up transition to renewable energy. 

This historic agreement will allow the country to limit power sector sectors to 29 million Mt by 2030. But this will be possible if Indonesian coal-fired power plants are retired and new projects are frozen. 

Adding more coal plants is part of President Joko Widodo’s flagship program to add 35 gigawatts to Indonesia’s national grid. The program calls for building hundreds of different kinds of power plants but most of the increase in capacity will be from coal-fired plants. 

One more major factor driving coal production up is the growing demand in the metals industry, particularly the nickel sector.

Complementing the Soaring Demand for Lithium-Ion Batteries

Indonesia is the world’s largest producer of nickel, a key element used in making lithium-ion batteries for electric vehicles and renewable energy storage.

The current administration wants to make the country an EV powerhouse. That means relying on Indonesia’s abundant nickel reserves, whose production also increased by 60% last year. 

Given that the nation’s power grid is largely run by coal (43%) and mining nickel is highly carbon intensive, it contributes largely to the rise in coal production and emissions. 

Moreover, the carbon per KwH of power generation in Indonesia is so much more than most other nickel producers. For example, comparing it to Canada, the Asian country will produce about 9x as much carbon per KwH of electricity.

Processing nickel requires smelters which are powered by coal-fired electricity plants, a.k.a. captive plants. New smelters were built in 2017 and started operations in 2019.

Unfortunately, retiring or replacing these plants are difficult; it needs investments in new infrastructure. And shutting them down means halting the smelters critical for processing battery-grade nickel. 

With that, it seems that Indonesia’s best hope to achieve its climate targets in the power sector is to stop building new fossil fuel plants and rather invest in renewable energy infrastructure. 

Last month, a group of global experts, Coal to Clean Credit Initiative (CCCI), announced they are developing a world-first “coal-to-clean” carbon credit program that incentivizes the transition away from coal-fired power plants to renewable energy in emerging economies.

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UAE to Invest $54B in Renewable Energy as Part of Net Zero Goal

The United Arab Emirates (UAE) is planning to invest $54 billion on renewables over the next 7 years as part of its strategies to reach net zero emissions by 2050. 

The UAE approved its National Energy Strategy with the aim to triple its share of energy coming from renewable sources. The Middle Eastern country also sets its eyes on hydrogen as a key source of clean energy. 

This plan comes as the major oil-producing nation will host the upcoming COP28 climate conference in November. 

UAE National Energy Strategy

Same with other major oil producers, fossil fuels still outweigh the push for a cleaner energy system globally. And the UAE received huge scrutiny from various climate activists for choosing Sultan al-Jaber, ADNOC head, to lead COP28.

Yet, the country was the first to reveal its 2050 zero goal in the region. Big part of the target is approving the country’s National Energy Strategy 2050

Prime Minister Sheikh Mohammed appointed Mohamed Hassan Alsuwaidi, Abu Dhabi wealth fund CEO and Masdar’s deputy chairman, to oversee the $54 billion investment. 

Apart from relying more on renewables, other plans are to improve energy efficiency and promote the use of clean energy. 

The strategy’s objective is to support research and development programs in clean energy technologies, on top of driving investments in the sector. Specifically, the UAE hopes to achieve 14GW capacity of clean energy by 2030, up from 9.2GW current capacity. 

Moreover, the strategy’s objective is to gain up to $27 billion financial savings by 2030. Overall, it targets an energy mix combining different sources of clean energy to satisfy these energy goals: 

44% clean energy
38% gas
12% clean coal
6% nuclear

In the near-term, the Arabic nation seeks to increase its share of clean energy to 30% by 2031. In the long-term, it hopes to cut carbon emissions from power generation by 70% by 2050. 

At a glance, here’s the UAE’s energy strategy to reach net zero emissions by midcentury.

Last year, the Arab country inked a $100 billion clean energy deal with the U.S. Their PACE (Partnership for Accelerating Clean Energy) agreement will deploy 100GW of clean energy in the two countries as well as in emerging economies by 2035. Earlier this year, the partners announced a $20 billion investment to fund 15 GW of clean and renewable energy projects.

The UAE’s oil and gas giant had also committed $15 billion to invest in low-carbon projects to cut emissions and meet decarbonization goals.

Along its national energy strategy, the UAE Cabinet has also approved its National Hydrogen Strategy.

“Top 10” Hydrogen Producer 

The country’s hydrogen strategy seeks to make the UAE part of a global “top 10” hydrogen (H2) producer by 2031. This strategy builds on the previous roadmap unveiled during the COP26 climate talks in 2021. 

The goal is to produce 14 million to 22 million tons per year of hydrogen by 2050. Highlighting this plan, Sheikh Mohammed remarked:

“The strategy aims to promote the UAE’s position as a producer and exporter of low-emission hydrogen over the next eight years through the development of supply chains, the establishment of hydrogen oases and a national research and development centre.”

The government expects to get 25% market share of low carbon hydrogen and derivatives in major import markets by 2030. It will initially focus on Europe, India, Japan, and South Korea, while also exploring export opportunities in other markets. 

To date, the Abu Dhabi nation is well on its way for low carbon hydrogen development with more than 7 projects planned to deliver 0.5 million tons per year. The details of each project are as follows:

The country’s ambition is to be a global leader in low carbon hydrogen and home to a robust hydrogen ecosystem. Low carbon hydrogen refers to H2 made with low carbon emissions pertaining to either of these two hydrogen technologies: 

Blue hydrogen from fossil fuels with carbon capture and storage 
Green hydrogen made through electrolyzer powered by renewable energy 

Hydrogen is the key enabler in UAE’s net zero strategy and here’s the timeline for making this goal a reality. 

Ultimately, the UAE government will invest over $163 billion by 2050 to meet the rising energy demand and ensure a sustainable growth for its economy.

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Navigating the Path to Net Zero: VCMI’s Claims Code of Practice

The Voluntary Carbon Market Integrity Initiative (VCMI) launched its Claims Code of Practice which aims to give companies a rulebook to follow for making credible climate claims using carbon credits on their path to net zero. 

VCMI first published the draft of the Claims Code in June last year. Since then, it went through beta testing by companies and rigorous consultations, and multi-stakeholder collaboration. 

A wide range of nonprofits, international organizations, companies, governments, and industry groups supported VCMI. Climate experts worldwide find the Code a welcome step forward for the VCM after it receives massive criticism. 

VCMI’s Claims Code promotes the use of the “contribution claims” model in financing climate actions through carbon credits. This approach builds market integrity and confidence in VCM as asserted by Rachel Kyte, Co-Chair of VCMI’s Steering Committee saying:

“Voluntary carbon markets bring considerable benefits as part of companies’ net-zero transition and as a means of financing climate transition worldwide… The Claims Code will give greater confidence and develop trust in those who use it. If you build integrity, trust will follow, and trust is the foundation of a high value, high impact market.”

The Code’s 3 Tiers of Corporate Claims

From the provisional bronze, silver, and gold, the final claim tiers or levels are now Silver, Gold, and Platinum. Each of them acknowledges investment in emission reductions and removals beyond corporate action to reach their net zero goals. 

Not all that glitters is gold because Platinum, not Gold, is the best available level for companies to claim. 

The chart shows the respective thresholds for each tier, representing the number of carbon credits retired (carbon emission reductions claimed). This is proportional to the remaining emissions in the year when a company makes a claim. Remaining emissions are emissions that remain in a given year as a company progresses towards its near and long-term targets.

VMCI will provide further guidance on this, particularly on the Measurement, Reporting, and Assurance (MRA) framework, additional claim tiers and claim names, in November 2023.

Making a VCMI Claim

To make a VCMI Claim, a company should go through these four steps:

Comply with VCMI’s Foundational Criteria
Choose which VCMI Claim to make from the 3 tiers
Buy carbon credits that meet quality thresholds – ICVCM’s Core Carbon Principles (CCP)
Disclose information and get 3rd-party assurance following the VCMI MRA Framework

In finalizing the Claims Code, the VCMI has been working with other major initiatives that drive corporate climate action. These include the Greenhouse Gas Protocol, the Integrity Council for the Voluntary Carbon Markets (ICVCM), Science Based Targets Initiative (SBTi), and Carbon Disclosure Project (CDP). 

A Code for High-Integrity Carbon Credit Market

When used with integrity, VCMs can accelerate climate mitigation and contribute significantly to the Paris Agreement goals and UN SDGs.

Thousands of companies are investing in the VCM to tackle their carbon emissions through high-quality carbon credits. Thus, it’s critical that the market has clear and transparent guidance on how to make voluntary use of carbon credits as part of their climate goals. 

VCMI Claims Code provides that guidance and more to prevent abusive use of carbon credits, e.g. greenwashing. It will bring integrity to the VCM and make it a powerful tool to get the world to net zero.

Allister Furey, CEO and co-founder of Sylvera commented on the launch of the Claims Code:

“The VCMI’s guidance is a solid step forward for resolving confusion and uncertainty around what claims companies can make about their climate action, and for overall climate action transparency with the inclusion of comprehensive requirements to disclose credit use.” 

The publication of this code of practice is indeed crucial in helping companies channel climate finance to credible climate action. But others also said that much more still needs to be done and carbon credits are not a silver bullet. There are other ways to invest in climate action.

Yet, the Code is a good starting point for entities looking to voluntarily use carbon credits toward their climate goals. By using it, companies can demonstrate their climate leadership, address reputation risks, and be ready to position themselves in a low-carbon transition.  

Ultimately, when paired with ICVCM’s Core Carbon Principles that guide the supply side of the market, VCMI’s Claims Code of Practice brings “end-to-end” integrity that allows for critical market development.

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