How carbon capture works and the debate about whether it's a future climate solution - The Times of India

Power plants and industrial facilities that emit carbon dioxide, the primary driver of global warming, are hopeful that Congress will keep tax credits for capturing the gas and storing it deep underground. The process, called carbon capture and sequestration, is seen by many as an important way to reduce pollution during a transition to renewable energy. But it faces criticism from some…

The global Direct Air Capture Market is expected to grow from an estimated USD 62 million in 2023 to USD 1,727 million by 2030, at a CAGR of 60.9% during the 2023–2030 period according to a new report by MarketsandMarkets™. 

#Carbon Chicken Project Revolutionizing Agriculture: Carbon Farming and ...

Eco-Profitability: Leveraging Carbon Capture Tech for Sustainable Business in Climate Trade

Weather change is a disaster that demands instant movement. The discharge of greenhouse gases, such as carbon dioxide (CO2), substantially contributes to this issue. To efficiently lower and cut out these emissions, it is indispensable to discover answers. 

One promising method is carbon sequestration technology, which involves capturing CO2 emissions from assets and either storing them underground or making use of them for functions.

This article examines the role of carbon capture technology in preventing climate change and its ability to change our destiny.

Grasp Carbon Seize Generation

The carbon capture era, also called carbon capture and storage (CCS), includes a procedure in which CO2 emissions from strong plants, industrial facilities and other sources are captured before they are launched into the atmosphere.

Find more information here about how to trap carbon from the air and bury it in bales beneath the earth to help us cut emissions and improve the environment.

The captured CO2 is eventually stored underground inside formations like depleted oil and gasoline fields or deep saline aquifers. This prevents the CO2 from reaching the surroundings and exacerbating weather exchange.

The Importance of Carbon capture generation

Carbon capture technology holds significance in addressing climate change due to the following motives; 

1. Increasing greenhouse gas emissions entails the use of carbon capture, which helps in taking pictures and storing carbon dioxide (CO2) emissions from resources like energy, plant life, factories and without delay from the air.

This technology prevents the discharge of these gases into the atmosphere, thereby decreasing emissions and preventing climate change.

Another method to cope with this problem is to transition to energy resources. Carbon shooting era allows us to maintain the use of fuels along with coal and herbal fuel even as minimizing their effect.

It captures the CO2 emissions launched in the course of their combustion procedure, allowing a shift toward stronger sources like renewables.

This serves as a solution until renewable energy becomes more reachable and cost effective.

Emerging situations and barriers

At the same time as carbon taking technology showcases capability, in addressing climate change there are challenges and barriers that need attention.

1. Value: In modern times, imposing and running carbon taking technology comes with a price tag. The fees associated with taking pictures, transporting and storing carbon dioxide make it economically challenging for adoption.

Further research efforts are necessary to reduce the expenses related to this technology.

2. Scalability: It is an element with regards to carbon taking picture centers. Currently, those facilities face obstacles in terms of scale. To truly make an impact on decreasing greenhouse gas emissions, we need to install large scale carbon shooting centers. 

However, it is vital to note that the infrastructure required for capturing and storing quantities of carbon dioxide remains in its early stages of development.

Scaling up this technology is a challenge that calls for planning and execution.

One of the foremost ventures within the process is locating locations for storing the captured carbon dioxide.

Underground storage sites like depleted oil and gas reservoirs or deep saline aquifers were diagnosed as preferences. 

Power intake is another thing to consider in carbon capture operations. The system itself calls for an amount of strength that can cause greenhouse gas emissions if sourced from fossil fuels.

To deal with this problem, it becomes necessary to explore energy methods or make use of power assets at some point in the carbon sequestration method. 

This way, we will avoid developing a technique that is both carbon neutral and has an impact on decreasing emissions.

The Destiny of Carbon capture technology

No matter the limitations it faces, carbon sequestration and generation keep momentum going as a solution for addressing climate change. Ongoing efforts are targeted at improving its performance and effectiveness through research and improvement initiatives. 

Scientists and engineers are continuously exploring strategies to seize and save carbon dioxide emissions from the dissipation of assets, including power plants, business centers and, without delay, from the atmosphere.

The final goal is to lessen the discharge of CO2 into the ecosystem, which considerably contributes to warming.

One of the technologies for carbon capture is known as carbon capture and storage (CCS).

This method involves taking pictures of CO2 emissions from electricity plants and industrial centers before they are released into the environment.

The captured CO2 is stored underground in geological formations or utilized for different purposes. CCS has the capability of reducing greenhouse gas emissions and combating climate change.

Every other big venture lies in finding garage web sites for captured CO2. figuring out formations for storing the captured carbon dioxide can be a complicated and time process. 

Regardless of the hurdles, progress in carbon capture and generation is lead-off at a tempo. Governments, industries and groups worldwide are acknowledging the importance of reducing greenhouse gas emissions. Are closely investing in the research and development of carbon capture technologies. This aid facilitates innovation. Expediting the implementation of carbon capture tasks

In conclusion 

Carbon capture and generation give an answer to addressing climate change by curbing CO2 emissions and helping the transition towards a low carbon financial system. even though there are challenges and limitations to ongoing study efforts, coupled with policy help, advancements in this subject are propelling its large adoption. 

As we persistently tackle weather trade issues, carbon capture and generation will play a role, in mitigating their impacts and paving the way for a sustainable destiny.

Author Bio: Techy Trends is a leading tech blogger with a passion for exploring the latest innovations. With a knack for simplifying complex tech topics, they keep readers informed and engaged. Follow for the latest trends in the ever-evolving tech world.

Carbon Capture and Sequestration (CCS) Market Insights Includes Dynamics Key Players, Demand, Products, and Application 2017 – 2032

Overview of the Carbon Capture and Sequestration (CCS) Market:

The carbon capture and sequestration (CCS) market involves technologies and processes aimed at capturing carbon dioxide (CO2) emissions from industrial and energy-related sources, transporting it, and securely storing it underground or utilizing it in other applications. CCS is a key strategy in mitigating greenhouse gas emissions and addressing climate change by reducing CO2 emissions from fossil fuel-based power plants, industrial facilities, and other high-emitting sources.

Global Carbon Capture and Sequestration Market is valued at USD 2.1 Billion in 2022 and is projected to reach a value of USD 7.49 Billion by 2030 at a CAGR (Compound Annual Growth Rate) of 19.9% over the forecast period 2023-2030.

Key Factors Driving the Carbon Capture and Sequestration (CCS) Market:

Climate Change Mitigation: CCS plays a crucial role in mitigating climate change by capturing and storing CO2 emissions from major industrial and energy-related sources. As governments, organizations, and industries commit to reducing greenhouse gas emissions, CCS offers a viable solution for decarbonizing high-emitting sectors.

Policy and Regulatory Support: Government policies and regulations that incentivize or mandate the reduction of CO2 emissions provide a significant driver for the CCS market. Financial support, tax incentives, carbon pricing mechanisms, and emissions reduction targets create a favorable environment for CCS deployment and investment.

Energy Transition and Fossil Fuel Use: CCS technology enables the continued use of fossil fuels while reducing their carbon footprint. As the world transitions to cleaner energy sources, CCS can play a vital role in mitigating emissions from fossil fuel power plants and industrial processes during the transition period.

Industrial Emissions Reduction: Industries such as cement production, steel manufacturing, and chemical processing contribute to a significant share of global CO2 emissions. CCS can help these industries reduce their emissions by capturing and storing CO2 generated during their production processes.

Enhanced Oil Recovery (EOR): CCS can be coupled with enhanced oil recovery techniques, where the captured CO2 is injected into oil reservoirs to extract additional oil. The revenue generated from EOR can provide economic incentives for implementing CCS projects.

Here's an overview of the demand and scope of the CCS market:

Demand:

Climate Change Mitigation: The primary driver of CCS demand is the urgent need to reduce carbon dioxide (CO2) emissions and limit global warming. CCS offers a way to capture CO2 emissions from industrial processes and power plants before they are released into the atmosphere.

Regulatory Pressures: Governments and international organizations are implementing stricter emissions reduction targets. CCS can help industries comply with these regulations and avoid penalties.

Emission-Intensive Sectors: Industries such as power generation, cement production, steel manufacturing, and oil and gas extraction are major sources of CO2 emissions. These sectors have a high demand for CCS technologies to lower their carbon footprint.

Transition to Clean Energy: As renewable energy sources like wind and solar power grow, CCS can complement these efforts by capturing emissions from intermittent renewable sources and providing a stable source of low-carbon energy.

Scope:

Carbon Capture Technologies: CCS involves capturing CO2 emissions from various sources such as power plants, industrial facilities, and even directly from the air. Different capture technologies, such as post-combustion capture, pre-combustion capture, and oxyfuel combustion, offer diverse solutions for different industries.

Transport and Storage: Once captured, the CO2 needs to be transported and stored safely. This involves building pipelines to transport CO2 to storage sites, often deep underground in geological formations like depleted oil and gas reservoirs or saline aquifers.

Enhanced Oil Recovery (EOR): Some CCS projects leverage the CO2 for enhanced oil recovery, a process where injected CO2 helps extract more oil from depleted wells while simultaneously storing the CO2 underground.

Policy and Incentives: Governments and organizations are providing financial incentives, subsidies, and grants to support CCS projects as part of their climate change mitigation strategies. The scope includes policy frameworks and regulatory mechanisms to encourage CCS adoption.

Research and Innovation: Ongoing research aims to improve the efficiency and affordability of CCS technologies. Innovations in materials, capture processes, and storage techniques expand the scope of CCS applications.

Global Cooperation: CCS requires international cooperation due to its potential for cross-border carbon transport and storage. Collaborative efforts between countries can enhance the effectiveness of CCS projects.

Public Perception and Education: Part of the scope involves raising awareness about CCS, addressing public concerns, and building public support for these technologies as a crucial tool in the fight against climate change.

We recommend referring our Stringent datalytics firm, industry publications, and websites that specialize in providing market reports. These sources often offer comprehensive analysis, market trends, growth forecasts, competitive landscape, and other valuable insights into this market.

By visiting our website or contacting us directly, you can explore the availability of specific reports related to this market. These reports often require a purchase or subscription, but we provide comprehensive and in-depth information that can be valuable for businesses, investors, and individuals interested in this market.

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Market Segmentations:

Global Carbon Capture and Sequestration (CCS) Market: By Company

• Siemens

• Aker Solutions

• Fluor

• Mitsubishi Heavy Industries

• Halliburton

• Honeywell International

• Shell Global

• Maersk Oil

Global Carbon Capture and Sequestration (CCS) Market: By Type

• Carbon Capture

• Carbon Sequestration

Global Carbon Capture and Sequestration (CCS) Market: By Application

• Energy

• Industrial

• Agricultural

• Others

Global Carbon Capture and Sequestration (CCS) Market: Regional Analysis

The regional analysis of the global Carbon Capture and Sequestration (CCS) market provides insights into the market's performance across different regions of the world. The analysis is based on recent and future trends and includes market forecast for the prediction period. The countries covered in the regional analysis of the Carbon Capture and Sequestration (CCS) market report are as follows:

North America: The North America region includes the U.S., Canada, and Mexico. The U.S. is the largest market for Carbon Capture and Sequestration (CCS) in this region, followed by Canada and Mexico. The market growth in this region is primarily driven by the presence of key market players and the increasing demand for the product.

Europe: The Europe region includes Germany, France, U.K., Russia, Italy, Spain, Turkey, Netherlands, Switzerland, Belgium, and Rest of Europe. Germany is the largest market for Carbon Capture and Sequestration (CCS) in this region, followed by the U.K. and France. The market growth in this region is driven by the increasing demand for the product in the automotive and aerospace sectors.

Asia-Pacific: The Asia-Pacific region includes Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, China, Japan, India, South Korea, and Rest of Asia-Pacific. China is the largest market for Carbon Capture and Sequestration (CCS) in this region, followed by Japan and India. The market growth in this region is driven by the increasing adoption of the product in various end-use industries, such as automotive, aerospace, and construction.

Middle East and Africa: The Middle East and Africa region includes Saudi Arabia, U.A.E, South Africa, Egypt, Israel, and Rest of Middle East and Africa. The market growth in this region is driven by the increasing demand for the product in the aerospace and defense sectors.

South America: The South America region includes Argentina, Brazil, and Rest of South America. Brazil is the largest market for Carbon Capture and Sequestration (CCS) in this region, followed by Argentina. The market growth in this region is primarily driven by the increasing demand for the product in the automotive sector.

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Tribbles can reproduce explosively from small amounts of food

Tribbles are, presumably, carbon-based life forms

In order to produce this much biomass, far in excess of the matter they consume, they must be pulling some of that carbon from the air

Anyway I’m off to go develop a tribble-based technology for carbon sequestration. There’s no way this could possibly-

Often, the dominant image of natural carbon sequestration is a vast forest canopy, but while reforestation is vital, it is not the most stable long-term carbon sink. Carbon stored in trees is vulnerable: wildfires release carbon as CO₂, and storms cause fallen trees to decompose, feeding microbes that respire carbon back into the atmosphere. To build resilient carbon sequestration systems, we must expand our focus to other ecosystems—such as grasslands sustained by herd animals.

The Role of Herd Animals in Grassland Ecosystems

Restoring and expanding grasslands means dedicating more land to herd animals like bison (North America), wildebeest and antelope (African savannas), reindeer and caribou (Arctic tundra), and elephants (Africa and parts of Asia). Trophic rewilding reestablishes the intricate food webs that sustain these ecosystems. Through grazing, trampling, and nutrient cycling, herd animals regenerate grasslands, making them powerful carbon sinks.

Unlike forests, where carbon is stored in above-ground biomass, grasslands primarily store carbon underground. Their deep-rooted perennial grasses sequester carbon in subsoil and humus, a highly stable form of organic matter that can last centuries or millennia. While tree roots also store carbon, they eventually decompose upon deforestation, releasing CO₂. Conversely, grasslands continuously build soil carbon through root growth and turnover, making them a more enduring carbon sink.

How grazing enhances soil carbon storage

Grazing by herd animals facilitates long-term carbon storage in several ways:

Increased Root Turnover – When grasses are grazed, they shed fine roots, which decay and contribute to humus formation, locking carbon into the soil.

Boosted Microbial and Fungal Activity – Manure, dead roots, and trampled plant material provide organic inputs that fuel microbes, which convert carbon into stable soil compounds.

Stabilized Carbon in Soil Aggregates – Organic matter binds with soil minerals, forming stable aggregates that slow decomposition and protect stored carbon from being released.

Excerpt from this story from Politico:

Interior Secretary nominee North Dakota Gov. Doug Burgumtestified at his confirmation hearing on Thursday that the United States must invest in “clean coal” to support the growth of an artificial intelligence industry.

Burgum said he would help develop resources like coal and natural gas from federal lands to provide more baseload power that data centers require for round-the-clock operations. He alluded to technologies like carbon capture and sequestration to reduce the climate effects of those fossil fuels while providing power for AI.

“This is part of a larger crisis our nation is facing around electricity. We have a shortage of electricity, and especially we have a shortage of baseload,” Burgum told the Senate Energy and Natural Resources Committee. “Without baseload, we're going to lose the AI arms race to China. And if we lose the AI arms race to China, then that's got direct impacts on our national security in the future of this country.”

President-elect Donald Trump has vowed to position the U.S. as an AI leader, which he has said would require new energy sources, including from fossil fuels. Analyses have forecast AI and data centers will drive up electricity consumption in the U.S. after years of flat demand.

Coal is the most carbon-intensive fuel in the power grid, but proponents of carbon capture say that technology can mitigate its planet-warming effects. But the technology is nascent and has not been applied at broad scale in the power sector with government subsidies. Burgum has viewed the technology as promising, as he relied on it to set a goal for North Dakota to become carbon neutral by 2030.

Burgum said the current federal incentives were "out of whack" in providing disproportionate support for renewable power sources that don't provide round-the-clock power.

"We are creating roadblocks for people that want to do baseload and we’ve got massive tax incentives for people who want to do intermittent and unreliable," he said.

we have CO2 sequestration machines that exist right now that can each pump 1 million tons of CO2 from the atmosphere into the ground per year, and this still only mitigates 15 minutes worth of global yearly emissions

you could build one of these machines every day for a whole year, putting away 365 million tons of carbon per year, and it would reverse less than 4 days worth of global yearly emissions

if you kept building one machine every day without stopping, it would take 93 years to reach the number of machines needed to zero out the amount of CO2 we currently produce in 2023

we should not feel comforted by companies planting trees or paying to offset their carbon with new shiny technology when the plain reality is that they need to stop fucking producing so much of it

A research team led by Associate Professor Ding PAN from the Department of Physics and the Department of Chemistry at the Hong Kong University of Science and Technology (HKUST), in collaboration with Prof. Yuan Yao from the Department of Mathematics, has made significant discoveries regarding the complex reaction mechanisms of carbon dioxide (CO2) in supercritical water. These findings are crucial for understanding the molecular mechanisms of CO2 mineralization and sequestration in nature and engineering, as well as the deep carbon cycle within the Earth's interior. This understanding will help pave the way for new directions in future carbon sequestration technologies. The study was published in the Proceedings of the National Academy of Sciences (PNAS)*.

Read more.

The U.S. Department of Agriculture (USDA) National Institute of Food and Agriculture (NIFA) announced today an investment of $70 million in seven creative and visionary agricultural projects to transform the U.S. food and agricultural system and sustainably increase agricultural production in ways that also reduce its environmental footprint.

This Fiscal Year 2023 investment is part of the Sustainable Agricultural Systems program area of NIFA’s Agriculture and Food Research Initiative, the nation’s leading and largest competitive grants program for agricultural sciences.

The innovative program focuses on a broad range of needed research, education and Extension solutions – from addressing agricultural workforce challenges and promoting land stewardship to addressing climate change impacts in agriculture and filling critical needs in food and nutrition.

“Agriculture is facing a multitude of complex challenges,” said Dr. Chavonda Jacobs-Young, USDA Chief Scientist and Under Secretary for Research, Education and Economics. “We need all hands on deck developing creative, sustainable and strategic ways to feed, clothe and fuel future generations.”

The $10 million awards are for coordinated agricultural projects (CAPs), which are larger-scale and longer-term investments that integrate research, education and Extension efforts. These projects promote collaboration, open communication, information exchange and reduce duplication efforts by coordinating activities among individuals, institutions, states and regions.

“These research investments support exciting projects that integrate innovative systems-based thinking, methods and technologies to establish robust, resilient, and climate-smart food and agricultural systems,” said NIFA Director Dr. Manjit Misra. “These visionary projects will improve the local and regional supply of affordable, safe, nutritious and accessible food and agricultural products, while fostering economic development and rural prosperity in America.”

Explore the seven projects, which include the following:

At the University of Wisconsin-Madison, Dr. Erin Silva is leading a collaboration with the Great Lakes Intertribal Food Coalition, the Wisconsin Tribal Conservation Advisory Council, and the Menominee Nation on a transdisciplinary project that aims to scale up traditional Indigenous food production practices — practices that for generations have already been climate-smart and sustainable — by expanding production, processing, storage, and distribution systems, as well as education and Extension programs, that are needed to support integrated crop-livestock systems, cover crops, and rotationally-grazed cattle and pastured chickens.

At the University of Maine, Dr. Hemant Pendse is leading an integrated research, education and Extension effort to advance the bioeconomy by developing biorefinery technologies that will make the millions of tons of available low-grade woody biomass – which currently has a very limited market – more commercially viable in both the sustainable aviation fuel and fish feed sectors.

At Texas A&M AgriLife Research, Dr. Muthu Bagavathiannan is leading a project that seeks to transform cotton production in the southern United States into a more sustainable, climate-smart enterprise by applying improved precision management practices to increase carbon sequestration and reduce greenhouse gas emissions; enhance pest control, and nutrient and water management; and address labor challenges while creating new market opportunities.

AFRI, which also makes grants in the Foundational and Applied Sciences and Education and Workforce Development program areas, is designed to improve plant and animal production and sustainability, and human and environmental health. Grants are available to eligible colleges, universities, and other research organizations.

Do you think there’s any hope to save the planet? Like, whatsoever? Or are things just totally fucked forever? I’ve seen a lot of professionals (citation needed) saying everything is irreversibly fucked forever and we’re doomed

Not only there is hope, but things have changed in positive directions lately.

If you're concerned about climate change, recall that the initial expectations for climate change, during the Paris Agreement, with no intervention at all, were an increse of 4°C by 2100. This would have been virtually a collapse event for human civilization, as this would have meant catastrophic crop failures, violent changes in climate, deadly heatwaves, and more.

That is not the scenario we're heading towards to, however, because that is the scenario without any interventions at all, that is, the "business as usual, we keep burning coal" scenario. We no longer live in that sccenario at all. Coal plants have closed at a fast pace, while renewables are cheaper than ever in history. Virtually all of India's new electricity production, to give one example, are renewables, while China is thoughening, if inconsistently, its carbon zero targets, but renewable energy is so cheap that it does not make sense to invest in fossil fuels anymore. Current actions point to 2.7°C increase, but this means CURRENT actions. Further pledges reduce that to 2.1°C. Future technologies such as carbon sequestration, as well as the ol' reliable "planting trees" might even reverse climate change in the future. These are things that are happening right now.

If you're concerned about ecosystem degradation, ecosystems can recover VERY quickly when just left alone to recover. True, ecological succession is slow to recover biodiversity rich areas, but without human pressure, habitats recover surprisingly quickly. Animals are quicker to reproduce than humans in general, and while you do need to give a push, reintroducing species and rebuilding original vegetation cover, once that's done, the biomes that were there originally spread again. The key factor is how to do that while having a good relationship with the people who live in those areas. Coordination with native peoples and rural communities is key here.

If you're asking about the more political side of things, I subscribe to a historical materialist view of things. For me, the fall of capitalism is inevitable once states serve the working class. This will happen, eventually, because of the contradictions of capitalism and organized popular struggle (by many ways, not just one). I don't believe in the end of history. Capitalism will be only a phase in human history, and perhaps not even a long-lived one.