Market Overview
The Europe plasma gasification market size was worth US$ XX million in 2022 and is estimated to reach US$ XX million by 2029, growing at a CAGR of 10.7% during the forecast period (2022-2029).
The "fourth state of matter," often known as plasma, is a very hot, highly ionized (electrically charged) and current-conducting gas. Natural plasma examples include lightning and the gas on the sun’s surface. Plasma technology has a long development history and is a vital tool for engineers and scientists who need to use very high temperatures for novel process applications.
Artificial plasma is created by running an electrical discharge through a gas, such as air or oxygen (O2). The gas is split into electrons and ions due to its contact with the electric arc, which also raises the temperature of the gas to levels that are frequently higher than 6,000?C or almost as hot as the sun’s surface. Plasma is used in plasma gasification, an extremely hot thermal process that turns organic material into syngas (synthesis gas), primarily consisting of hydrogen and carbon monoxide.

Market Dynamics
Increased demand for clean and efficient energy generation technology and the adoption of waste-to-energy facilities internationally fuels the expansion of the Europe plasma gasification market. However, the hefty initial investment and the need for particular feedstock may restrain market expansion.
Growing demand for clean and efficient energy generation technology
The power generation sector has been driven to use clean and environmentally friendly energy sources by growing concerns and increasing environmental protection rules globally. Additionally, many regions with strong economies are concentrating on building their renewable energy capabilities to lessen their reliance on conventional power generation, which drives the market share for sustainable technology.
Electricity is produced using clean energy, which doesn’t harm the environment by emitting greenhouse gases like carbon dioxide. One such technology that provides a more effective means of eliminating waste feedstock from society while contributing substantially to the circular green economy is plasma gasification.
Municipal solid waste, discarded plastics & paper, forest biomass waste and other wastes all contain molecules ready to be released into valuable syngas, such as hydrogen, aviation fuel, bio-gasoline and other molecules. Additionally, the European Union has put clear-cut waste management legislation in place, promoting preventive and mitigating steps to reduce the constantly rising amounts of solid waste, creating the potential for plasma gasification in the region.
Increasing adoption of waste to energy plants globally
Between 2010 and 2018, the EU-27’s total garbage generation increased by 5% (114 million tonnes). It rises by 7% when major mineral wastes are excluded from the total (50.3 million tons). The cited figure suggests that the EU-27 is behind schedule in achieving its waste reduction policy objective, which supports the deployment of waste reduction technologies. One such technique is plasma gasification, utilized throughout Europe to decrease trash and turn it into energy to meet the region’s rising energy demand.
Compared to more common waste-to-energy (WtE) processes like incineration or gasification, plasma gasification is a successful thermal treatment for waste streams, particularly solid wastes. It results in lower pollutant emissions, fewer materials that need to be landfilled, higher conversion efficiencies and better quality producer gas. Additionally, plasma gasification transforms MSW into usable synthesis gas or syngas.
High initial investment and requirement-specific feedstock
Due to high production and operating expenses, plasma gasification techniques cannot become widely used in various European nations with significant electricity and associated environmental problems. Although plasma gasification offers numerous benefits that help the market expand, the process’ high initial cost continues to be its principal barrier to expansion. Because landfill land is scarce in small nations like Sweden and UK, where landfill and incinerator costs typically range between US$200 and US$300 per ton, thermal plasma gasification for MSW is more cost-effective there.
Additionally, research on European facilities reveals that many plants have shut down owing to financial issues, citing insufficient revenues and feedstock preparation expenses. Companies with contracts to treat waste must also pay the extra costs of moving waste somewhere else if the facility doesn’t work as expected or needs to be shut down for repairs. Thus, plasma gasification is more expensive than other waste management methods like recycling, composting and landfilling.

COVID-19 Impact Analysis
To stem the COVID-19 outbreak, travel bans and airline cancellations have been implemented. The World Energy Council also estimates that by 2020, the coronavirus will have eliminated billions of barrels of oil, trillions of cubic meters of gas and millions of tonnes of coal from the world’s energy system. Since current blending requirements require that biofuels be blended with gasoline or diesel, a drop in demand for road transportation is expected to affect the supply of biofuels immediately.
The management of trash is a concern on a global scale. Each year, the agricultural, municipal and industrial sectors produce billions of tonnes of waste. These facilities could help you turn a waste management issue into a profit-generating opportunity for your farm or company. Solid and liquid waste materials are recycled into synthesis gas through a chemical reaction. Among other useful products, syngas can produce electricity or gas fuel as a byproduct.
A new method called plasma gasification can turn carbon-based materials into fuels. It might be incorporated into the design of a system that generates renewable fuels and achieves zero waste while protecting the environment. Plasma arc processing has been used for years to turn chemical weapons and incinerator waste into non-hazardous slag. Nearly all types of medical waste have been successfully treated using plasma gasification technology. The technique has improved the circular economy idea by using by-products as useful inputs to other materials.

Segment Analysis
By application, the Europe plasma gasification market is segmented into methanol, Fischer-tropsch, synthetic natural gas, iron reduction, syngas production, hydrogen and power generation.
The rising agricultural waste drives the methanol segment’s growth
Among other things, syngas is used as a fuel for gas turbines, as the anode gas in solid oxide fuel cells and as a component of methanol production. Methanol is manufactured from the syngas created during the plasma gasification process. A commercially proven technique, which uses both natural gas and coal as fuel, produces methanol from syngas. Methanol factories in the modern world have a daily production capacity of between 2,000 and 2,500 metric tonnes (t/d). Larger scale (5,000 t/d) single-train methanol processing systems are present.
Agriculture trash makes up a major portion of the rising global waste volumes. For instance, UK produces about 135,500 tonnes of agricultural plastic waste each year, of which 32,000 tonnes come from plastic packaging waste. Comparatively, non-packaging plastics make up about 103,500 tonnes (including contamination). As a result, there will be a great need for plasma gasifiers during the projection period due to the expanding agricultural waste’s enormous potential for methanol production

Geographical Analysis
The growing need to achieve net-zero emissions in UK
In major cities, automobiles now account for the majority of air pollution. Even the most technologically adept automakers have been unable to reach acceptable levels of exhaust gas toxicity and specific fuel rate. Due to tightening environmental rules regarding hazardous emissions, work on spark-ignited internal combustion engines and the creation of gaseous fuels has increased.
Reducing emissions from road transportation is still a major challenge for UK as it works to attain net-zero emissions by the year 2050; as of the end of 2018, only 0.5% of all vehicles with UK license plates were ultra-low emission vehicles. However, GHG emissions from vehicle travel in UK have grown by 6% from 1990 to 2017, slower than the traffic growth.
The most dependable and energy-efficient conversion process is plasma gasification, which also has advantages in terms of flexibility upstream and downstream. The feedstock’s hydrogen-to-carbon ratio is improved by a thermochemical conversion that breaks carbon bonds and adds hydrogen to gaseous products. Thus, rising concerns about UK automotive industry air pollution have increased demand for fuel gas with little negative environmental effects.
Europe Plasma Gasification Market Competitive Landscape
With few competitors in the industry, the Europe plasma gasification market exhibits a highly competitive landscape. Regional firms that are well-represented in Europe and specific markets dominate the market. Several firms battle for a sizeable piece of the market to diversify their product offerings while expanding their geographic reach. A current driving force in Europe is the European government’s support for the plasma gasification industry through various policies and regulations.
Major Europe plasma gasification market companies include S.W.H. GROUP SE, OMNI Conversion Technologies Inc., PyroGenesis Canada Inc., Tetronics Environmental Waste Treatment, Fomento de Construcciones y Contratas, S.A. (FCC), Aventum, Millenium Technologies, A.S., Plasma Power, LLC., Boson Energy SA and Nedap N.V.
PyroGenesis Canada Inc.
Overview: PyroGenesis Canada Inc. is a market leader in designing, developing, producing and commercializing innovative plasma technologies. Many items are available for defense, metallurgical, mining, additive manufacturing (like 3D printing), oil & gas and environmental industries. In Montreal, Canada, a production plant is 3,800 m2 and a distribution center is 2,940 m2. PyroGenesis is a world leader in plasma torches, plasma waste processing, high-temperature metallurgical processes and technical services owing to its key competencies.
Product Portfolio: The company offers a two-stage gasification/vitrification method that uses thermal plasma technology to transform chemical waste into clean fuel. The inert slag or glass, on the other hand, can be made into various high-value goods or utilized in construction. Trash is converted into electrical energy, metals and vitreous slag using a two-stage gasification process. For instance, the PRRS system feeds unsorted garbage into a graphite arc plasma furnace, where gasification creates a synthesis gas from the organic part of the waste.
Key Development: Airscience technologies inc. and its affiliates, collectively referred to as "A.S.T.," were purchased by PyroGenesis in August 2021 for a total cash value of roughly US$4.4 million.
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Target Audience 2022


  • • Plasma Gasification Service Providers/ Buyers
    • Industry Investors/Investment Bankers
    • Education & Research Institutes
    • Emerging Companies
    • Plasma Gasification Manufacturers