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According to Stratistics MRC, the Global Hydrogenation Catalyst Market is accounted for $1.49 billion in 2023 and is expected to reach $2.31 billion by 2030 growing at a CAGR of 6.5% during the forecast period. In the presence of catalysts like nickel, palladium, or platinum, the chemical reaction of hydrogen with another substance, compound, or element is known as hydrogenation. A hydrogenation catalyst is a catalyst used to produce hydrogen. These catalysts are used in industry to remove the benzyloxycarbonyl and benzyl groups as well as hydrogenate the carbon-carbon (C-C) bond.
According to World Economic Forum, in United States, manufacturing industry accounts for 23% of direct carbon emission. Further, increased demand for hydrogenation catalyst from pharmaceutical industry is also estimated to be another important factor to drive the growth of the global hydrogenation catalyst market.
The market for hydrogenation catalysts is primarily driven by the rising demand for hydrogenated goods across numerous industries. In industries like petrochemicals, food, pharmaceuticals, and chemicals, hydrogenation is a critical procedure that is used to change unsaturated compounds into saturated ones. Moreover, the demand for hydrogenation catalysts is increased by this process, which improves the quality and stability of products.
Although hydrogenation techniques can enhance product quality and lower emissions, they are not entirely eco-friendly. Additionally, when hydrogen gas is consumed, it frequently comes from fossil fuels, which can increase greenhouse gas emissions. As environmental concerns increase, the environmental impact of hydrogenation processes may come under more scrutiny, which could lead to stricter regulations or the investigation of more environmentally friendly alternatives.
Due to factors like rising healthcare needs and the development of innovative therapies, the pharmaceutical industry is still expanding globally. In order to synthesize pharmaceutical intermediates and active ingredients with high purity and selectivity, hydrogenation catalysts are necessary. Furthermore, manufacturers of catalysts can benefit from this burgeoning market by offering high-quality catalysts that are specifically designed to meet the demanding needs of pharmaceutical production.
Alternatives to conventional hydrogenation techniques that are more effective or sustainable could cause market disruptions thanks to new technologies and inventive processes. Moreover, manufacturers of catalysts must keep track of developments in non-catalytic hydrogenation, alternative catalyst materials, and/or proprietary technologies that may eventually replace or lessen the need for conventional hydrogenation catalysts.
On the market for hydrogenation catalysts, the COVID-19 pandemic had a wide range of effects. While lockdowns and restrictions initially caused supply chains to be disrupted, industrial activity to decline, and projects to be delayed, the market recovered as a result of industries, particularly the pharmaceutical and food processing sectors, prioritizing the production of necessities while attempting to meet a rise in demand for packaged foods and pharmaceuticals. Additionally, the pandemic highlighted the value of catalysts in vaccine development and pharmaceutical research, encouraging investment in catalyst technologies.
It is anticipated that the precious metal-based hydrogen catalyst segment will hold the largest market share. This dominance is mainly attributable to the superior catalytic capabilities of precious metals like platinum, palladium, and rhodium, which allow for highly effective and selective hydrogenation reactions in a variety of sectors, including petrochemicals, pharmaceuticals, and specialty chemicals. However, they are crucial to many industrial processes because of how well they enable crucial transformations like the reduction of unsaturated compounds.
In the hydrogenation catalyst market, the environmental segment is growing at the highest CAGR. The growing global emphasis on sustainability and environmental responsibility is what fuels this growth. In environmental applications like the purification of emissions in air pollution control systems and the removal of pollutants from wastewater, hydrogenation catalysts are essential. Moreover, the demand for hydrogenation catalysts in environmental applications is steadily rising, making it one of the fastest-growing market segments due to strict environmental regulations and a growing awareness of the need for cleaner industrial processes.
The Asia-Pacific region holds the largest market share for hydrogenation catalysts. The region's strong industrial growth, particularly in nations like China and India, which have sizable chemical, petrochemical, and refining industries, is what's fueling this dominance. Asia-Pacific currently holds the top spot in the global hydrogenation catalyst market thanks to the rising demand for hydrogenation catalysts in these industries as well as the growing emphasis on environmentally friendly manufacturing techniques. Additionally, the region's booming food and pharmaceutical sectors also help to increase demand for these catalysts, further solidifying its position as the market leader.
The Middle East and Africa (MEA) is predicted to have the highest CAGR in the market for hydrogenation catalysts. The region has a sizable presence in the oil and gas sector, including the refining of crude oil and the production of petrochemicals which is driving this rapid growth. The demand for hydrogenation catalysts is being driven by significant investments in petrochemical and refining projects in MEA, which are necessary to meet environmental regulations and optimize processes. Additionally, the area's strategic location and easy access to feedstock make it a center for chemical manufacturing, which will help fuel the market for hydrogenation catalysts' anticipated rapid expansion.
Some of the key players in Hydrogenation Catalyst Market include: Haldor Topsoe A/S, SOLVIAS AG, Albemarle Corporation, China National Petroleum Corporation, CRI/Criterion Inc., BASF SE, SINOPEC Catalyst Company, W. R. Grace and Co., Advanced Refining Technologies (ART), Haldor Topsoe, Johnson Matthey, Axens, Honeywell International, Inc., SJEP and Evonik Industries AG.
In June 2023, QatarEnergy signed on Tuesday with China National Petroleum Corporation (CNPC) a long-term Liquefied Natural Gas sales agreement at its headquarters in Doha. The agreement entails the delivery of 4 million tonnes of LNG per year from QatarEnergy's North Field East LNG expansion project to CNPC's receiving terminals in China, spanning the course of 27 years, according to the Qatari state-owned company and the CNPC.
In May 2023, Albemarle Corporation, a global leader in providing essential elements for mobility, energy, connectivity and health, today announced a definitive agreement with Ford Motor Company to deliver battery-grade lithium hydroxide to support the automaker's ability to scale electric vehicle (EV) production. Albemarle will supply more than 100,000 metric tons of battery-grade lithium hydroxide for approximately 3 million future Ford EV batteries. The five-year supply agreement starts in 2026 and continues through 2030.
In May 2023, BASF Environmental Catalyst and Metal Solutions, a global leader in precious metals and catalysis, and Advent Technologies Holdings, Inc., an innovation-driven leader in the fuel cell and hydrogen technology sectors, have concluded the terms of a new agreement to join efforts in building a full loop component supply chain for fuel cells and enter discussions to extend the partnership into the field of water electrolysis.