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According to Stratistics MRC, the Global Iron Phosphate Market is accounted for $601.49 million in 2024 and is expected to reach $912.84 million by 2030 growing at a CAGR of 7.2% during the forecast period. Iron phosphate is a substance that is frequently utilized in many chemical and industrial processes, particularly in the energy storage industry. Known for its stability, longevity, and safety features, lithium iron phosphate (LiFePO4) batteries are made with it as a key component. Renewable energy storage systems, electric vehicles (EVs), and other applications requiring high performance and dependability frequently use these batteries.
According to the European Food Safety Authority (EFSA), iron phosphate is used in animal feed to prevent iron deficiency in livestock, which is essential for their growth and overall health. The EFSA reports that iron phosphate supplementation can improve livestock growth rates by 15-20%.
Rising demand for batteries made of lithium iron phosphate (LFP)
One of the main causes of the rising demand for iron phosphate, particularly in the form of lithium iron phosphate (LFP) batteries, is the rise in the use of electric vehicles (EVs). Because of their superior safety profile, extended lifespan, and affordability when compared to alternative battery chemistries, these batteries are recommended for EVs. LFP batteries are viewed as an essential part of the energy transition, given the global drive to lower carbon emissions and switch to more environmentally friendly energy sources. Furthermore, they are perfect for use in electric vehicles due to their increased stability, better thermal management, and lower risk of fire hazards.
Expensive manufacturing and scarce raw materials
Lithium, phosphate, and iron are among the particular raw materials needed to produce iron phosphate, particularly as lithium iron phosphate (LFP) for battery applications. Due to global supply chain constraints, these materials may occasionally be scarce or subject to price fluctuations. The rise in electric vehicles (EVs) has increased demand for LFP batteries, which could limit market growth by placing pressure on raw materials and raising production costs. Moreover, the availability and cost of necessary materials may be impacted by environmental and regulatory issues that the global mining industry faces.
Growing need for sustainable fertilizers in agriculture
Iron phosphate has a great chance to expand in the agricultural industry as sustainable farming methods gain popularity. The ability of fertilizers based on iron phosphate to increase soil fertility without having the harmful side effects of conventional fertilizers makes them valuable. As agricultural practices change in response to global concerns about environmental degradation and food security, these environmentally friendly fertilizers are especially crucial. Additionally, agricultural sustainability can be greatly aided by iron phosphate as the world's population rises and the demand for greater crop yields rises. Iron phosphate's use in pest control also increases its allure in environmentally friendly farming methods.
Competition from other technologies and materials
Due to fierce competition from alternative battery chemistries, especially in the electric vehicle (EV) and energy storage industries, iron phosphate is facing significant challenges. Despite their reputation for affordability and safety, lithium iron phosphate (LFP) batteries have a lower energy density than other battery chemistries like lithium manganese oxide (LMO) and lithium nickel cobalt aluminum (NCA). LFP batteries may also be threatened by the emergence of solid-state batteries, which provide greater energy densities and quicker charging times. Furthermore, if alternative materials prove to be more effective, these developments may lessen the need for iron phosphate in the manufacturing of batteries.
The COVID-19 pandemic had a major effect on the iron phosphate market, mostly due to manufacturing halts, delays in raw material production, and disruptions in global supply chains. The mining and extraction of vital resources like iron, phosphate, and lithium were impacted by the lockdowns and travel restrictions, which raised production costs and caused supply shortages. Furthermore, factory closures and a decline in consumer demand for automobiles caused production to slow down in the automotive sector, which is a significant user of lithium iron phosphate (LFP) batteries.
The Ferric Phosphate segment is expected to be the largest during the forecast period
Due to its widespread application in a variety of industries, such as food, agriculture, and batteries, the ferric phosphate segment is projected to hold the largest share in the iron phosphate market. Ferric phosphate is a common environmentally friendly pesticide in agriculture that is safer than synthetic chemicals, especially when used to control slugs and snails. Moreover, its dominance in the market has also been greatly aided by its involvement in energy storage solutions, such as the manufacturing of lithium iron phosphate (LFP) batteries for EVs and renewable energy storage.
The Powder segment is expected to have the highest CAGR during the forecast period
Throughout the projection period, the Powder segment is expected to have the highest CAGR. This expansion is fueled by the rising demand for goods based on iron phosphate, particularly in sectors like chemicals, agriculture, and battery manufacturing. The cost-effectiveness, safety, and environmental benefits of lithium iron phosphate (LFP) batteries, which use powdered iron phosphate, have led to their widespread use in the electric vehicle (EV) market. Iron phosphate powder is also widely used in agriculture as a more environmentally friendly and efficient substitute for conventional chemicals in fertilizers and pest control. Additionally, rapid market growth has been attributed to the powder form's increased efficiency, ease of use, and versatility in industrial applications.
The market for iron phosphate is projected to be dominated by the Asia-Pacific region due to its robust manufacturing base and rising demand for renewable energy storage systems, electric vehicles (EVs), and agricultural applications. China, Japan, and South Korea are major producers of lithium iron phosphate (LFP) batteries, which are extensively utilized in EVs because of their affordability and safety benefits. Iron phosphate is also being used more often in fertilizers and pesticides due to the regions quickly growing agricultural sector, especially in China and India. Furthermore, the region also gains from government programs that support green technologies and clean energy, which helps the iron phosphate market expand.
The iron phosphate market's highest CAGR is anticipated in the Middle East and Africa region. Growing investments in renewable energy projects, the increasing use of electric vehicles (EVs), and the expanding agricultural sector in important nations are the main drivers of this growth. The Middle East is making significant investments in sustainable technologies and clean energy as part of its efforts to diversify away from its reliance on oil, which increases demand for batteries based on iron phosphate, especially lithium iron phosphate (LFP) batteries. Moreover, iron phosphate is also becoming more and more popular in Africa for use in fertilizers and pesticides as nations look to increase agricultural productivity and food security.
Key players in the market
Some of the key players in Iron Phosphate market include Thermo Fisher Scientific Inc., Merck KGaA, Aarvee Chemicals, Charkit Chemical Company LLC, Innophos Holdings Inc., BASF SE, Jost Chemical Co., Mosaic Company, Alfa Aesar, Bayer AG, Pioneer Enterprise, Imperial Chemorporation, Crest Industrial Chemicals, Zhengzhou Ruipu Biological Engineering Co. Ltd and Spectrum Chemical Manufacturing Corporation.
In May 2024, Merck has signed a definitive agreement to acquire life science company Mirus Bio for US$ 600 million. Based in Madison, Wisconsin, USA, Mirus Bio is a specialist in the development and commercialization of transfection reagents. Transfection reagents, such as Mirus Bio's TransIT-VirusGEN(R), are used to help introduce genetic material into cells.
In April 2024, Bayer AG has signed a long-term supply agreement for electricity from renewable energy sources with Wuppertaler Stadtwerke (WSW), the public utility company of Wuppertal in North Rhein-Westphalia, Germany. The contract underlines Bayer's global commitment to sustainability.
In February 2023, Thermo Fisher Scientific Inc. entered into a definitive agreement to acquire CorEvitas, a provider of regulatory-grade, real-world evidence for approved medical treatments and therapies, from Audax Private Equity, for $912.5 million in cash. CorEvitas will become part of Thermo Fisher's Laboratory Products and Biopharma Services segment.