BROMINATED FLAME RETARDANT MARKET

KEY FINDINGS

• The market saw a decline in 2023 compared to 2022 due to the lack of sales in electronics globally and has a 3-9 month lag in the supply chain​.
• Electric vehicles, data centres, and consumer electronics will drive the market over the forecast period​.
• There is a prevailing uncertainty in the market due to the impact of regulations and 2025 will be a critical year for the brominated flame retardant market to determine the future, especially for chemicals such as TBBPA and DBDPE​
• The growth of increasing energy storage globally will drive the market for global brominated flame retardant market mainly in electric vehicle​
• There will also be growth across different geographies due to the increase in the size of data centres and electronics usage​
• There will be new brominated flame retardants that will come into the market to keep up with sustainability and toxicity norms​
• There will be a focus on improving the recyclability of bromine and brominated flame retardants from electronic components​
• The CHIPS act is enabling multiple foundries that are being set up in the USA which will enable chip manufacturing in USA will lead the growth of brominated flame retardant market in the region 
• Bromine recyclability is being looked into massively in the USA. ACC, NAFRA, CDU, and UAEU are collaborating to develop new processes for recovering and recycling bromine and antimony from flame-retarded plastics. ​
• The strategy prioritises brominated flame retardants, particularly aromatic ones, for restriction, following the Restrictions Roadmap. ​
• Future assessments will address non-halogen and organophosphorus flame retardants. Aromatic brominated variants raise concerns due to PBT/vPvB properties, warranting minimised release.Proposed restriction proposals await conclusive data from ongoing studies​

BROMINATED FLAME RETARDANT MARKET OVERVIEW

The market is subjected to witness changes due to regulations mainly coming in from USA and Europe which can lead to negative growth especially based on the study results from Europe in 2025​

Governments and industry bodies around the world are implementing increasingly strict fire safety regulations. These regulations often mandate the use of flame retardants in various applications, such as building materials, electronics, and textiles, to enhance public safety and minimise fire hazards. This regulatory framework plays a crucial role in driving demand for flame retardants, including brominated varieties.​

The automotive industry’s emphasis on lightweight materials and energy-efficient vehicles has led to the use of highly flammable materials, necessitating the incorporation of flame retardants, including brominated flame retardants, to enhance vehicle safety.​

Increasing regulations and standards mandating fire safety measures in various industries, such as construction, electronics, and automotive, drive the demand for flame retardant materials, including brominated flame retardants.​

The proliferation of electronic devices and the increasing complexity of electronic components create a higher risk of fire incidents. Brominated flame retardants are widely used in electronics to mitigate fire hazards and ensure product safety.​

Brominated flame retardants have been associated with various health and environmental concerns, including potential carcinogenicity, endocrine disruption, and toxicity to aquatic organisms. ​

Many countries have either banned or restricted the use of certain brominated flame retardants, leading to a shift towards alternative flame retardant compounds.

New flame retardants need to be compatible with a wide range of materials used in electronics (e.g., polymers, resins), construction (e.g., plastics, textiles), and furnishings (e.g., foams, fabrics). 

The market for Global Brominated Flame Retardant in US will grow from XX Kilotons in 2023 to XX Kilotons in 2030 at a CAGR of X% from 2024-2030.​

INTRODUCTION TO BROMINATED FLAME RETARDANT MARKET

Organobromine chemicals known as brominated flame retardants have an inhibitory influence on combustion chemistry and tend to make items less flammable. Brominated flame retardants (BFRs) are concoctions of synthetic chemicals put into a wide range of goods, including those used in industry, to reduce their flammability. They are frequently used in electrical and electronic equipment, textiles, and plastics. In our built environment, brominated flame retardants (BFRs) are a common sight.

These flame retardants have increased public safety for many years by lowering the flammability of commonplace things including computers, furniture, and beds. Because it can put out fires before they reach their ignition point and release active atoms when heated, bromine is the most prevalent component. Bromine atoms can stop a fire from spreading further or fully put it out by interfering with the chemical reaction occurring inside the flames.

BROMINATED FLAME RETARDANT MARKET SIZE AND FORECAST

The Global Brominated Flame Retardant market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.

TRENDS IN BROMINATED FLAME RETARDANT MARKET

• Core-Shell Nanostructures: Combining a fire-retardant core material (e.g., metal oxide) with a polymer shell for better compatibility and targeted delivery within the material.​
• Nanocomposite Networks: Creating a network of flame-retardant nanoparticles throughout the material to improve efficiency and heat dissipation properties.​
• Self-Extinguishing Polymers: Polymers that automatically stop burning upon removal of the heat source. This could be achieved by incorporating flame-retardant moieties directly into the polymer backbone.​
• Flame-Triggered Chemical Reactions: Polymers designed to undergo specific chemical reactions when exposed to high temperatures. These reactions could release non-flammable gases or form a protective char layer.​
• Intumescent Systems Inspired by Wood: Studying the natural fire resistance of wood, where cellulose decomposes to form a char layer, and mimicking this behaviour in synthetic materials.​
• Layered Double Hydroxides (LDHs) Inspired by Clays: Utilising LDHs, which naturally exhibit flame-retardant properties due to their ability to absorb water and release it upon heating, as inspiration for novel flame retardant materials.​
• Virtual Flame Testing: Simulating fire scenarios using computer models to predict the behaviour of materials with different flame retardant systems. This allows for faster and more cost-effective screening of potential candidates.​
• Material Design at the Atomic Level: Utilising computational chemistry to design flame retardant molecules at the atomic level, tailoring their properties for optimal efficiency and compatibility with specific materials.​

BROMINATED FLAME RETARDANT MARKET NEW PRODUCT LAUNCH

New Isonex Flame Retardants by Albemarle Corporation:​ ​Isonex 1000: Primarily used in engineering plastics and high-performance composites. ​Isonex 2000: Suitable for various applications, including electrical and electronic components.​ Isonex 3000: Designed for use in printed circuit boards and electronic components.​

Non-halogenated Flame Retardants: These alternatives do not contain bromine or chlorine and are generally considered safer for human health and the environment. Examples include phosphates, red phosphorus, and metal oxides. Research and development efforts are focused on improving their flame retardant efficiency to match the performance of brominated flame retardants.​

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Tetrabromobisphenol A (TBBPA) :​ A reactive flame retardant with a global consumption of 210,000 tonnes. TBBPA is widely used across diverse industries due to its excellent flame-retardant properties and cost-effectiveness. TBBPA is becoming a preferred choice among manufacturers due to its relatively low toxicity and environmental impact compared to other bromine-based flame retardants.​

Targeted Modifications :​ Debromination: This involves reducing the number of bromine atoms in existing brominated flame retardant molecules. This can potentially lower their environmental impact while still maintaining some level of fire retardancy.​

Encapsulation: Encapsulating brominated flame retardants within a shell material can minimise their release into the environment and potentially improve safety during product use and disposal.​

Sustainability for safe environments :​ FRX Innovations’ Nofia® flame retardants received the prestigious SAFER certification in 2022. This eco-friendly alternative to traditional flame retardants prioritises both safety and sustainability. FRX Polymers, the parent company, solidified its lead in the eco-friendly flame retardant market with Nofia®, used in various products from electronics to building materials.​

BROMINATED FLAME RETARDANT MARKET PRODUCT DEVELOPMENT AND INNOVATION

A common brominated flame retardant used to improve the fire safety characteristics of materials and goods is DE-83R. DE-83R, also known as Decabromodiphenyl Ethane, is a member of the brominated flame retardant family and is a very effective flame retardant.

It has a chemical composition of C14H4Br10 and is a white, crystalline powder. By generating bromine radicals during combustion, DE-83R’s unique molecular structure enables it to successfully prevent the start and spread of fire. The high bromine content of DE-83R, which contributes to its remarkable flame retardant capabilities, is one of the substance’s distinguishing characteristics. Its 82% bromine concentration makes it a useful additive for ensuring fire safety compliance in a variety of materials and products. Plastics, textiles, electronics, construction materials, and automobile parts are among the main industries in which DE-83R is utilized as a flame retardant.

 The plastics industry uses DE-83R extensively, and it is frequently employed as an additive in thermoplastics such polyolefins, polystyrene, and polyamides. Manufacturers can strengthen these materials’ fire resistance, lower their flammability, and perform better in terms of overall fire safety by integrating DE-83R into them. DE-83R can be employed in a variety of plastic molding procedures, including injection molding, extrusion, and blow molding, thanks to its adaptability.

When it comes to synthetic fibers like polyester, nylon, and acrylic, DE-83R is used as a flame retardant in the textile sector. It can be used on completed fabrics as a post-treatment or during the textile manufacturing process.  In order to make textiles acceptable for applications where fire safety is essential, such as upholstery, curtains, and protective equipment, DE-83R can be used to considerably improve the fabrics’ fire resistance. Another significant application for DE-83R is as a flame retardant in electrical gadgets.

To stop or postpone the start of a fire and its spread, it is built into the plastic housings, circuit boards, and connectors of electronic equipment. Despite the fact that DE-83R has been widely utilized in a variety of industries due to its benefits for fire safety, it is important to take into account the environmental implications of its use. Due to worries about their possible persistence, bioaccumulation, and toxicity, brominated flame retardants, especially DE-83R, have come under close examination. Manufacturers and regulatory agencies have been attempting to create substitute flame retardants with better environmental profiles in response to these worries.

Research and development efforts are being made to look into potential substitutes for brominated flame retardants like DE-83R as the need for more environmentally friendly flame retardant solutions grows. These options seek to offer reliable fire protection features while reducing adverse effects on the environment and human health. Nanocomposites, intumescent systems, and flame retardants based on phosphorus are a few viable substitutes. A highly effective brominated flame retardant with several uses in different sectors is DE-83R.

It is a valuable additive for boosting fire safety in plastics, textiles, electrical devices, and other materials due to its high bromine concentration and outstanding flame retardant qualities. However, continuous study and development of substitutes have been prompted by environmental concerns related to brominated flame retardants, notably DE-83R. In the end, the development of flame retardant technology will be influenced by the need to strike a balance between fire safety needs and environmental concerns.

BROMINATED FLAME RETARDANT MARKET SEGMENTATION

By Geography​

• US​
• Europe​
• China​
• Asia Ex China​
• ROW​

By Type​

• (TBBPA)​
• (DBDPE)​
• Others

By Application​

• Plastics & Polymers​
• Textiles​
• Foam Insulation​
• Adhesives & Sealants​

By End Use​

• Electronics & Electrical​
• Building & Construction​
• Automotive​
• Textile & Furniture​

BROMINATED FLAME RETARDANT MARKET COMPANY PROFILES

• Albemarle Corporation (US)​
• ICL Industrial Products (Israel)​
• LANXESS AG (Germany)​
• Tosoh Corporation (Japan)​
• Tata Chemicals (India)​
• Gulf Resources (China)​

BROMINATED FLAME RETARDANT MARKET REPORT WILL ANSWER FOLLOWING QUESTIONS

1. How many Brominated Flame Retardants are manufactured per annum globally? Who are the sub-component suppliers in different regions?
2. Cost breakup of a Global Brominated Flame Retardant and key vendor selection criteria
3. Where is the Brominated Flame Retardant manufactured? What is the average margin per unit?
4. Market share of Global Brominated Flame Retardant market manufacturers and their upcoming products
5. Cost advantage for OEMs who manufacture Global Brominated Flame Retardant in-house
6. key predictions for next 5 years in Global Brominated Flame Retardant market
7. Average B-2-B Brominated Flame Retardant market price in all segments
8. Latest trends in Brominated Flame Retardant market, by every market segment
9. The market size (both volume and value) of the Brominated Flame Retardant market in 2024-2030 and every year in between?
10. Production breakup of Brominated Flame Retardant market, by suppliers and their OEM relationship
11. How are regulations regarding the use of brominated flame retardants (BFRs) in automotive materials evolving globally, and how are these regulations impacting the BFR market?
12. How is the BFR market for automotive applications segmented by type of BFR (e.g., PBDEs, HBCDs)?  Are there specific segments experiencing faster growth or decline?
13. What are the key trends in the substitution of BFRs with alternative flame retardant solutions in the automotive industry?  What are the main challenges with these replacements?
14. How does the presence of BFRs in automotive components complicate the recycling process, and what are potential solutions to overcome these challenges?
15. How are ongoing health concerns regarding potential health risks associated with BFRs influencing consumer preferences and manufacturer decisions in the automotive sector?
16. Are there significant regional variations in the adoption rates and regulations concerning BFRs used in automotive applications?  If so, what are the driving factors behind these differences?
17. Are there any emerging BFR formulations or technologies being developed that address both fire safety and environmental/health concerns for the automotive industry?
18. Considering the potential costs of BFR regulations, substitution, and potential health risks, how does the overall cost-benefit analysis of using BFRs compare to alternative flame retardant solutions in the long term?
19. Are there collaborative efforts among automotive manufacturers, BFR producers, and regulatory bodies to develop safer and more sustainable BFR solutions for the future?
20. How are life cycle assessments being used to evaluate the environmental impact of BFRs throughout their entire life cycle in automotive applications, from production to disposal?
21. How can the automotive industry increase consumer awareness regarding the use of BFRs in vehicles and the ongoing efforts towards safer alternatives?