Professor Richard Hull
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Richard is a chemist who spends most of his time understanding the behaviour of unwanted fires, particularly the effects of fire retardants and the toxicity of the smoke. He teaches physical chemistry and, until the COVID pandemic, was giving lectures on his work all over the world.
Richard has over 140 published papers on the assessment of flammability, the influence of fire retardants on flammability, the toxicity of fire smoke and the effects of fire retardants on the smoke toxicity. He has published two major books Fire Toxicity (with Prof Anna Stec) and Fire Retardancy: New Strategies and Mechanisms.
Graduating in Chemistry with first class honours and a course prize from the University of Salford, Richard went on to study for a PhD using a laser pyrolysis time-of-flight mass spectrometer to investigate fire retardant behaviour. 10 years later, he was appointed to a University lectureship at Salford, where he returned to his fire retardancy research and started to work in fire toxicity. He was appointed to a Readership at the University of Bolton. In 2007, he was appointed to the first Chemistry Professorship here where he has continued to pursue his interest in fire research. He has twice been co-chair of the world's leading Fire Retardant Polymers FRPM07 and FRPM17 conference. Following the tragic Grenfell tower fire, his expertise in material flammability and smoke toxicity have been much in demand. He has been interviewed on the BBC's Panorama, Newsnight, Breakfast (on the red couch) and World at One, Channel 4's Dispatches, as well as many major news programmes. He has been invited to speak on his work in both the UK and European parliaments.
He is currently active with projects on fire protection of massive timber structures; fire protection of structural steel; fire safety of upholstered furniture; and fire toxicity and the case for regulation. He represents the Royal Society of Chemistry on British and International Standards Technical Committees on furniture flammability and smoke toxicity measurement.
- PhD Physical Chemistry, University of Salford 1987
- PGCE (Further and Technical Education), University of Manchester, 1987
- BSc (Hons) Chemistry, University of Salford, 1981
- Fire Retardants
- Fire Science
- Fire Toxicity
- Principal UK expert to the ISO technical committee on fire chemistry
- Fellow of the Royal Society of Chemistry (FRSC CChem)
- Fellow of the Institution of Fire Engineers (FFireE)
- Fellow of the Higher Education Academy (FHEA)
- Chartered Scientist (CSci)
Most unwanted fires are fuelled by polymeric materials long chains, with up to a million links in each chain, so the process of a fire starting involves breaking the chain into molecules which are small enough to vaporise, then react with oxygen, producing free radicals and releasing lots of heat - resulting in a flame. The reactions in a flame are billions of times faster than normal chemical reactions, and in the simple process of lighting a match, cellulose polymer chains are broken into small molecules, which are then oxidised to carbon dioxide and water! Fire retardants work by interfering with these processes. Some increase the amount of char formation, so the fuel is protected by a layer which won't vaporise easily. Others produce a swollen protective layer on the surface of the polymer, stopping the heat being able to break the chains.
A third group interfere with the free radical processes in flames, resulting in more products of incomplete combustion, including carbon monoxide, hydrocarbons and smoke. All are a testament to the ingenuity of chemists in creating a wonderful “box of tricks” without interfering too much with the useful properties of the plastic. Unfortunately, as plastics, and so fire retardants, have become more and more widespread, a number of problems have become associated with their use. Many of the original flame retardants are gas phase quenchers. Not only are they toxic, but also stable enough to persist in the environment. They have been found in pristine regions, such as the Arctic ice, and cause harm in wild birds, whales and porpoises. The gas phase flame retardants also increase the toxicity of the smoke when they burn. Almost all fire retardants cause problems for recyclers during end-of-life processing.
Fire retardants are only added to meet regulatory requirements, so can allow more flammable polymers to be used in high-risk situations. Most fire deaths and most fire injuries result from inhalation of toxic smoke. The team at UCLan are world-leading in understanding the generation, quantification and hazards of toxic smoke. While a single match burning will only produce carbon dioxide and water, a larger fire, particularly indoors, will quickly grow to become ventilation-controlled and because it cannot get enough oxygen will produce large amounts of deadly carbon monoxide, smoke, which stops people being able to see how to escape, and other partly oxygenated hydrocarbons which make it difficult to breathe. We have shown the effect of ventilation and fire retardants on the toxicity of smoke.
Recent publications:
- Ammonium polyphosphates: Correlating structure to application (2025) European Polymer Journal, 223, 113644.
- Variation of flammability and smoke toxicity of upholstered furniture composites with fire retardant treatment (2024) Journal of Materials Science and Technology, 202, 140-151.
- Flammability and burning behaviour of fire protected timber, (2023) Fire Safety Journal, 140, art. no. 103918.
- Smoke toxicity of fire protecting timber treatments, (2023) Fire Safety Journal, 141, art. no. 103977.
- A Critical Appraisal of the UK’s Regulatory Regime for Combustible Façades (2021) Fire Technology, 57(1), 261-290
- Fire behaviour of modern façade materials – Understanding the Grenfell Tower fire, (2019) Journal of Hazardous Materials, 368, pp. 115-123.
Use the links below to view their profiles:
- Centre for Fire and Hazards Science
- Fire Toxicity
- Fire retardants for furniture
- making tall buildings safer from fire
- Innovate UK Knowledge Transfer Partnership (1026104)
- Investigating the effect of large waste fires on air quality, Daphne Jackson Fellowship/EPSRC
- Novel Fire protection for structural steelwork using graphene based coatings, Innovate UK/TWI
- Investigation of self-heating and spontaneous ignition (Industry)
- Fire Toxicity of Insulation Materials (Industry)
- Innovate UK Knowledge Transfer Partnership (Rated "Outstanding")
- Fire retardant behaviour of silica fume nanoparticles (Industry)
- EPSRC Industrial Case studentship: Durable, Fire-safe Protection for Building Refurbishment
- Application of Naturally Occurring Huntite and Hydromagnesite to Fire Retardancy”, (Industry)
- Development of Fire-Safe Rubber-based Materials, (Industry)
- Use of recycled materials in fire lighters, (Envirolink)
- Use of industrial effluent as raw material for fire retardant products, (Envirolink)
- EPSRC Industrial Case studentship PEEK polymers with improved fire performance
- Development of Tube Furnace Toxicity Standard” (Industry)
- DTI Spark Award for feasibility study to develop fire retarded coating
- EPSRC Case Studentship Composition of early fire gases for sensing and detection
- BRE Fire and Security, Use of FTIR for fire gas analysis
- EU Framework 6 Predfire Nano Project to predict fire behaviour of nanocomposite materials
- EPSRC Nanocomposite Fire Retardants for Synthetic Fibres
- EPSRC funded Fire Retardants Network
- EPSRC Determination of combustion-toxicity of polymeric materials under different fire conditions”
Telephone:+44 (0) 1772 893543
Email: Email:Professor Richard Hull
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