Thermal decomposition

Last updated April 20, 2024

Thermal decomposition (or thermolysis) is a chemical decomposition caused by heat. The decomposition temperature of a substance is the temperature at which the substance chemically decomposes. The reaction is usually endothermic as heat is required to break chemical bonds in the compound undergoing decomposition. If decomposition is sufficiently exothermic, a positive feedback loop is created producing thermal runaway and possibly an explosion or other chemical reaction.

Decomposition temperature definition

A simple substance (like water) may exist in equilibrium with its thermal decomposition products, effectively halting the decomposition. The equilibrium fraction of decomposed molecules increases with the temperature. Since thermal decomposition is a kinetic process, the observed temperature of its beginning in most instances will be a function of the experimental conditions and sensitivity of the experimental setup. For a rigorous depiction of the process, the use of thermokinetic modeling is recommended.^[1]

main definition: Thermal decomposition is the breakdown of a compound into two or more different substances using heat, and it is an endothermic reaction

Examples

Calcium carbonate (limestone or chalk) decomposes into calcium oxide and carbon dioxide when heated. The chemical reaction is as follows:

CaCO₃ → CaO + CO₂

The reaction is used to make quick lime, which is an industrially important product.

Another example of thermal decomposition is 2Pb(NO₃)₂ → 2PbO + O₂ + 4NO₂.

Some oxides, especially of weakly electropositive metals decompose when heated to high enough temperature. A classical example is the decomposition of mercuric oxide to give oxygen and mercury metal. The reaction was used by Joseph Priestley to prepare samples of gaseous oxygen for the first time.
When water is heated to well over 2,000 °C (2,270 K; 3,630 °F), a small percentage of it will decompose into OH, monatomic oxygen, monatomic hydrogen, O₂, and H₂.^[2]
The compound with the highest known decomposition temperature is carbon monoxide at ≈3870 °C (≈7000 °F).^{[ citation needed ]}

Decomposition of nitrates, nitrites and ammonium compounds

Ammonium dichromate on heating yields nitrogen, water and chromium(III) oxide.
Ammonium nitrate on strong heating yields dinitrogen oxide ("laughing gas") and water.
Ammonium nitrite on heating yields nitrogen gas and water.
Barium azide on heating yields barium metal and nitrogen gas.
Sodium azide on heating at 300 °C (573 K; 572 °F) violently decomposes to nitrogen and metallic sodium.
Sodium nitrate on heating yields sodium nitrite and oxygen gas.
Organic compounds like tertiary amines on heating undergo Hofmann elimination and yield secondary amines and alkenes.

Ease of decomposition

When metals are near the bottom of the reactivity series, their compounds generally decompose easily at high temperatures. This is because stronger bonds form between atoms towards the top of the reactivity series, and strong bonds are difficult to break. For example, copper is near the bottom of the reactivity series, and copper sulfate (CuSO₄), begins to decompose at about 200 °C (473 K; 392 °F), increasing rapidly at higher temperatures to about 560 °C (833 K; 1,040 °F). In contrast potassium is near the top of the reactivity series, and potassium sulfate (K₂SO₄) does not decompose at its melting point of about 1,069 °C (1,342 K; 1,956 °F), nor even at its boiling point.

Practical applications

Many scenarios in the real world are affected by thermal degradation. One of the things affected is fingerprints. When anyone touches something, there is residue left from the fingers. If fingers are sweaty, or contain more oils, the residue contains many chemicals. De Paoli and her collogues conducted a study testing thermal degradation on certain components found in fingerprints. For heat exposure, the amino acid and urea samples started degradation at 100 °C (373 K; 212 °F) and for lactic acid, the decomposition process started around 50 °C (323 K; 122 °F).^[3] These components are necessary for further testing, so in the forensics discipline, decomposition of fingerprints is significant.

Related Research Articles

Combustion, or burning, is a high-temperature exothermic redox chemical reaction between a fuel and an oxidant, usually atmospheric oxygen, that produces oxidized, often gaseous products, in a mixture termed as smoke. Combustion does not always result in fire, because a flame is only visible when substances undergoing combustion vaporize, but when it does, a flame is a characteristic indicator of the reaction. While activation energy must be supplied to initiate combustion, the heat from a flame may provide enough energy to make the reaction self-sustaining. The study of combustion is known as combustion science.

Chlorine is a chemical element; it has symbol Cl and atomic number 17. The second-lightest of the halogens, it appears between fluorine and bromine in the periodic table and its properties are mostly intermediate between them. Chlorine is a yellow-green gas at room temperature. It is an extremely reactive element and a strong oxidising agent: among the elements, it has the highest electron affinity and the third-highest electronegativity on the revised Pauling scale, behind only oxygen and fluorine.

An explosive is a reactive substance that contains a great amount of potential energy that can produce an explosion if released suddenly, usually accompanied by the production of light, heat, sound, and pressure. An explosive charge is a measured quantity of explosive material, which may either be composed solely of one ingredient or be a mixture containing at least two substances.

Nitrogen is a chemical element; it has symbol N and atomic number 7. Nitrogen is a nonmetal and the lightest member of group 15 of the periodic table, often called the pnictogens. It is a common element in the universe, estimated at seventh in total abundance in the Milky Way and the Solar System. At standard temperature and pressure, two atoms of the element bond to form N₂, a colorless and odorless diatomic gas. N₂ forms about 78% of Earth's atmosphere, making it the most abundant uncombined element in air. Because of the volatility of nitrogen compounds, nitrogen is relatively rare in the solid parts of the Earth.

<span class="mw-page-title-main">Ammonium nitrate</span> Chemical compound with formula NH4NO3

Ammonium nitrate is a chemical compound with the formula NH₄NO₃. It is a white crystalline salt consisting of ions of ammonium and nitrate. It is highly soluble in water and hygroscopic as a solid, although it does not form hydrates. It is predominantly used in agriculture as a high-nitrogen fertilizer.

Nitrogen dioxide is a chemical compound with the formula NO₂. One of several nitrogen oxides, nitrogen dioxide is a reddish-brown gas. It is a paramagnetic, bent molecule with C_2v point group symmetry. Industrially, NO₂ is an intermediate in the synthesis of nitric acid, millions of tons of which are produced each year, primarily for the production of fertilizers.

In chemistry, azide is a linear, polyatomic anion with the formula N−3 and structure ⁻N=N⁺=N⁻. It is the conjugate base of hydrazoic acid HN₃. Organic azides are organic compounds with the formula RN₃, containing the azide functional group. The dominant application of azides is as a propellant in air bags.

Dinitrogen pentoxide is the chemical compound with the formula N₂O₅. It is one of the binary nitrogen oxides, a family of compounds that only contain nitrogen and oxygen. It exists as colourless crystals that sublime slightly above room temperature, yielding a colorless gas.

Calcination is thermal treatment of a solid chemical compound (e.g. mixed carbonate ores) whereby the compound is raised to high temperature without melting under restricted supply of ambient oxygen (i.e. gaseous O₂ fraction of air), generally for the purpose of removing impurities or volatile substances and/or to incur thermal decomposition.

Chemical decomposition, or chemical breakdown, is the process or effect of simplifying a single chemical entity into two or more fragments. Chemical decomposition is usually regarded and defined as the exact opposite of chemical synthesis. In short, the chemical reaction in which two or more products are formed from a single reactant is called a decomposition reaction.

<span class="mw-page-title-main">Hydrazoic acid</span> Unstable and toxic chemical compound

Hydrazoic acid, also known as hydrogen azide, azic acid or azoimide, is a compound with the chemical formula HN₃. It is a colorless, volatile, and explosive liquid at room temperature and pressure. It is a compound of nitrogen and hydrogen, and is therefore a pnictogen hydride. The oxidation state of the nitrogen atoms in hydrazoic acid is fractional and is -1/3. It was first isolated in 1890 by Theodor Curtius. The acid has few applications, but its conjugate base, the azide ion, is useful in specialized processes.

Oxygen fluorides are compounds of elements oxygen and fluorine with the general formula O_nF₂, where n = 1 to 6. Many different oxygen fluorides are known:

The Curtius rearrangement, first defined by Theodor Curtius in 1885, is the thermal decomposition of an acyl azide to an isocyanate with loss of nitrogen gas. The isocyanate then undergoes attack by a variety of nucleophiles such as water, alcohols and amines, to yield a primary amine, carbamate or urea derivative respectively. Several reviews have been published.

The chemical element nitrogen is one of the most abundant elements in the universe and can form many compounds. It can take several oxidation states; but the most common oxidation states are -3 and +3. Nitrogen can form nitride and nitrate ions. It also forms a part of nitric acid and nitrate salts. Nitrogen compounds also have an important role in organic chemistry, as nitrogen is part of proteins, amino acids and adenosine triphosphate.

Magnesium compounds are compounds formed by the element magnesium (Mg). These compounds are important to industry and biology, including magnesium carbonate, magnesium chloride, magnesium citrate, magnesium hydroxide, magnesium oxide, magnesium sulfate, and magnesium sulfate heptahydrate.

Fire-safe polymers are polymers that are resistant to degradation at high temperatures. There is need for fire-resistant polymers in the construction of small, enclosed spaces such as skyscrapers, boats, and airplane cabins. In these tight spaces, ability to escape in the event of a fire is compromised, increasing fire risk. In fact, some studies report that about 20% of victims of airplane crashes are killed not by the crash itself but by ensuing fires. Fire-safe polymers also find application as adhesives in aerospace materials, insulation for electronics, and in military materials such as canvas tenting.

<span class="mw-page-title-main">Potassium azide</span> Chemical compound

Potassium azide is the inorganic compound having the formula KN₃. It is a white, water-soluble salt. It is used as a reagent in the laboratory.

Scandium bromide, or ScBr₃, is a trihalide, hygroscopic, water-soluble chemical compound of scandium and bromine.

<span class="mw-page-title-main">Cobalt oxide nanoparticle</span>

In materials and electric battery research, cobalt oxide nanoparticles usually refers to particles of cobalt(II,III) oxide Co^₃O^₄ of nanometer size, with various shapes and crystal structures.

Photogeochemistry merges photochemistry and geochemistry into the study of light-induced chemical reactions that occur or may occur among natural components of Earth's surface. The first comprehensive review on the subject was published in 2017 by the chemist and soil scientist Timothy A Doane, but the term photogeochemistry appeared a few years earlier as a keyword in studies that described the role of light-induced mineral transformations in shaping the biogeochemistry of Earth; this indeed describes the core of photogeochemical study, although other facets may be admitted into the definition.

References

↑ Koga, Nobuyoshi; Vyazovkin, Sergey; Burnham, Alan K.; Favergeon, Loic; Muravyev, Nikita V.; Pérez-Maqueda, Luis A.; Saggese, Chiara; Sánchez-Jiménez, Pedro E. (2023). "ICTAC Kinetics Committee recommendations for analysis of thermal decomposition kinetics". Thermochimica Acta. 719: 179384. doi: 10.1016/j.tca.2022.179384 . S2CID 253341877.
↑ Baykara S (2004). "Hydrogen production by direct solar thermal decomposition of water, possibilities for improvement of process efficiency". International Journal of Hydrogen Energy. 29 (14): 1451–1458. doi:10.1016/j.ijhydene.2004.02.014.
↑ De Paoli G, Lewis SA, Schuette EL, Lewis LA, Connatser RM, Farkas T (July 2010). "Photo- and thermal-degradation studies of select eccrine fingerprint constituents". Journal of Forensic Sciences. 55 (4): 962–969. doi:10.1111/j.1556-4029.2010.01420.x. PMID 20487155. S2CID 37942037.

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[1] Koga, Nobuyoshi; Vyazovkin, Sergey; Burnham, Alan K.; Favergeon, Loic; Muravyev, Nikita V.; Pérez-Maqueda, Luis A.; Saggese, Chiara; Sánchez-Jiménez, Pedro E. (2023). "ICTAC Kinetics Committee recommendations for analysis of thermal decomposition kinetics". Thermochimica Acta. 719: 179384. doi: 10.1016/j.tca.2022.179384 . S2CID 253341877.

[2] Baykara S (2004). "Hydrogen production by direct solar thermal decomposition of water, possibilities for improvement of process efficiency". International Journal of Hydrogen Energy. 29 (14): 1451–1458. doi:10.1016/j.ijhydene.2004.02.014.

[3] De Paoli G, Lewis SA, Schuette EL, Lewis LA, Connatser RM, Farkas T (July 2010). "Photo- and thermal-degradation studies of select eccrine fingerprint constituents". Journal of Forensic Sciences. 55 (4): 962–969. doi:10.1111/j.1556-4029.2010.01420.x. PMID 20487155. S2CID 37942037.

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