Decomposition temperature is the temperature at which a substance chemically decomposes, breaking down into simpler substances or elements. This process typically involves the breaking of chemical bonds and often results in the release of gases, heat, or both. In the context of a Safety Data Sheet (SDS), decomposition temperature is a critical safety parameter that indicates the thermal stability of a substance and the potential hazards associated with its decomposition.
Key concepts related to decomposition temperature include:
Decomposition temperature information in an SDS is important for several reasons:
Several analytical techniques are used to determine decomposition temperature:
| Method | Description | Advantages | Limitations |
|---|---|---|---|
| Differential Scanning Calorimetry (DSC) | Measures heat flow associated with thermal transitions as a function of temperature | Small sample size, quantitative heat measurement, widely available | May miss subtle decomposition, pressure effects not captured |
| Thermogravimetric Analysis (TGA) | Measures weight changes as a function of temperature | Directly measures mass loss, can identify multi-stage decomposition | No heat flow information, not sensitive to decomposition without mass loss |
| Differential Thermal Analysis (DTA) | Measures temperature difference between sample and reference as a function of temperature | Can handle larger samples, simpler instrumentation | Less quantitative than DSC, lower sensitivity |
| Accelerating Rate Calorimetry (ARC) | Adiabatic calorimetry that measures self-heating rates | Simulates real-world scenarios, measures pressure effects | Requires larger samples, more complex and expensive |
| Isothermal Stability Testing | Holds sample at constant temperature and monitors for changes | Provides time-dependent stability information | Time-consuming, may require multiple tests |
| Evolved Gas Analysis (EGA) | Analyzes gases released during heating (often coupled with TGA) | Identifies decomposition products, provides mechanistic insights | Requires specialized equipment, complex data interpretation |
| UN Test Series H | Standardized tests for self-reactive substances and organic peroxides | Internationally recognized, directly applicable to transportation regulations | Designed for specific substance classes, resource-intensive |
| Type | Description | Examples | Safety Implications |
|---|---|---|---|
| Exothermic Decomposition | Releases heat during decomposition | Organic peroxides, nitro compounds, some metal nitrates | Can lead to thermal runaway, fires, or explosions if heat cannot dissipate |
| Endothermic Decomposition | Absorbs heat during decomposition | Metal carbonates, metal hydroxides, some hydrates | Generally self-limiting, less hazardous than exothermic decomposition |
| Oxidative Decomposition | Involves reaction with oxygen | Polymers, oils, fats | Can be accelerated by oxygen concentration, may lead to fires |
| Hydrolytic Decomposition | Involves reaction with water | Esters, amides, acid chlorides | Can be accelerated by humidity, may generate acidic or corrosive products |
| Photolytic Decomposition | Triggered by light exposure | Some pharmaceuticals, dyes, hydrogen peroxide | Requires light protection in packaging and storage |
| Catalytic Decomposition | Accelerated by catalysts | Hydrogen peroxide (metals), organic peroxides (metal ions) | Trace contaminants can significantly reduce stability |
| Self-Accelerating Decomposition | Rate increases as decomposition progresses | Organic peroxides, self-reactive substances | Can lead to rapid temperature and pressure increase, potential explosion |
| Category | Typical Decomposition Temperature Range | Stability Classification | Examples |
|---|---|---|---|
| Thermally Unstable | <100°C | Very Unstable | Some organic peroxides, diazo compounds, azides |
| Low Thermal Stability | 100-150°C | Unstable | Many organic peroxides, some nitro compounds |
| Moderate Thermal Stability | 150-250°C | Moderately Stable | Many polymers, some pharmaceuticals |
| High Thermal Stability | 250-400°C | Stable | Many organic compounds, some inorganic salts |
| Very High Thermal Stability | >400°C | Very Stable | Many inorganic compounds, ceramics, metals |
Note: These categories are approximate and may vary depending on the specific context and regulatory framework.
| Substance | Decomposition Temperature (°C) | Decomposition Type | Major Decomposition Products |
|---|---|---|---|
| Sodium Bicarbonate (Baking Soda) | 50 (begins), 270 (complete) | Endothermic | Sodium carbonate, water, carbon dioxide |
| Calcium Carbonate | 825 | Endothermic | Calcium oxide, carbon dioxide |
| Ammonium Nitrate | 210 | Exothermic | Nitrogen oxides, water, oxygen |
| Hydrogen Peroxide (90%) | 80-100 | Exothermic | Water, oxygen |
| Benzoyl Peroxide | 105 | Exothermic | Benzoic acid, carbon dioxide, phenyl radicals |
| Polyethylene | 335-450 | Exothermic | Various hydrocarbons, carbon monoxide, carbon dioxide |
| Polyvinyl Chloride (PVC) | 200-300 | Exothermic | Hydrogen chloride, benzene, toluene |
| Nylon-6,6 | 350-400 | Exothermic | Various nitrogen compounds, hydrocarbons |
| Aspirin (Acetylsalicylic Acid) | 140 | Endothermic | Salicylic acid, acetic acid |
| Potassium Chlorate | 400 | Exothermic | Potassium chloride, oxygen |
| Sodium Azide | 300 | Exothermic | Sodium, nitrogen gas |
| Sucrose (Table Sugar) | 186 | Endothermic | Carbon, water, carbon dioxide |
| Urea | 133 | Endothermic | Ammonia, isocyanic acid |
The molecular structure significantly affects decomposition temperature:
Several physical and environmental factors can influence decomposition temperature:
Understanding decomposition temperature is critical for safety for several reasons:
According to GHS and various regional regulations (EU CLP, US OSHA HazCom, etc.), decomposition temperature should be indicated in Section 9 of the Safety Data Sheet as part of the description of basic physical and chemical properties. This information is particularly important for thermally unstable substances.
For self-reactive substances and organic peroxides, the Self-Accelerating Decomposition Temperature (SADT) is a critical parameter for classification and transportation requirements under regulations such as UN Recommendations on the Transport of Dangerous Goods, ADR, IMDG, and IATA.
When reporting decomposition temperature in an SDS: