Ethanolamine: Properties, Production, Applications, and Safety

Ethanolamine, also known as monoethanolamine (MEA), is an organic chemical compound that serves as both an alcohol and an amine. With the chemical formula C₂H₇NO, ethanolamine is a colorless, viscous liquid at room temperature and plays a vital role in a wide range of industrial and commercial applications.

It is widely used in the production of detergents, emulsifiers, pharmaceuticals, chemical intermediates, and as a gas treatment agent for removing acid gases. Thanks to its unique chemical structure and reactivity, ethanolamine has become a cornerstone compound in numerous sectors including agriculture, petrochemicals, and consumer goods.

Chemical Structure and Properties

IUPAC Name: 2-Aminoethanol
Common Name: Ethanolamine
Chemical Formula: C₂H₇NO
Molecular Weight: 61.08 g/mol
CAS Number: 141-43-5
Appearance: Colorless to pale yellow viscous liquid
Odor: Slight ammonia-like
Melting Point: 10.3 °C (50.5 °F)
Boiling Point: 170 °C (338 °F)
Density: 1.018 g/cm³
Solubility: Completely miscible with water, alcohol, and acetone

Ethanolamine is a hydroxyalkylamine, featuring both a hydroxyl group (-OH) and an amine group (-NH₂) on a two-carbon backbone. This dual functionality makes it highly reactive and useful in both nucleophilic and hydrogen-bonding chemical environments.

Production and Manufacturing

1. Industrial Synthesis

The most common industrial method for producing ethanolamine is through the reaction of ethylene oxide with ammonia:

mathematica

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C₂H₄O + NH₃ → C₂H₇NO (Ethanolamine)

This reaction also produces diethanolamine (DEA) and triethanolamine (TEA) as by-products depending on the stoichiometry and conditions of the reaction.

2. Separation Process

After synthesis, the mixture is distilled to separate the three ethanolamines:

Monoethanolamine (MEA) – primary product
Diethanolamine (DEA) – secondary amine
Triethanolamine (TEA) – tertiary amine

Each has distinct chemical properties and applications.

Applications of Ethanolamine

Ethanolamine is one of the most versatile chemicals in industry. Its applications are diverse and widespread:

1. Gas Treatment (Amine Scrubbing)

MEA is extensively used in the removal of acidic gases like carbon dioxide (CO₂) and hydrogen sulfide (H₂S) from natural gas and refinery process streams. This process is known as amine scrubbing or gas sweetening.

2. Surfactants and Detergents

Due to its amphiphilic nature (having both polar and non-polar properties), ethanolamine is used in the manufacture of anionic and nonionic surfactants for:

Shampoos
Soaps
Household cleaners
Dishwashing liquids

3. Pharmaceuticals and Cosmetics

Ethanolamine serves as a pH buffer and emulsifying agent in cosmetic formulations and pharmaceutical products. It is often found in:

Skin creams
Lotions
Shaving products
Medicinal ointments

4. Agricultural Chemicals

Ethanolamine is used as a base in herbicide and pesticide formulations, improving solubility and delivery. It is often neutralized with acid herbicides to form stable, water-soluble salts.

5. Cement and Concrete Additives

As a grinding aid and setting time controller, ethanolamine improves the production efficiency of cement and concrete, making it useful in the construction industry.

6. Textile and Leather Industry

Used in dyeing processes and as a softening agent for leather and textiles.

7. Chemical Intermediates

Ethanolamine is used in the production of:

Morpholine (used in corrosion inhibitors and rubber chemicals)
Ethylene amines
Emulsifiers
Plasticizers

Health and Safety Considerations

1. Toxicity

While ethanolamine is generally considered low in acute toxicity, it can cause irritation to the skin, eyes, and respiratory tract:

Inhalation: May cause respiratory discomfort and coughing
Skin Contact: Can cause redness, irritation, and chemical burns on prolonged exposure
Eye Contact: Severe irritation or even eye damage
Ingestion: Harmful, may lead to gastrointestinal irritation or systemic toxicity

Chronic exposure can affect the liver and kidneys. Workers handling ethanolamine should use protective gloves, eye protection, and work in well-ventilated areas.

2. Flammability and Reactivity

Flash point: ~85 °C (185 °F) – combustible but not highly flammable
Reactivity: Can react with acids, oxidizing agents, and some metals (e.g., aluminum)

3. Environmental Impact

Ethanolamine is biodegradable and generally considered to pose low environmental risk when handled properly. However, spills in large quantities can affect aquatic organisms due to changes in pH and oxygen levels.

Regulatory bodies like the EPA, OSHA, and REACH have established guidelines for the safe handling and disposal of ethanolamine.

Global Market and Economics

The global demand for ethanolamine continues to grow due to its wide range of industrial applications. Key market sectors include:

Oil & gas (for gas treatment)
Consumer goods (personal care, cleaning products)
Agriculture (herbicides)
Manufacturing and construction

Major producers include:

Dow Chemical Company
BASF
INEOS Oxide
SABIC
Eastman Chemical

The compound is typically sold in 99% purity and shipped in steel drums or bulk containers, often stabilized with inhibitors to prevent degradation.

Future Trends and Research

1. Green Chemistry and Bio-Based Alternatives

With the shift toward sustainable chemistry, research is exploring bio-based production of ethanolamines from bio-ethylene oxide or amino alcohols derived from plant biomass. This could significantly reduce the carbon footprint associated with fossil fuel-based production.

2. Advanced Gas Treatment Applications

Innovations in amine scrubbing are improving the energy efficiency and selectivity of CO₂ capture, especially for carbon capture and storage (CCS) technologies in response to climate change.

3. New Derivatives and Functional Materials

Ethanolamine derivatives are being studied for use in advanced polymers, coatings, and materials with specialized electronic, optical, or antimicrobial properties.

Conclusion

Ethanolamine is a highly functional and essential chemical compound with broad utility across multiple industries, from cosmetics and agriculture to petrochemical processing and pharmaceuticals. While it offers substantial benefits due to its reactivity and dual functional groups, responsible handling and environmental stewardship are essential given its potential health hazards.

With growing industrial demand and increased emphasis on sustainability, ethanolamine is poised to remain a cornerstone chemical in the global economy—especially as cleaner production methods and innovative applications continue to evolve.

Ethanolamine