Absorption (chemistry): Difference between revisions
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In [[chemistry]], '''absorption''' is a process by which a substance incorporated in one state is transferred into | {{Dambigbox|Absorption (chemistry) |Absorption}} | ||
In [[chemistry]], '''absorption''' is a process by which a substance incorporated in one [[Matter#phases|state]] is transferred into another substance of a different state (e.g., [[gas]]es being absorbed by a [[liquid]] or liquids being absorbed by a [[solid]]). As an industrial process, the most commonly encountered use of absorption is for the separation and/or purification of a gas mixture by the absorption of part of the mixture in a [[solvent]]. | |||
Another chemistry process is adsorption which is the physical adherence or bonding of substances on the surface of another substance and it is not to be confused with absorption. In essence, absorption involves substances in one state being incorporated into the bulk volume of another substance in a different state, whereas adsorption involves substances being adhered to the surface of another substance. | |||
==Types of absorption== | ==Types of absorption== | ||
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Absorption may be either a physical or a chemical process:<ref>[http://www.ceas.manchester.ac.uk/research/centres/centreforprocessintegration/topics/energyefficiency/absorptionsystems/ Physical and Chemical Absorption Systems] Dr. Megan Jobson, School of Chemical Engineering and Analytical Science, [[University of Manchester]], [[England]].</ref> | Absorption may be either a physical or a chemical process:<ref>[http://www.ceas.manchester.ac.uk/research/centres/centreforprocessintegration/topics/energyefficiency/absorptionsystems/ Physical and Chemical Absorption Systems] Dr. Megan Jobson, School of Chemical Engineering and Analytical Science, [[University of Manchester]], [[England]].</ref> | ||
'''''Physical absorption''''' of a gas or part of a gas mixture in a liquid solvent involves the mass transfer that occurs at the interface between the gas and the liquid and the rate at which the gas diffuses into the liquid. | '''''Physical absorption''''' of a gas or part of a gas mixture in a liquid solvent involves the mass transfer that occurs at the interface between the gas and the liquid and the rate at which the gas diffuses into the liquid. Physical absorption of gases in a liquid solvent depends on the following parameters: [[solubility]] of the gases and the [[pressure]] and [[temperature]] conditions. | ||
:An example of physical absorption of a gas into a liquid is the absorption of [[ammonia]] (NH<sub>3</sub>) into [[water]] (H<sub>2</sub>O). Some other examples are: the [[glycol dehydration]] of raw [[natural gas]] by absorption of the water vapor contained in the natural gas into liquid [[glycol]]s, and the the separation of low [[molecular weight]] [[gas]]es such as [[propane]] (C<sub>3</sub>H<sub>8</sub>) and [[butane]] (C<sub>4</sub>H<sub>10</sub>) from a [[hydrocarbon]] gas mixture of [[methane]] (CH<sub>4</sub>), [[ethane]] (C<sub>2</sub>H<sub>6</sub>), propane and butane by absorbing the propane and butane in a solvent that is a mixture of much higher molecular weight hydrocarbon liquids. | |||
'''''Chemical absorption''''' or '''''reactive absorption''''' involves a [[chemical reaction]] between the substance being absorbed and the absorbing medium. In some cases, it occurs in combination with physical absorption. Chemical absorption depends upon the [[stoichiometry]] of the reaction and the [[concentration]] of the reactants. | |||
:An example of chemical absorption is the purification of natural gas by passing the natural gas through an aqueous solution of an [[ethanolamine]] in which any [[acid gas]]es, such as [[hydrogen sulphide]] (H<sub>2</sub>S) and [[carbon dioxide]]] (CO<sub>2</sub>), are removed from the natural gas by reacting with the ethanolamine (see the [[Amine gas treating]] and [[Natural gas processing]] articles). Another example is the removal of any hydrogen sulfide gas from the feedstock to an [[ammonia production]] plant by contacting the hydrogen sulfide with a bed of solid [[zinc oxide]] (ZnO) with which it reacts to form solid [[zinc sulfide]] (ZnS) (see the [[Ammonia production]] article). | |||
Either type of absorption may be reversible or irreversible. The physical absorption of small amounts of [[oxygen]] in water can be reversed by heating the water. The reactive absorption of acid gases by an aqueous solution of ethanolamine can be reversed by distillation of the ethanolamine solution. However, the reactive absorption of hydrogen sulfide by zinc oxide cannot be reversed. The reactive absorption of carbon dioxide by an aqueous solution of [[sodium hydroxide]] (NaOH) is also irreversible and there not as economically acceptable as the reversible reactive absorption of carbon dioxide by ethanolamine solutions. | |||
==References== | ==References== | ||
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Latest revision as of 16:00, 5 July 2024
In chemistry, absorption is a process by which a substance incorporated in one state is transferred into another substance of a different state (e.g., gases being absorbed by a liquid or liquids being absorbed by a solid). As an industrial process, the most commonly encountered use of absorption is for the separation and/or purification of a gas mixture by the absorption of part of the mixture in a solvent.
Another chemistry process is adsorption which is the physical adherence or bonding of substances on the surface of another substance and it is not to be confused with absorption. In essence, absorption involves substances in one state being incorporated into the bulk volume of another substance in a different state, whereas adsorption involves substances being adhered to the surface of another substance.
Types of absorption
Absorption may be either a physical or a chemical process:[1]
Physical absorption of a gas or part of a gas mixture in a liquid solvent involves the mass transfer that occurs at the interface between the gas and the liquid and the rate at which the gas diffuses into the liquid. Physical absorption of gases in a liquid solvent depends on the following parameters: solubility of the gases and the pressure and temperature conditions.
- An example of physical absorption of a gas into a liquid is the absorption of ammonia (NH3) into water (H2O). Some other examples are: the glycol dehydration of raw natural gas by absorption of the water vapor contained in the natural gas into liquid glycols, and the the separation of low molecular weight gases such as propane (C3H8) and butane (C4H10) from a hydrocarbon gas mixture of methane (CH4), ethane (C2H6), propane and butane by absorbing the propane and butane in a solvent that is a mixture of much higher molecular weight hydrocarbon liquids.
Chemical absorption or reactive absorption involves a chemical reaction between the substance being absorbed and the absorbing medium. In some cases, it occurs in combination with physical absorption. Chemical absorption depends upon the stoichiometry of the reaction and the concentration of the reactants.
- An example of chemical absorption is the purification of natural gas by passing the natural gas through an aqueous solution of an ethanolamine in which any acid gases, such as hydrogen sulphide (H2S) and carbon dioxide] (CO2), are removed from the natural gas by reacting with the ethanolamine (see the Amine gas treating and Natural gas processing articles). Another example is the removal of any hydrogen sulfide gas from the feedstock to an ammonia production plant by contacting the hydrogen sulfide with a bed of solid zinc oxide (ZnO) with which it reacts to form solid zinc sulfide (ZnS) (see the Ammonia production article).
Either type of absorption may be reversible or irreversible. The physical absorption of small amounts of oxygen in water can be reversed by heating the water. The reactive absorption of acid gases by an aqueous solution of ethanolamine can be reversed by distillation of the ethanolamine solution. However, the reactive absorption of hydrogen sulfide by zinc oxide cannot be reversed. The reactive absorption of carbon dioxide by an aqueous solution of sodium hydroxide (NaOH) is also irreversible and there not as economically acceptable as the reversible reactive absorption of carbon dioxide by ethanolamine solutions.
References
- ↑ Physical and Chemical Absorption Systems Dr. Megan Jobson, School of Chemical Engineering and Analytical Science, University of Manchester, England.