Degassing, also known as degasification, is the removal of dissolved gases from liquids, especially water or aqueous solutions. There are numerous methods for removing gases from liquids.
Gases are removed for various reasons. Chemists remove gases from solvents when the compounds they are working on are possibly air- or oxygen-sensitive (air-free technique), or when bubble formation at solid-liquid interfaces becomes a problem. The formation of gas bubbles when a liquid is frozen can also be undesirable, necessitating degassing beforehand.
The solubility of gas obeys Henry's law, that is, the amount of a dissolved gas in a liquid is proportional to its partial pressure. Therefore, placing a solution under reduced pressure makes the dissolved gas less soluble. Sonication and stirring under reduced pressure can usually enhance the efficiency. This technique is often referred to as vacuum degasification. Specialized vacuum chambers, called vacuum degassers, are used to degas materials through pressure reduction.
Generally speaking, an aqueous solvent dissolves less gas at higher temperature, and vice versa for organic solvents (provided the solute and solvent do not react). Consequently, heating an aqueous solution can expel dissolved gas, whereas cooling an organic solution has the same effect. Ultrasonication and stirring during thermal regulation are also effective. This method needs no special apparatus and is easy to conduct. In some cases, however, the solvent and the solute decompose, react with each other, or evaporate at high temperature, and the rate of removal is less reproducible.
Membrane degasification
Gas-liquid separation membranes allow gas but not liquid to pass through. Flowing a solution inside a gas-liquid separation membrane and evacuating outside makes the dissolved gas go out through the membrane. This method has the advantage of being able to prevent redissolution of the gas, so it is used to produce very pure solvents. New applications are in inkjet systems where gas in the ink forms bubbles that degrade print quality, a degassing unit is placed prior to the print head to remove gas and prevent the buildup of bubbles keeping good jetting and print quality.
The above three methods are used to remove all dissolved gases. Below are methods for more selective removal.
Ultrasonic degassing
Ultrasonic liquid processors are a commonly used method for removing dissolved gasses and/or entrained gas bubbles from various of liquids. The advantage of this method is that that ultrasonic degassing can be done in a continuous-flow mode, which makes it suitable for commercial-scale production.[1][2][3]
Bubbling a solution with a high-purity (typically inert) gas can pull out undesired (typically reactive) dissolved gases such as oxygen and carbon dioxide. Nitrogen, argon, helium and other inert gases are commonly used. To maximize this process called sparging, the solution is stirred vigorously and bubbled for a long time. Because helium is not very soluble in most liquids, it is particularly useful to reduce the risk of bubbles in high-performance liquid chromatography (HPLC) systems.
Addition of reductant
If oxygen should be removed, the addition of reductants is sometimes effective. For example, especially in the field of electrochemistry, ammonium sulfite is frequently used as a reductant because it reacts with oxygen to form sulfate ions. Although this method can be applied only to oxygen and involves the risk of reduction of the solute, the dissolved oxygen is almost totally eliminated. The ketyl radical from sodium and benzophenone can also be used for removing both oxygen and water from inert solvents such as hydrocarbons and ethers; the degassed solvent can be separated by distillation. The latter method is particularly useful because a high concentration of ketyl radical generates a deep blue colour, indicating the solvent is fully degassed.
Freeze-pump-thaw cycling
In this laboratory-scale technique, the fluid to be degassed is placed in a Schlenk flask and flash-frozen, usually with liquid nitrogen. Next a vacuum is applied, perhaps to attain a vacuum of 1 mm Hg (for illustrative purposes). The flask is sealed from the vacuum source, and the frozen solvent is allowed to thaw. Often, bubbles appears upon melting. The process is typically repeated a total of three cycles.[4] The degree of degassing is expressed by the equation (1/760)3 for the case of initial pressure being 760 mm Hg, the vacuum being 1 mm Hg, and the total number of cycles being three.[5]
Degassing wine
Yeast uses sugar to produce alcohol and carbon dioxide. In winemaking, carbon dioxide is an undesired by-product for most wines. If the wine is bottled quickly after fermentation, it is important to degas the wine before bottling.
Wineries can skip the degassing process if they age their wines prior to bottling. Storing the wines in steel or oak barrels for months and sometimes years allows gases to be released from the wine and escape into the air through air-locks.
Oil degassing
For separation of gaseous hydrocarbons from crude oil, see Oil refinery.
The most efficient method of industrial oil degassing is vacuum processing, which removes air and water solved in the oil.[6] This can be achieved by:
spraying of oil in large vacuum chambers;
distributing the oil into a thin layer over special surfaces (spiral rings, Raschig rings etc) in vacuum chambers.
Under vacuum, an equilibrium between the content of moisture and air (solved gases) in the liquid and gaseous phase is achieved. The equilibrium depends on the temperature and the residual pressure. The lower that pressure, the faster and more efficiently are water and gas removed.
^Zhang Yong, Zhai Wei-Dong (2015). "Shallow-ocean methane leakage and degassing to the atmosphere: triggered by offshore oil-gas and methane hydrate explorations". Frontiers in Marine Science. 2: 34. doi:10.3389/fmars.2015.00034.{{cite journal}}: CS1 maint: uses authors parameter (link)
^Giancarlo Ciotoli, Monia Procesi, Giuseppe Etiope, Umberto Fracassi & Guido Ventura (2020). "Influence of tectonics on global scale distribution of geological methane emissions". Nature Communications. 11 (1): 2305. Bibcode:2020NatCo..11.2305C. doi:10.1038/s41467-020-16229-1. PMC7210894. PMID 32385247.{{cite journal}}: CS1 maint: uses authors parameter (link)
January 08, 2023
degassing, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, november, 2016, . This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Degassing news newspapers books scholar JSTOR November 2016 Learn how and when to remove this template message Degassing also known as degasification is the removal of dissolved gases from liquids especially water or aqueous solutions There are numerous methods for removing gases from liquids Gases are removed for various reasons Chemists remove gases from solvents when the compounds they are working on are possibly air or oxygen sensitive air free technique or when bubble formation at solid liquid interfaces becomes a problem The formation of gas bubbles when a liquid is frozen can also be undesirable necessitating degassing beforehand Contents 1 Pressure reduction 2 Thermal regulation 3 Membrane degasification 4 Ultrasonic degassing 5 Sparging by inert gas 6 Addition of reductant 7 Freeze pump thaw cycling 8 Degassing wine 9 Oil degassing 10 Unintended degassing 11 See also 12 ReferencesPressure reduction EditThe solubility of gas obeys Henry s law that is the amount of a dissolved gas in a liquid is proportional to its partial pressure Therefore placing a solution under reduced pressure makes the dissolved gas less soluble Sonication and stirring under reduced pressure can usually enhance the efficiency This technique is often referred to as vacuum degasification Specialized vacuum chambers called vacuum degassers are used to degas materials through pressure reduction Thermal regulation EditSee also Deaerator Generally speaking an aqueous solvent dissolves less gas at higher temperature and vice versa for organic solvents provided the solute and solvent do not react Consequently heating an aqueous solution can expel dissolved gas whereas cooling an organic solution has the same effect Ultrasonication and stirring during thermal regulation are also effective This method needs no special apparatus and is easy to conduct In some cases however the solvent and the solute decompose react with each other or evaporate at high temperature and the rate of removal is less reproducible Membrane degasification EditGas liquid separation membranes allow gas but not liquid to pass through Flowing a solution inside a gas liquid separation membrane and evacuating outside makes the dissolved gas go out through the membrane This method has the advantage of being able to prevent redissolution of the gas so it is used to produce very pure solvents New applications are in inkjet systems where gas in the ink forms bubbles that degrade print quality a degassing unit is placed prior to the print head to remove gas and prevent the buildup of bubbles keeping good jetting and print quality The above three methods are used to remove all dissolved gases Below are methods for more selective removal Ultrasonic degassing EditUltrasonic liquid processors are a commonly used method for removing dissolved gasses and or entrained gas bubbles from various of liquids The advantage of this method is that that ultrasonic degassing can be done in a continuous flow mode which makes it suitable for commercial scale production 1 2 3 Sparging by inert gas EditSee also Sparging chemistry Bubbling a solution with a high purity typically inert gas can pull out undesired typically reactive dissolved gases such as oxygen and carbon dioxide Nitrogen argon helium and other inert gases are commonly used To maximize this process called sparging the solution is stirred vigorously and bubbled for a long time Because helium is not very soluble in most liquids it is particularly useful to reduce the risk of bubbles in high performance liquid chromatography HPLC systems Addition of reductant EditIf oxygen should be removed the addition of reductants is sometimes effective For example especially in the field of electrochemistry ammonium sulfite is frequently used as a reductant because it reacts with oxygen to form sulfate ions Although this method can be applied only to oxygen and involves the risk of reduction of the solute the dissolved oxygen is almost totally eliminated The ketyl radical from sodium and benzophenone can also be used for removing both oxygen and water from inert solvents such as hydrocarbons and ethers the degassed solvent can be separated by distillation The latter method is particularly useful because a high concentration of ketyl radical generates a deep blue colour indicating the solvent is fully degassed Freeze pump thaw cycling EditIn this laboratory scale technique the fluid to be degassed is placed in a Schlenk flask and flash frozen usually with liquid nitrogen Next a vacuum is applied perhaps to attain a vacuum of 1 mm Hg for illustrative purposes The flask is sealed from the vacuum source and the frozen solvent is allowed to thaw Often bubbles appears upon melting The process is typically repeated a total of three cycles 4 The degree of degassing is expressed by the equation 1 760 3 for the case of initial pressure being 760 mm Hg the vacuum being 1 mm Hg and the total number of cycles being three 5 Degassing wine EditYeast uses sugar to produce alcohol and carbon dioxide In winemaking carbon dioxide is an undesired by product for most wines If the wine is bottled quickly after fermentation it is important to degas the wine before bottling Wineries can skip the degassing process if they age their wines prior to bottling Storing the wines in steel or oak barrels for months and sometimes years allows gases to be released from the wine and escape into the air through air locks Oil degassing EditFor separation of gaseous hydrocarbons from crude oil see Oil refinery The most efficient method of industrial oil degassing is vacuum processing which removes air and water solved in the oil 6 This can be achieved by spraying of oil in large vacuum chambers distributing the oil into a thin layer over special surfaces spiral rings Raschig rings etc in vacuum chambers Under vacuum an equilibrium between the content of moisture and air solved gases in the liquid and gaseous phase is achieved The equilibrium depends on the temperature and the residual pressure The lower that pressure the faster and more efficiently are water and gas removed Unintended degassing EditUnintended degassing can happen for various reasons such as accidental release of methane CH4 from the seabed during human activity such as underwater exploration by the energy industry Natural processes such as tectonic plate movement can also contribute to methane release from the ocean floor In both cases the volume of CH4 released can be a significant contributor to climate change 7 8 See also EditDegas conductivity Degassed water Limnic eruption Outgassing includes geological and volcanic emissions Volcanic gasReferences Edit Degassing of Liquids https www sonomechanics com liquid degassing deaeration European publication server Degassing electrorheological fluid Freeze Pump Thaw Degassing of Liquids PDF University of Washington Duward F Shriver and M A Drezdzon The Manipulation of Air Sensitive Compounds 1986 J Wiley and Sons New York ISBN 0 471 86773 X D J Hucknall 1991 Vacuum Technology and Applications Oxford Butterworth Heinemann Ltd ISBN 0 7506 1145 6 Zhang Yong Zhai Wei Dong 2015 Shallow ocean methane leakage and degassing to the atmosphere triggered by offshore oil gas and methane hydrate explorations Frontiers in Marine Science 2 34 doi 10 3389 fmars 2015 00034 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint uses authors parameter link Giancarlo Ciotoli Monia Procesi Giuseppe Etiope Umberto Fracassi amp Guido Ventura 2020 Influence of tectonics on global scale distribution of geological methane emissions Nature Communications 11 1 2305 Bibcode 2020NatCo 11 2305C doi 10 1038 s41467 020 16229 1 PMC 7210894 PMID 32385247 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint uses authors parameter link Retrieved from https en wikipedia org w index php title Degassing amp oldid 1115324020, wikipedia, wiki, book, books, library,
