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Superheated water

February 04, 2023

Superheated water is liquid water under pressure at temperatures between the usual boiling point, 100 °C (212 °F) and the critical temperature, 374 °C (705 °F). It is also known as "subcritical water" or "pressurized hot water". Superheated water is stable because of overpressure that raises the boiling point, or by heating it in a sealed vessel with a headspace, where the liquid water is in equilibrium with vapour at the saturated vapor pressure. This is distinct from the use of the term superheating to refer to water at atmospheric pressure above its normal boiling point, which has not boiled due to a lack of nucleation sites (sometimes experienced by heating liquids in a microwave).

Pressure cookers produce superheated water, which cooks the food more rapidly than boiling water.

Many of water's anomalous properties are due to very strong hydrogen bonding. Over the superheated temperature range the hydrogen bonds break, changing the properties more than usually expected by increasing temperature alone. Water becomes less polar and behaves more like an organic solvent such as methanol or ethanol. Solubility of organic materials and gases increases by several orders of magnitude and the water itself can act as a solvent, reagent, and catalyst in industrial and analytical applications, including extraction, chemical reactions and cleaning.

Change of properties with temperature

All materials change with temperature, but superheated water exhibits greater changes than would be expected from temperature considerations alone. Viscosity and surface tension of water drop and diffusivity increases with increasing temperature. [1]Self-ionization of water increases with temperature, and the pKw of water at 250 °C is closer to 11 than the more familiar 14 at 25 °C. This means the concentration of hydronium ion (H
3O+
) and the concentration of hydroxide (OH
) are increased while the pH remains neutral. Specific heat capacity at constant pressure also increases with temperature, from 4.187 kJ/kg at 25 °C to 8.138 kJ/kg at 350 °C. A significant effect on the behaviour of water at high temperatures is decreased dielectric constant (relative permittivity).[2]

Explanation of anomalous behaviour

Water is a polar molecule, where the centers of positive and negative charge are separated; so molecules will align with an electric field. The extensive hydrogen bonded network in water tends to oppose this alignment, and the degree of alignment is measured by the relative permittivity. Water has a high relative permittivity of about 80 at room temperature; because polarity shifts are rapidly transmitted through shifts in orientation of the linked hydrogen bonds. This allows water to dissolve salts, as the attractive electric field between ions is reduced by about 80–fold.[1] Thermal motion of the molecules disrupts the hydrogen bonding network as temperature increases; so relative permittivity decreases with temperature to about 7 at the critical temperature. At 205 °C the relative permittivity falls to 33, the same as methanol at room temperature. Thus water behaves like a water–methanol mixture between 100 °C and 200 °C. Disruption of extended hydrogen bonding allows molecules to move more freely (viscosity, diffusion and surface tension effects), and extra energy must be supplied to break the bonds (increased heat capacity).

Solubility

Organic compounds

Organic molecules often show a dramatic increase in solubility with temperature, partly because of the polarity changes described above, and also because the solubility of sparingly soluble materials tends to increase with temperature as they have a high enthalpy of solution. Thus materials generally considered "insoluble" can become soluble in superheated water. E.g., the solubility of PAHs is increased by 5 orders of magnitude from 25 °C to 225 °C[3] and naphthalene, for example, forms a 10% wt solution in water at 270 °C, and the solubility of the pesticide chlorothalonil with temperature is shown in the table below.[2]

Solubility of Chlorothalonil in Water
T (°C) Mole Fraction
50 5.41 x 10−8
100 1.8 x 10−6
150 6.43 x 10−5
200 1.58 x 10−3

Thus superheated water can be used to process many organic compounds with significant environmental benefits compared to the use of conventional organic solvents.

Salts

Despite the reduction in relative permittivity, many salts remain soluble in superheated water until the critical point is approached. Sodium chloride, for example, dissolves at 37 wt% at 300 °C[4] As the critical point is approached, solubility drops markedly to a few ppm, and salts are hardly soluble in supercritical water. Some salts show a reduction in solubility with temperature, but this behaviour is less common.

Gases

The solubility of gases in water is usually thought to decrease with temperature, but this only occurs to a certain temperature, before increasing again. For nitrogen, this minimum is 74 °C and for oxygen it is 94 °C[5] Gases are soluble in superheated water at elevated pressures. Above the critical temperature, water is completely miscible with all gasses. The increasing solubility of oxygen in particular allows superheated water to be used for wet oxidation processes.

Corrosion

Superheated water can be more corrosive than water at ordinary temperatures, and at temperatures above 300 °C special corrosion resistant alloys may be required, depending on other dissolved components. Continuous use of carbon steel pipes for 20 years at 282 °C has been reported without significant corrosion,[6] and stainless steel cells showed only slight deterioration after 40–50 uses at temperatures up to 350 °C.[7] The degree of corrosion that can be tolerated depends on the use, and even corrosion resistant alloys can fail eventually. Corrosion of an Inconel U-tube in a heat exchanger was blamed for an accident at a nuclear power station.[8] Therefore, for occasional or experimental use, ordinary grades of stainless steel are probably adequate with continuous monitoring, but for critical applications and difficult to service parts, extra care needs to be taken in materials selection.

Effect of pressure

At temperatures below 300 °C water is fairly incompressible, which means that pressure has little effect on the physical properties of water, provided it is sufficient to maintain a liquid state. This pressure is given by the saturated vapour pressure, and can be looked up in steam tables, or calculated.[9] As a guide, the saturated vapour pressure at 121 °C is 200 kPa, 150 °C is 470 kPa, and 200 °C is 1,550 kPa. The critical point is 21.7 MPa at a temperature of 374 °C, above which water is supercritical rather than superheated. Above about 300 °C, water starts to behave as a near-critical liquid, and physical properties such as density start to change more significantly with pressure. However, higher pressures increase the rate of extractions using superheated water below 300 °C. This could be due to effects on the substrate, particularly plant materials, rather than changing water properties.

Energy requirements

The energy required to heat water is significantly lower than that needed to vaporize it, for example for steam distillation[10] and the energy is easier to recycle using heat exchangers. The energy requirements can be calculated from steam tables. For example, to heat water from 25 °C to steam at 250 °C at 1 atm requires 2869 kJ/kg. To heat water at 25 °C to liquid water at 250 °C at 5 MPa requires only 976 kJ/kg. It is also possible to recover much of the heat (say 75%) from superheated water, and therefore energy use for superheated water extraction is less than one sixth that needed for steam distillation. This also means that the energy contained in superheated water is insufficient to vaporise the water on decompression. In the above example, only 30% of the water would be converted to vapour on decompression from 5 MPa to atmospheric pressure.[2]

Extraction

Extraction using superheated water tends to be fast because diffusion rates increase with temperature. Organic materials tend to increase in solubility with temperature, but not all at the same rate. For example, in extraction of essential oils from rosemary[11] and coriander,[12] the more valuable oxygenated terpenes were extracted much faster than the hydrocarbons. Therefore, extraction with superheated water can be both selective and rapid, and has been used to fractionate diesel and woodsmoke particulates.[13] Superheated water is being used commercially to extract starch material from marsh mallow root for skincare applications[14] and to remove low levels of metals from a high-temperature resistant polymer.[15][16]

For analytical purposes, superheated water can replace organic solvents in many applications, for example extraction of PAHs from soils[17] and can also be used on a large scale to remediate contaminated soils, by either extraction alone or extraction linked to supercritical or wet oxidation.[18]

Reactions

Superheated water, along with supercritical water, has been used to oxidise hazardous material in the wet oxidation process. Organic compounds are rapidly oxidised without the production of toxic materials sometimes produced by combustion. However, when the oxygen levels are lower, organic compounds can be quite stable in superheated water. As the concentration of hydronium (H
3O+
) and hydroxide (OH
) ions are 100 times larger than in water at 25 °C, superheated water can act as a stronger acid and a stronger base, and many different types of reaction can be carried out. An example of a selective reaction is oxidation of ethylbenzene to acetophenone, with no evidence of formation of phenylethanoic acid, or of pyrolysis products.[7] Several different types of reaction in which water was behaving as reactant, catalyst and solvent were described by Katritzky et al.[19]Triglycerides can be hydrolysed to free fatty acids and glycerol by superheated water at 275 °C,[20] which can be the first in a two-stage process to make biodiesel. [21] Superheated water can be used to chemically convert organic material into fuel products. This is known by several terms, including direct hydrothermal liquefaction,[22] and hydrous pyrolysis. A few commercial scale applications exist. Thermal depolymerization or thermal conversion (TCC) uses superheated water at about 250 °C to convert turkey waste into a light fuel oil and is said to process 200 tons of low grade waste into fuel oil a day. [23] The initial product from the hydrolysis reaction is de-watered and further processed by dry cracking at 500 °C. The "SlurryCarb" process operated by EnerTech uses similar technology to decarboxylate wet solid biowaste, which can then be physically dewatered and used as a solid fuel called E-Fuel. The plant at Rialto is said to be able to process 683 tons of waste per day. [24] The HTU or Hydro Thermal Upgrading process appears similar to the first stage of the TCC process. A demonstration plant is due to start up in The Netherlands said to be capable of processing 64 tons of biomass (dry basis) per day into oil.[25]

Chromatography

Reverse phased HPLC often uses methanol–water mixtures as the mobile phase. Since the polarity of water spans the same range from 25 to 205 °C, a temperature gradient can be used to effect similar separations, for example of phenols. [26] The use of water allows the use of the flame ionisation detector (FID), which gives mass sensitive output for nearly all organic compounds. [27] The maximum temperature is limited to that at which the stationary phase is stable. C18 bonded phases which are common in HPLC seem to be stable at temperatures up to 200 °C, far above that of pure silica, and polymeric styrene–divinylbenzene phases offer similar temperature stability. [28] Water is also compatible with use of an ultraviolet detector down to a wavelength of 190 nm.

See also

References

  1. ^ a b Chaplin, Martin (2008-01-04). . London South Bank University. Archived from the original on 2007-10-17.
  2. ^ a b c Clifford, A.A. (2008-01-04). "Changes of water properties with temperature". from the original on 2008-02-13. Retrieved 2008-01-15.
  3. ^ Miller, D.J.; Hawthorne, S.B; Gizir, A.M.; Clifford, A.A. (1998). "Solubility of polycyclic aromatic hydrocarbons in subcritical water from 298 K to 498 K". Journal of Chemical & Engineering Data. 43 (6): 1043–1047. doi:10.1021/je980094g.
  4. ^ Letcher, Trevor M. (2007). Thermodynamics, solubility and environmental issues. Elsevier. p. 60. ISBN 978-0-444-52707-3.
  5. ^ "Guideline on the Henry's constant and vapor-liquid distribution constant for gases in H2O and D2O at high temperatures" (PDF). International Association for the Properties of Water and Steam. September 2004. Retrieved 2008-01-14.
  6. ^ Burnham, Robert N.; et al. (2001). (PDF). Panametrix. Archived from the original (PDF) on 2007-10-27.
  7. ^ a b Holliday, Russel L.; Yong, B.Y.M.; Kolis, J.W. (1998). "Organic synthesis in subcritical water. Oxidation of alkyl aromatics". Journal of Supercritical Fluids. 12 (3): 255–260. doi:10.1016/S0896-8446(98)00084-9.
  8. ^ "Corrosion seen as A-plant accident cause". New York Times. 2000-03-03. Retrieved 2008-01-15.
  9. ^ Clifford, A.A. (2007-12-04). "Superheated water: more details". from the original on 2008-02-13. Retrieved 2008-01-12.
  10. ^ King, Jerry W. . Los Alamos National Laboratories. Archived from the original on 2008-07-25. Retrieved 2008-01-12.
  11. ^ Basile, A.; et al. (1998). "Extraction of Rosemary by Superheated Water". J. Agric. Food Chem. 46 (12): 5205–5209. doi:10.1021/jf980437e.
  12. ^ Eikani, M.H.; Golmohammad, F.; Rowshanzamir, S. (2007). "Subcritical water extraction of essential oils from coriander seeds (Corianrum sativum L.)" (PDF). Journal of Food Engineering. 80 (2): 735–740. doi:10.1016/j.jfoodeng.2006.05.015. Retrieved 2008-01-04.
  13. ^ Kubatova, Alena; Mayia Fernandez; Steven Hawthorne (2002-04-09). (PDF). PM2.5 and electric power generation: recent findings and implications. Pittsburgh, PA: National Energy Technology Laboratory. Archived from the original (PDF) on 2011-05-29.
  14. ^ (PDF). Newsletter No.8. BBSRC. Spring 2007. Archived from the original (PDF) on 2011-05-17. Retrieved 2008-01-08.
  15. ^ Clifford, A.A. (2007-12-04). "Applications: water and superheated water". from the original on 2008-02-13. Retrieved 2008-01-08.
  16. ^ Clifford, Tony (Nov 5–8, 2006). . 8th International Symposium on Supercritical Fluids. Kyoto, Japan. Archived from the original on 2006-08-23. Retrieved 2008-01-16.
  17. ^ Kipp, Sabine; et al. (July 1998). "Coupling superheated water extraction with enzyme immunoassay for an efficient and fast PAH screening in soil". Talanta. 46 (3): 385–393. doi:10.1016/S0039-9140(97)00404-9. PMID 18967160.
  18. ^ Hartonen, K; Kronholm and Reikkola (2005). Jalkanen, Anneli; Nygren, Pekka (eds.). Sustainable use of renewable natural resources – principles and practice (PDF). Chapter 5.2 Utilisation of high temperature water in the purification of water and soil: University of Helsinki Department of Forest Ecology. ISBN 978-952-10-2817-5.{{cite book}}: CS1 maint: location (link)
  19. ^ Katritzki, A.R.; S. M. Allin; M. Siskin (1996). (PDF). Accounts of Chemical Research. 29 (8): 399–406. doi:10.1021/ar950144w. Archived from the original (PDF) on 2012-12-02. Retrieved 2008-01-14.
  20. ^ King, Jerry W.; Holliday, R.L.; List, G.R. (December 1999). "Hydrolysis of soubean oil in a subcritical water flow reactor". Green Chemistry. 1 (6): 261–264. doi:10.1039/a908861j.
  21. ^ Saka, Shiro; Kusdiana, Dadan. (PDF). Archived from the original (PDF) on 2011-09-10. Retrieved 2008-01-12.
  22. ^ . US Department of Energy. Energy Efficiency and Renewable Energy. 2005-10-13. Archived from the original on 2008-01-03. Retrieved 2008-01-12.
  23. ^ "About TCP Technology". Renewable Environmental Solutions LLC. Retrieved 2008-01-12.
  24. ^ Sforza, Teri (2007-03-14). "New plan replaces sewage sludge fiasco". Orange County Register. Retrieved 2008-01-27.
  25. ^ Goudriaan, Frans; Naber Jaap; van den Berg. "Conversion of Biomass Residues to Transportation Fuels with the HTU Process" (PDF). Retrieved 2019-03-29.
  26. ^ Yarita, Takashi; Nakajima, R.; Shibukawa, M. (February 2003). "Superheated water chromatography of phenols using poly(styrene-divnylbenzene) packings as a stationary phase". Analytical Sciences. 19 (2): 269–272. doi:10.2116/analsci.19.269. PMID 12608758.
  27. ^ Smith, Roger; Young, E.; Sharp, B. (2012). "Liquid chromatography-flame ionisation detection using a nebuliser/spray chamber interface. Part 2. Comparison of functional group responses". Journal of Chromatography A. 1236: 21–27. doi:10.1016/j.chroma.2012.02.035. PMID 22420954.
  28. ^ Smith, R. M.; Burgess, R.J. (1996). "Superheated water – a clean eluent for reverse phase high performance chromatography". Analytical Communications. 33 (9): 327–329. doi:10.1039/AC9963300327.

External links

  • The International Association for the Properties of Water and Steam
  • for vapour pressure and enthalpy of superheated water.

February 04, 2023
superheated, water, liquid, water, under, pressure, temperatures, between, usual, boiling, point, critical, temperature, also, known, subcritical, water, pressurized, water, stable, because, overpressure, that, raises, boiling, point, heating, sealed, vessel, . Superheated water is liquid water under pressure at temperatures between the usual boiling point 100 C 212 F and the critical temperature 374 C 705 F It is also known as subcritical water or pressurized hot water Superheated water is stable because of overpressure that raises the boiling point or by heating it in a sealed vessel with a headspace where the liquid water is in equilibrium with vapour at the saturated vapor pressure This is distinct from the use of the term superheating to refer to water at atmospheric pressure above its normal boiling point which has not boiled due to a lack of nucleation sites sometimes experienced by heating liquids in a microwave Pressure cookers produce superheated water which cooks the food more rapidly than boiling water Many of water s anomalous properties are due to very strong hydrogen bonding Over the superheated temperature range the hydrogen bonds break changing the properties more than usually expected by increasing temperature alone Water becomes less polar and behaves more like an organic solvent such as methanol or ethanol Solubility of organic materials and gases increases by several orders of magnitude and the water itself can act as a solvent reagent and catalyst in industrial and analytical applications including extraction chemical reactions and cleaning Contents 1 Change of properties with temperature 2 Explanation of anomalous behaviour 3 Solubility 3 1 Organic compounds 3 2 Salts 3 3 Gases 4 Corrosion 5 Effect of pressure 6 Energy requirements 7 Extraction 8 Reactions 9 Chromatography 10 See also 11 References 12 External linksChange of properties with temperature EditAll materials change with temperature but superheated water exhibits greater changes than would be expected from temperature considerations alone Viscosity and surface tension of water drop and diffusivity increases with increasing temperature 1 Self ionization of water increases with temperature and the pKw of water at 250 C is closer to 11 than the more familiar 14 at 25 C This means the concentration of hydronium ion H3 O and the concentration of hydroxide OH are increased while the pH remains neutral Specific heat capacity at constant pressure also increases with temperature from 4 187 kJ kg at 25 C to 8 138 kJ kg at 350 C A significant effect on the behaviour of water at high temperatures is decreased dielectric constant relative permittivity 2 Explanation of anomalous behaviour EditWater is a polar molecule where the centers of positive and negative charge are separated so molecules will align with an electric field The extensive hydrogen bonded network in water tends to oppose this alignment and the degree of alignment is measured by the relative permittivity Water has a high relative permittivity of about 80 at room temperature because polarity shifts are rapidly transmitted through shifts in orientation of the linked hydrogen bonds This allows water to dissolve salts as the attractive electric field between ions is reduced by about 80 fold 1 Thermal motion of the molecules disrupts the hydrogen bonding network as temperature increases so relative permittivity decreases with temperature to about 7 at the critical temperature At 205 C the relative permittivity falls to 33 the same as methanol at room temperature Thus water behaves like a water methanol mixture between 100 C and 200 C Disruption of extended hydrogen bonding allows molecules to move more freely viscosity diffusion and surface tension effects and extra energy must be supplied to break the bonds increased heat capacity Solubility EditOrganic compounds Edit Organic molecules often show a dramatic increase in solubility with temperature partly because of the polarity changes described above and also because the solubility of sparingly soluble materials tends to increase with temperature as they have a high enthalpy of solution Thus materials generally considered insoluble can become soluble in superheated water E g the solubility of PAHs is increased by 5 orders of magnitude from 25 C to 225 C 3 and naphthalene for example forms a 10 wt solution in water at 270 C and the solubility of the pesticide chlorothalonil with temperature is shown in the table below 2 Solubility of Chlorothalonil in Water T C Mole Fraction50 5 41 x 10 8100 1 8 x 10 6150 6 43 x 10 5200 1 58 x 10 3Thus superheated water can be used to process many organic compounds with significant environmental benefits compared to the use of conventional organic solvents Salts Edit Despite the reduction in relative permittivity many salts remain soluble in superheated water until the critical point is approached Sodium chloride for example dissolves at 37 wt at 300 C 4 As the critical point is approached solubility drops markedly to a few ppm and salts are hardly soluble in supercritical water Some salts show a reduction in solubility with temperature but this behaviour is less common Gases Edit The solubility of gases in water is usually thought to decrease with temperature but this only occurs to a certain temperature before increasing again For nitrogen this minimum is 74 C and for oxygen it is 94 C 5 Gases are soluble in superheated water at elevated pressures Above the critical temperature water is completely miscible with all gasses The increasing solubility of oxygen in particular allows superheated water to be used for wet oxidation processes Corrosion EditSuperheated water can be more corrosive than water at ordinary temperatures and at temperatures above 300 C special corrosion resistant alloys may be required depending on other dissolved components Continuous use of carbon steel pipes for 20 years at 282 C has been reported without significant corrosion 6 and stainless steel cells showed only slight deterioration after 40 50 uses at temperatures up to 350 C 7 The degree of corrosion that can be tolerated depends on the use and even corrosion resistant alloys can fail eventually Corrosion of an Inconel U tube in a heat exchanger was blamed for an accident at a nuclear power station 8 Therefore for occasional or experimental use ordinary grades of stainless steel are probably adequate with continuous monitoring but for critical applications and difficult to service parts extra care needs to be taken in materials selection Effect of pressure EditAt temperatures below 300 C water is fairly incompressible which means that pressure has little effect on the physical properties of water provided it is sufficient to maintain a liquid state This pressure is given by the saturated vapour pressure and can be looked up in steam tables or calculated 9 As a guide the saturated vapour pressure at 121 C is 200 kPa 150 C is 470 kPa and 200 C is 1 550 kPa The critical point is 21 7 MPa at a temperature of 374 C above which water is supercritical rather than superheated Above about 300 C water starts to behave as a near critical liquid and physical properties such as density start to change more significantly with pressure However higher pressures increase the rate of extractions using superheated water below 300 C This could be due to effects on the substrate particularly plant materials rather than changing water properties Energy requirements EditThe energy required to heat water is significantly lower than that needed to vaporize it for example for steam distillation 10 and the energy is easier to recycle using heat exchangers The energy requirements can be calculated from steam tables For example to heat water from 25 C to steam at 250 C at 1 atm requires 2869 kJ kg To heat water at 25 C to liquid water at 250 C at 5 MPa requires only 976 kJ kg It is also possible to recover much of the heat say 75 from superheated water and therefore energy use for superheated water extraction is less than one sixth that needed for steam distillation This also means that the energy contained in superheated water is insufficient to vaporise the water on decompression In the above example only 30 of the water would be converted to vapour on decompression from 5 MPa to atmospheric pressure 2 Extraction EditExtraction using superheated water tends to be fast because diffusion rates increase with temperature Organic materials tend to increase in solubility with temperature but not all at the same rate For example in extraction of essential oils from rosemary 11 and coriander 12 the more valuable oxygenated terpenes were extracted much faster than the hydrocarbons Therefore extraction with superheated water can be both selective and rapid and has been used to fractionate diesel and woodsmoke particulates 13 Superheated water is being used commercially to extract starch material from marsh mallow root for skincare applications 14 and to remove low levels of metals from a high temperature resistant polymer 15 16 For analytical purposes superheated water can replace organic solvents in many applications for example extraction of PAHs from soils 17 and can also be used on a large scale to remediate contaminated soils by either extraction alone or extraction linked to supercritical or wet oxidation 18 Reactions EditSuperheated water along with supercritical water has been used to oxidise hazardous material in the wet oxidation process Organic compounds are rapidly oxidised without the production of toxic materials sometimes produced by combustion However when the oxygen levels are lower organic compounds can be quite stable in superheated water As the concentration of hydronium H3 O and hydroxide OH ions are 100 times larger than in water at 25 C superheated water can act as a stronger acid and a stronger base and many different types of reaction can be carried out An example of a selective reaction is oxidation of ethylbenzene to acetophenone with no evidence of formation of phenylethanoic acid or of pyrolysis products 7 Several different types of reaction in which water was behaving as reactant catalyst and solvent were described by Katritzky et al 19 Triglycerides can be hydrolysed to free fatty acids and glycerol by superheated water at 275 C 20 which can be the first in a two stage process to make biodiesel 21 Superheated water can be used to chemically convert organic material into fuel products This is known by several terms including direct hydrothermal liquefaction 22 and hydrous pyrolysis A few commercial scale applications exist Thermal depolymerization or thermal conversion TCC uses superheated water at about 250 C to convert turkey waste into a light fuel oil and is said to process 200 tons of low grade waste into fuel oil a day 23 The initial product from the hydrolysis reaction is de watered and further processed by dry cracking at 500 C The SlurryCarb process operated by EnerTech uses similar technology to decarboxylate wet solid biowaste which can then be physically dewatered and used as a solid fuel called E Fuel The plant at Rialto is said to be able to process 683 tons of waste per day 24 The HTU or Hydro Thermal Upgrading process appears similar to the first stage of the TCC process A demonstration plant is due to start up in The Netherlands said to be capable of processing 64 tons of biomass dry basis per day into oil 25 Chromatography EditReverse phased HPLC often uses methanol water mixtures as the mobile phase Since the polarity of water spans the same range from 25 to 205 C a temperature gradient can be used to effect similar separations for example of phenols 26 The use of water allows the use of the flame ionisation detector FID which gives mass sensitive output for nearly all organic compounds 27 The maximum temperature is limited to that at which the stationary phase is stable C18 bonded phases which are common in HPLC seem to be stable at temperatures up to 200 C far above that of pure silica and polymeric styrene divinylbenzene phases offer similar temperature stability 28 Water is also compatible with use of an ultraviolet detector down to a wavelength of 190 nm See also EditPressurized water reactor Steam cracking Supercritical carbon dioxide Superheated steam Water heatingReferences Edit a b Chaplin Martin 2008 01 04 Explanation of the physical anomalies of water London South Bank University Archived from the original on 2007 10 17 a b c Clifford A A 2008 01 04 Changes of water properties with temperature Archived from the original on 2008 02 13 Retrieved 2008 01 15 Miller D J Hawthorne S B Gizir A M Clifford A A 1998 Solubility of polycyclic aromatic hydrocarbons in subcritical water from 298 K to 498 K Journal of Chemical amp Engineering Data 43 6 1043 1047 doi 10 1021 je980094g Letcher Trevor M 2007 Thermodynamics solubility and environmental issues Elsevier p 60 ISBN 978 0 444 52707 3 Guideline on the Henry s constant and vapor liquid distribution constant for gases in H2O and D2O at high temperatures PDF International Association for the Properties of Water and Steam September 2004 Retrieved 2008 01 14 Burnham Robert N et al 2001 Measurement of the flow of superheated water in blowdown pipes at MP2 using an ultrasonic clamp on method PDF Panametrix Archived from the original PDF on 2007 10 27 a b Holliday Russel L Yong B Y M Kolis J W 1998 Organic synthesis in subcritical water Oxidation of alkyl aromatics Journal of Supercritical Fluids 12 3 255 260 doi 10 1016 S0896 8446 98 00084 9 Corrosion seen as A plant accident cause New York Times 2000 03 03 Retrieved 2008 01 15 Clifford A A 2007 12 04 Superheated water more details Archived from the original on 2008 02 13 Retrieved 2008 01 12 King Jerry W Poster 12 Pressurized water extraction resources and techniques for optimizing analytical applications Image 13 Los Alamos National Laboratories Archived from the original on 2008 07 25 Retrieved 2008 01 12 Basile A et al 1998 Extraction of Rosemary by Superheated Water J Agric Food Chem 46 12 5205 5209 doi 10 1021 jf980437e Eikani M H Golmohammad F Rowshanzamir S 2007 Subcritical water extraction of essential oils from coriander seeds Corianrum sativum L PDF Journal of Food Engineering 80 2 735 740 doi 10 1016 j jfoodeng 2006 05 015 Retrieved 2008 01 04 Kubatova Alena Mayia Fernandez Steven Hawthorne 2002 04 09 A new approach to characterizing organic aerosol wood smoke and diesel exhaust particulate using subcritical water fractionation PDF PM2 5 and electric power generation recent findings and implications Pittsburgh PA National Energy Technology Laboratory Archived from the original PDF on 2011 05 29 LINK Competitive Industrial Materials from Non Food Crops Applications water and superheated water PDF Newsletter No 8 BBSRC Spring 2007 Archived from the original PDF on 2011 05 17 Retrieved 2008 01 08 Clifford A A 2007 12 04 Applications water and superheated water Archived from the original on 2008 02 13 Retrieved 2008 01 08 Clifford Tony Nov 5 8 2006 Separations using superheated water 8th International Symposium on Supercritical Fluids Kyoto Japan Archived from the original on 2006 08 23 Retrieved 2008 01 16 Kipp Sabine et al July 1998 Coupling superheated water extraction with enzyme immunoassay for an efficient and fast PAH screening in soil Talanta 46 3 385 393 doi 10 1016 S0039 9140 97 00404 9 PMID 18967160 Hartonen K Kronholm and Reikkola 2005 Jalkanen Anneli Nygren Pekka eds Sustainable use of renewable natural resources principles and practice PDF Chapter 5 2 Utilisation of high temperature water in the purification of water and soil University of Helsinki Department of Forest Ecology ISBN 978 952 10 2817 5 a href Template Cite book html title Template Cite book cite book a CS1 maint location link Katritzki A R S M Allin M Siskin 1996 Aquathermolysis reaction of organic compounds with superheated water PDF Accounts of Chemical Research 29 8 399 406 doi 10 1021 ar950144w Archived from the original PDF on 2012 12 02 Retrieved 2008 01 14 King Jerry W Holliday R L List G R December 1999 Hydrolysis of soubean oil in a subcritical water flow reactor Green Chemistry 1 6 261 264 doi 10 1039 a908861j Saka Shiro Kusdiana Dadan NEDO High efficiency bioenergy conversion project R amp D for biodiesel fuel BDF by two step supercritical methanol method PDF Archived from the original PDF on 2011 09 10 Retrieved 2008 01 12 Biomass Program direct Hydrothermal Liquefaction US Department of Energy Energy Efficiency and Renewable Energy 2005 10 13 Archived from the original on 2008 01 03 Retrieved 2008 01 12 About TCP Technology Renewable Environmental Solutions LLC Retrieved 2008 01 12 Sforza Teri 2007 03 14 New plan replaces sewage sludge fiasco Orange County Register Retrieved 2008 01 27 Goudriaan Frans Naber Jaap van den Berg Conversion of Biomass Residues to Transportation Fuels with the HTU Process PDF Retrieved 2019 03 29 Yarita Takashi Nakajima R Shibukawa M February 2003 Superheated water chromatography of phenols using poly styrene divnylbenzene packings as a stationary phase Analytical Sciences 19 2 269 272 doi 10 2116 analsci 19 269 PMID 12608758 Smith Roger Young E Sharp B 2012 Liquid chromatography flame ionisation detection using a nebuliser spray chamber interface Part 2 Comparison of functional group responses Journal of Chromatography A 1236 21 27 doi 10 1016 j chroma 2012 02 035 PMID 22420954 Smith R M Burgess R J 1996 Superheated water a clean eluent for reverse phase high performance chromatography Analytical Communications 33 9 327 329 doi 10 1039 AC9963300327 External links EditThe International Association for the Properties of Water and Steam Calculator for vapour pressure and enthalpy of superheated water Retrieved from https en wikipedia org w index php title Superheated water amp oldid 1129040295, wikipedia, wiki, book, books, library,

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