Nitromethane: Difference between revisions

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| ImageFileL1    = Valence structural formula of nitromethane.svg
| ImageFileL1    = Valence structural formula of nitromethane.svg
| ImageNameL1    = Structural formula of nitromethane
| ImageNameL1    = Structural formula of nitromethane
| ImageClassL1  = skin-invert
| ImageClassR1  = bg-transparent
| ImageFileR1    = Nitromethane-3D-vdW.png
| ImageFileR1    = Nitromethane-3D-vdW.png
| ImageNameR1    = Nitromethane
| ImageNameR1    = Nitromethane
| PIN            = Nitromethane<ref name=iupac2013>{{cite book | title =  Nomenclature of Organic Chemistry : IUPAC Recommendations and Preferred Names 2013 (Blue Book) | publisher = [[Royal Society of Chemistry|The Royal Society of Chemistry]] | date = 2014 | location = Cambridge | page = 662 | doi = 10.1039/9781849733069-FP001 | isbn = 978-0-85404-182-4| chapter = Front Matter }}</ref>
| PIN            = Nitromethane<ref name=iupac2013>{{cite book | title =  Nomenclature of Organic Chemistry: IUPAC Recommendations and Preferred Names 2013 (Blue Book) | publisher = [[Royal Society of Chemistry|The Royal Society of Chemistry]] | date = 2014 | location = Cambridge | page = 662 | doi = 10.1039/9781849733069-FP001 | isbn = 978-0-85404-182-4| chapter = Front Matter }}</ref>
| SystematicName =  
| SystematicName =  
| OtherNames    = Nitrocarbol
| OtherNames    = Nitrocarbol
Line 109: Line 111:


== Preparation ==
== Preparation ==
Nitromethane is produced industrially by combining [[propane]] and [[nitric acid]] in the gas phase at {{convert|350|–|450|C|F}}. This [[exothermic]] reaction produces the four industrially significant nitroalkanes: nitromethane, [[nitroethane]], [[1-nitropropane]], and [[2-Nitropropane|2-nitropropane]]. The reaction involves free radicals, including the alkoxyl radicals of the type {{chem2|CH3CH2CH2O}}, which arise via [[Homolysis (chemistry)|homolysis]] of the corresponding nitrite [[ester]]. These alkoxy radicals are susceptible to C—C fragmentation reactions, which explains the formation of a mixture of products.<ref name=Markofsky>{{ cite encyclopedia | author = Markofsky, S. B. | chapter = Nitro Compounds, Aliphatic | encyclopedia = Ullmann's Encyclopedia of Industrial Chemistry | year = 2000 | publisher = Wiley-VCH | location = Weinheim | doi = 10.1002/14356007.a17_401.pub2 | isbn = 978-3527306732 }}</ref>
Nitromethane is produced industrially by combining [[propane]] and [[nitric acid]] in the gas phase at {{convert|350|–|450|C|F}}. This [[exothermic]] reaction produces the four industrially significant nitroalkanes: nitromethane, [[nitroethane]], [[1-nitropropane]], and [[2-Nitropropane|2-nitropropane]]. The reaction involves free radicals, including the alkoxyl radicals of the type {{chem2|CH3CH2CH2O}}, which arise via [[Homolysis (chemistry)|homolysis]] of the corresponding nitrite [[ester]]. These alkoxy radicals are susceptible to C—C fragmentation reactions, which explains the formation of a mixture of products.<ref name=Markofsky>{{ cite encyclopedia | author = Markofsky, S. B. | chapter = Nitro Compounds, Aliphatic | encyclopedia = Ullmann's Encyclopedia of Industrial Chemistry | year = 2000 | publisher = Wiley-VCH | location = Weinheim | doi = 10.1002/14356007.a17_401.pub2 | isbn = 978-3-527-30673-2 }}</ref>


===Laboratory methods===
===Laboratory methods===
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Nitromethane is used as a fuel in motor racing, particularly [[drag racing]], as well as for [[radio-controlled]] model power boats, [[cars]], [[airplane|plane]]s and [[helicopters]]. In this context, nitromethane is commonly referred to as "nitro fuel" or simply "nitro", and is the principal ingredient for fuel used in the "[[Top Fuel]]" category of drag racing.<ref>{{Cite web |last=Carley |first=Larry |date=2013-01-06 |title=HPBG: The Power of Racing Fuels |url=https://www.enginebuildermag.com/2013/01/hpbg-the-power-of-racing-fuels/ |access-date=2024-05-31 |website=Engine Builder Magazine |language=en-US}}</ref>
Nitromethane is used as a fuel in motor racing, particularly [[drag racing]], as well as for [[radio-controlled]] model power boats, [[cars]], [[airplane|plane]]s and [[helicopters]]. In this context, nitromethane is commonly referred to as "nitro fuel" or simply "nitro", and is the principal ingredient for fuel used in the "[[Top Fuel]]" category of drag racing.<ref>{{Cite web |last=Carley |first=Larry |date=2013-01-06 |title=HPBG: The Power of Racing Fuels |url=https://www.enginebuildermag.com/2013/01/hpbg-the-power-of-racing-fuels/ |access-date=2024-05-31 |website=Engine Builder Magazine |language=en-US}}</ref>


The [[oxygen]] content of nitromethane enables it to burn with much less atmospheric oxygen than conventional fuels.<ref>{{Cite web |date=2024-03-05 |title=What is Nitro Methane Fuel: Understanding High-Performance Racing's Power Source - Ran When Parked - Car, Vehicle & Truck Guides and Repair Journals. |url=https://ranwhenparked.net/what-is-nitro-methane-fuel/ |access-date=2024-05-31 |website=ranwhenparked.net |language=en-US}}</ref> During nitromethane combustion, [[nitric oxide]] (NO) is one of the major emission products along with CO{{sub|2}} and H{{sub|2}}O.<ref>{{Cite journal|last1=Shrestha|first1=Krishna Prasad|last2=Vin|first2=Nicolas|last3=Herbinet|first3=Olivier|last4=Seidel|first4=Lars|last5=Battin-Leclerc|first5=Frédérique|last6=Zeuch|first6=Thomas|last7=Mauss|first7=Fabian|date=2020-02-01|title=Insights into nitromethane combustion from detailed kinetic modeling – Pyrolysis experiments in jet-stirred and flow reactors|journal=Fuel|volume=261|pages=116349|doi=10.1016/j.fuel.2019.116349|bibcode=2020Fuel..26116349S |s2cid=208755285|issn=0016-2361|url=https://hal.archives-ouvertes.fr/hal-02320515/file/2020%20Fuel%20CH3NO2.pdf}}</ref> Nitric oxide contributes to air pollution, acid rain, and ozone layer depletion. Recent (2020) studies<ref>{{Cite journal|last1=Shrestha|first1=Krishna Prasad|last2=Vin|first2=Nicolas|last3=Herbinet|first3=Olivier|last4=Seidel|first4=Lars|last5=Battin-Leclerc|first5=Frédérique|author5-link=Frédérique Battin-Leclerc|last6=Zeuch|first6=Thomas|last7=Mauss|first7=Fabian|date=2020-02-01|title=Insights into nitromethane combustion from detailed kinetic modeling – Pyrolysis experiments in jet-stirred and flow reactors|journal=Fuel|volume=261|pages=116349|doi=10.1016/j.fuel.2019.116349|bibcode=2020Fuel..26116349S |s2cid=208755285|issn=0016-2361|url=https://hal.archives-ouvertes.fr/hal-02320515/file/2020%20Fuel%20CH3NO2.pdf}}</ref> suggest the correct stoichiometric equation for the burning of nitromethane is:
The [[oxygen]] content of nitromethane enables it to burn with much less atmospheric oxygen than conventional fuels.<ref>{{Cite web |date=2024-03-05 |title=What is Nitro Methane Fuel: Understanding High-Performance Racing's Power Source - Ran When Parked - Car, Vehicle & Truck Guides and Repair Journals. |url=https://ranwhenparked.net/what-is-nitro-methane-fuel/ |access-date=2024-05-31 |website=ranwhenparked.net |language=en-US}}</ref> During nitromethane combustion, [[nitric oxide]] (NO) is one of the major emission products along with CO{{sub|2}} and H{{sub|2}}O.<ref>{{Cite journal|last1=Shrestha|first1=Krishna Prasad|last2=Vin|first2=Nicolas|last3=Herbinet|first3=Olivier|last4=Seidel|first4=Lars|last5=Battin-Leclerc|first5=Frédérique|last6=Zeuch|first6=Thomas|last7=Mauss|first7=Fabian|date=2020-02-01|title=Insights into nitromethane combustion from detailed kinetic modeling – Pyrolysis experiments in jet-stirred and flow reactors|journal=Fuel|volume=261|article-number=116349|doi=10.1016/j.fuel.2019.116349|bibcode=2020Fuel..26116349S |s2cid=208755285|issn=0016-2361|url=https://hal.archives-ouvertes.fr/hal-02320515/file/2020%20Fuel%20CH3NO2.pdf}}</ref> Nitric oxide contributes to air pollution, acid rain, and ozone layer depletion. Recent (2020) studies<ref>{{Cite journal|last1=Shrestha|first1=Krishna Prasad|last2=Vin|first2=Nicolas|last3=Herbinet|first3=Olivier|last4=Seidel|first4=Lars|last5=Battin-Leclerc|first5=Frédérique|author5-link=Frédérique Battin-Leclerc|last6=Zeuch|first6=Thomas|last7=Mauss|first7=Fabian|date=2020-02-01|title=Insights into nitromethane combustion from detailed kinetic modeling – Pyrolysis experiments in jet-stirred and flow reactors|journal=Fuel|volume=261|article-number=116349|doi=10.1016/j.fuel.2019.116349|bibcode=2020Fuel..26116349S |s2cid=208755285|issn=0016-2361|url=https://hal.archives-ouvertes.fr/hal-02320515/file/2020%20Fuel%20CH3NO2.pdf}}</ref> suggest the correct stoichiometric equation for the burning of nitromethane is:
:{{chem2|4 CH3NO2 + 5 O2 -> 4 CO2 + 6 H2O + 4 NO}}
:{{chem2|4 CH3NO2 + 5 O2 -> 4 CO2 + 6 H2O + 4 NO}}


The amount of air required to burn {{convert|1|kg|lb|abbr=on}} of gasoline is {{convert|14.7|kg|lb|abbr=on}}, but only {{convert|1.7|kg|lb|abbr=on}} of air is required for 1&nbsp;kg of nitromethane. Since an engine's cylinder can only contain a limited amount of air on each stroke, 8.6 times as much nitromethane as gasoline can be burned in one stroke. Nitromethane, however, has a lower specific energy: gasoline provides about 42–44 [[megajoule|MJ]]/kg, whereas nitromethane provides only 11.3 MJ/kg.{{Citation needed|date=April 2022}} This analysis indicates that nitromethane generates about 2.3 times the power of gasoline when combined with a given amount of oxygen.{{Citation needed|date=April 2022}}
The amount of air required to burn {{convert|1|kg|lb|abbr=on}} of gasoline is {{convert|14.7|kg|lb|abbr=on}}, but only {{convert|1.7|kg|lb|abbr=on}} of air is required for 1&nbsp;kg of nitromethane. Since an engine's cylinder can only contain a limited amount of air on each stroke, 8.6 times as much nitromethane as gasoline can be burned in one stroke. Nitromethane, however, has a lower specific energy: gasoline provides about 42–44 [[megajoule|MJ]]/kg, whereas nitromethane provides only 11.3 MJ/kg.{{Citation needed|date=April 2022}} This analysis indicates that nitromethane generates about 2.3 times the power of gasoline when combined with a given amount of oxygen.{{Citation needed|date=April 2022}}


Nitromethane can also be used as a [[monopropellant]], i.e., a propellant that decomposes to release energy without added oxygen. It was first tested as rocket monopropellant in 1930s by {{ill|Luigi Crocco|it|Luigi Crocco}} fom Italian Rocket Society.<ref>{{Cite conference |last1=Boyer |first1=E. |last2=Kuo |first2=K. |date=January 2006 |title=Characteristics of Nitromethane for Propulsion Applications |url=https://arc.aiaa.org/doi/10.2514/6.2006-361 |conference=44th AIAA Aerospace Sciences Meeting and Exhibit |location=Reno, NV |doi=10.2514/6.2006-361 |isbn=978-1-62410-039-0 |id=AIAA 2006-361}}</ref><ref name="Ignition">{{Cite book |last1=Clark |first1=J. D. |url=https://archive.org/details/ignitioninformal0000clar |title=Ignition! an informal history of liquid rocket propellants |last2=Asimov |first2=Isaac |date=1972 |publisher=Rutgers University Press |isbn=978-0-8135-0725-5 |pages=[https://archive.org/details/ignitioninformal0000clar/page/9 9]-10 |url-access=registration}}</ref> There is a renewed interest in nitromethane as safer replacement of [[hydrazine]] monopropellant.<ref>{{Cite conference |last1= Kurilov |first1=Maxim |last2= Werling |first2=Lukas |last3= Kirchberger |first3=Christoph |date=2023 |title=Nitromethane as a Green Propellant: First Results of a Combustion Test Campaign |url=https://www.eucass.eu/doi/EUCASS2023-372.pdf |conference=Aerospace Europe Conference 2023 |doi=10.13009/EUCASS2023-372 |doi-access=free}}</ref> The following equation describes this process:
Nitromethane can also be used as a [[monopropellant]], i.e., a propellant that decomposes to release energy without added oxygen. It was first tested as rocket monopropellant in 1930s by {{ill|Luigi Crocco|it|Luigi Crocco}} from the Italian Rocket Society.<ref>{{Cite conference |last1=Boyer |first1=E. |last2=Kuo |first2=K. |date=January 2006 |title=Characteristics of Nitromethane for Propulsion Applications |url=https://arc.aiaa.org/doi/10.2514/6.2006-361 |conference=44th AIAA Aerospace Sciences Meeting and Exhibit |location=Reno, NV |doi=10.2514/6.2006-361 |isbn=978-1-62410-039-0 |id=AIAA 2006-361|url-access=subscription }}</ref><ref name="Ignition">{{Cite book |last1=Clark |first1=J. D. |url=https://archive.org/details/ignitioninformal0000clar |title=Ignition! an informal history of liquid rocket propellants |last2=Asimov |first2=Isaac |date=1972 |publisher=Rutgers University Press |isbn=978-0-8135-0725-5 |pages=[https://archive.org/details/ignitioninformal0000clar/page/9 9]-10 |url-access=registration}}</ref> There is a renewed interest in nitromethane as safer replacement of [[hydrazine]] monopropellant.<ref>{{Cite conference |last1= Kurilov |first1=Maxim |last2= Werling |first2=Lukas |last3= Kirchberger |first3=Christoph |date=2023 |title=Nitromethane as a Green Propellant: First Results of a Combustion Test Campaign |url=https://www.eucass.eu/doi/EUCASS2023-372.pdf |conference=Aerospace Europe Conference 2023 |doi=10.13009/EUCASS2023-372 |doi-access=free}}</ref> The following equation describes this process:
:{{chem2|2 CH3NO2 -> 2 CO + 2 H2O + H2 + N2}}
:{{chem2|2 CH3NO2 -> 2 CO + 2 H2O + H2 + N2}}


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===Other===
===Other===
It can be used as an explosive, when gelled with several percent of gelling agent. This type of mixture is called [[PLX]]. Other mixtures include ANNM and ANNMAl – explosive mixtures of ammonium nitrate, nitromethane and aluminium powder.
It can be used as an explosive, when gelled with several percent of gelling agent. This type of mixture is called [[PLX]]. Other mixtures include ANNM and ANNMAl – explosive mixtures of ammonium nitrate, nitromethane and [[aluminium powder]].
 
A YouTuber posted a video that demonstrated that burning nitromethane will give off a very unusually colored flame.<ref>{{Cite AV media |url=https://www.youtube.com/shorts/yG34VsS6a0M |title=This flame looks fake but is real |language=en |access-date=2025-02-21 |via=www.youtube.com}}</ref> The flame actually appears to be black and white. He has used methanol to start the fire in the mentioned video.


==Reactions==
==Reactions==
===Acid-base properties===
===Acid-base properties===
Nitromethane is a relatively acidic [[carbon acid]]. It has a pK<sub>a</sub> of 17.2 in [[DMSO]] solution. This value indicates an aqueous pK<sub>a</sub> of about 11.<ref>{{cite journal|author1=Bordwell, F. G. |author2=Satish, A. V. |title=Is Resonance Important in Determining the Acidities of Weak Acids or the Homolytic Bond Dissociation Enthalpies (BDEs) of Their Acidic H-A Bonds?|journal=Journal of the American Chemical Society|volume=116|issue=20|pages=8885–8889|doi=10.1021/ja00099a004|year=1994|bibcode=1994JAChS.116.8885B }}</ref>  It is so acidic because the anion admits an alternate, stabilizing resonance structure: [[File:Nitromethane anion resonance.jpg|center|frameless|alt=Resonance with the aci form.]]
Nitromethane is a relatively acidic [[carbon acid]]. It has a pK<sub>a</sub> of 17.2 in [[DMSO]] solution. This value indicates an aqueous pK<sub>a</sub> of about 11.<ref>{{cite journal|author1=Bordwell, F. G. |author2=Satish, A. V. |title=Is Resonance Important in Determining the Acidities of Weak Acids or the Homolytic Bond Dissociation Enthalpies (BDEs) of Their Acidic H-A Bonds?|journal=Journal of the American Chemical Society|volume=116|issue=20|pages=8885–8889|doi=10.1021/ja00099a004|year=1994|bibcode=1994JAChS.116.8885B }}</ref>  It is so acidic because the anion admits an alternate, stabilizing resonance structure: [[File:Nitromethane anion resonance.jpg|class=skin-invert-image|center|frameless|alt=Resonance with the aci form.]]


The acid deprotonates only slowly. Protonation of the [[conjugate base]] {{chem2|O2NCH2−}}, which is nearly isosteric with [[nitrate]], occurs initially at oxygen.<ref>{{cite book|doi=10.1002/9780470166437.ch1|author1=Kramarz, K. W. |author2=Norton, J. R. |title=Progress in Inorganic Chemistry|pages=1–65|chapter=Slow Proton-Transfer Reactions in Organometallic and Bioinorganic Chemistry|year=2007|isbn=9780470166437}}
The acid deprotonates only slowly. Protonation of the [[conjugate base]] {{chem2|O2NCH2−}}, which is nearly isosteric with [[nitrate]], occurs initially at oxygen.<ref>{{cite book|doi=10.1002/9780470166437.ch1|author1=Kramarz, K. W. |author2=Norton, J. R. |title=Progress in Inorganic Chemistry|pages=1–65|chapter=Slow Proton-Transfer Reactions in Organometallic and Bioinorganic Chemistry|year=2007|isbn=978-0-470-16643-7}}
</ref>
</ref>


===Organic reactions===
===Organic reactions===
In [[organic synthesis]] nitromethane is employed as a one carbon [[synthon|building block]].<ref>{{ OrgSynth | author = Dauben, H. J. Jr. | author2 = Ringold, H. J. | author3 = Wade, R. H. | author4 = Pearson, D. L. | author5 = Anderson, A. G. Jr. | author6 = de Boer, T. J. | author7 = Backer, H. J. | title = Cycloheptanone | collvol = 4 | collvolpages = 221 | year = 1963 | prep = cv4p0221 }}</ref><ref>{{ OrgSynth | author = Noland, W. E. | title = 2-Nitroethanol | collvol = 4 | collvolpages = 833 | year = 1963 | prep = cv5p0833 }}</ref>  Its acidity allows it to undergo deprotonation, enabling condensation reactions analogous to those of carbonyl compounds. Thus, under base catalysis, nitromethane adds to [[aldehyde]]s in 1,2-addition in the [[nitroaldol reaction]]. Some important derivatives include the pesticides [[chloropicrin]] {{chem2|Cl3CNO2}}, [[beta-Nitrostyrene|beta-nitrostyrene]], and tris(hydroxymethyl)nitromethane {{chem2|(HOCH2)3CNO2}}. Reduction of the latter gives tris(hydroxymethyl)aminomethane, {{chem2|(HOCH2)3CNH2}}, better known as [[tris]], a widely used  [[Buffer solution|buffer]]. In more specialized [[organic synthesis]], nitromethane serves as a Michael donor, adding to α,β-unsaturated carbonyl compounds via 1,4-addition in the [[Michael reaction]].
In [[organic synthesis]] nitromethane is employed as a one carbon [[synthon|building block]].<ref>{{ OrgSynth | author = Dauben, H. J. Jr. | author2 = Ringold, H. J. | author3 = Wade, R. H. | author4 = Pearson, D. L. | author5 = Anderson, A. G. Jr. | author6 = de Boer, T. J. | author7 = Backer, H. J. | title = Cycloheptanone | collvol = 4 | collvolpages = 221 | year = 1963 | prep = cv4p0221 }}</ref><ref>{{ OrgSynth | author = Noland, W. E. | title = 2-Nitroethanol | collvol = 4 | collvolpages = 833 | year = 1963 | prep = cv5p0833 }}</ref>  Its acidity allows it to undergo deprotonation, enabling condensation reactions analogous to those of carbonyl compounds, and acting as a [[Michael reaction|Michael donor]]. Thus, under base catalysis, nitromethane adds to [[aldehyde]]s in 1,2-addition in the [[nitroaldol reaction]] and condenses with itself to make {{ill|methazonic acid|de|Methazons&auml;re}}.  
 
Some important derivatives include the pesticides [[chloropicrin]] {{chem2|Cl3CNO2}}, [[beta-Nitrostyrene|beta-nitrostyrene]], and tris(hydroxymethyl)nitromethane {{chem2|(HOCH2)3CNO2}}. Reduction of the latter gives tris(hydroxymethyl)aminomethane, {{chem2|(HOCH2)3CNH2}}, better known as [[tris]], a widely used  [[Buffer solution|buffer]].


==Purification==
==Purification==
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Nitromethane has a modest acute toxicity. [[LD50]] (oral, rats) is 1210±322&nbsp;mg/kg.<ref name=Markofsky/>
Nitromethane has a modest acute toxicity. [[LD50]] (oral, rats) is 1210±322&nbsp;mg/kg.<ref name=Markofsky/>


Nitromethane is "reasonably anticipated to be a human carcinogen" according to a U.S. government report.<ref>{{Cite web |date=December 21, 2021 |title=National Toxicology Program 15th Report on Carcinogens |url=https://ntp.niehs.nih.gov/sites/default/files/ntp/roc/content/profiles/nitromethane.pdf |url-status=live |archive-url=https://web.archive.org/web/20231002221739/https://ntp.niehs.nih.gov/sites/default/files/ntp/roc/content/profiles/nitromethane.pdf |archive-date=October 2, 2023 |access-date=May 30, 2024 |website=National Toxicology Program U.S. Department of Health and Human Services}}</ref>
Nitromethane is "reasonably anticipated to be a human carcinogen" according to a U.S. government report.'''<ref>{{Cite web |date=December 21, 2021 |title=National Toxicology Program 15th Report on Carcinogens |url=https://ntp.niehs.nih.gov/sites/default/files/ntp/roc/content/profiles/nitromethane.pdf |url-status=live |archive-url=https://web.archive.org/web/20231002221739/https://ntp.niehs.nih.gov/sites/default/files/ntp/roc/content/profiles/nitromethane.pdf |archive-date=October 2, 2023 |access-date=May 30, 2024 |website=National Toxicology Program U.S. Department of Health and Human Services}}</ref>''' In the United States, Nitromethane is regulated under the Department of Homeland Security, specifically under the Chemical Facilities Anti-Terrorism Standards (CFATS). <ref name=":0">https://www.cisa.gov/sites/default/files/publications/20171103-fl-nitromethane-508_0.pdf
 
https://web.archive.org/web/20221110000428/https://www.cisa.gov/sites/default/files/publications/20171103-fl-nitromethane-508_0.pdf
 
Department of Homeland Security, Chemical Facility Anti-Terrorism Standards: Nitromethane  </ref> Their program ensures that high-risk facilities take appropriate security measures to reduce overall risk associated with certain chemicals. <ref name=":0" /> The Department of Homeland Security considers chemicals such as Nitromethane to be "chemicals of interest" (COI) due to their hazardous nature. <ref name=":0" /> Due to this, CFATS requires specific protocols to be taken for marking, labeling, and transporting this material. <ref>{{Citation |last=Program |first=National Toxicology |title=Nitromethane |date=2021-12-21 |work=15th Report on Carcinogens [Internet] |url=https://www.ncbi.nlm.nih.gov/books/NBK590764/ |access-date=2025-12-13 |publisher=National Toxicology Program |language=en}}</ref> Additionally, within any facility that possesses over 42 gallons or more of Nitromethane must report and implement CFATS security measures accordingly.<ref name=":0" />


=== Explosive properties ===
=== Explosive properties ===
Nitromethane was not known to be a high [[explosive]] until a railroad [[tank car]] loaded with it exploded on {{#dateformat:June 1, 1958}}.<ref>{{cite web | url = http://www.blet602.org/Historic_accidents/Mt.%20Pulaski_6.1.1958.pdf | author = Interstate Commerce Commission | work = Ex Parte No 213 | title = Accident Near Mt. Pulaski, ILL |archiveurl=https://web.archive.org/web/20201101034350/http://www.blet602.org/Historic_accidents/Mt.%20Pulaski_6.1.1958.pdf|archivedate=1 November 2020}}</ref> After much testing{{citation needed|date=February 2024}}, it was realized that nitromethane was a more energetic high explosive than [[Trinitrotoluene|TNT]]{{citation needed|date=February 2024}}, although TNT has a higher [[Detonation velocity|velocity of detonation]] (VoD) and [[brisance]]{{citation needed|date=February 2024}}. Both of these explosives are oxygen-poor, and some benefits are gained from mixing with an [[oxidizer]], such as [[ammonium nitrate]]. Pure nitromethane is an insensitive explosive with a VoD of approximately {{convert|6400|m/s|ft/s|abbr=on}}, but even so inhibitors may be used to reduce the hazards. The tank car explosion was speculated{{citation needed|date=February 2024}} to be due to [[Adiabatic process|adiabatic]] compression, a hazard common to all liquid explosives. This is when small entrained air bubbles compress and superheat with rapid rises in pressure. It was thought that an operator rapidly snapped shut a valve creating a "[[water hammer|hammer-lock]]" pressure surge.{{Citation needed|date=April 2022}}
Nitromethane was not known to be a high [[explosive]] until a railroad [[tank car]] loaded with it exploded on {{#dateformat:June 1, 1958}}.<ref>{{cite web | url = http://www.blet602.org/Historic_accidents/Mt.%20Pulaski_6.1.1958.pdf | author = Interstate Commerce Commission | work = Ex Parte No 213 | title = Accident Near Mt. Pulaski, ILL |archive-url=https://web.archive.org/web/20201101034350/http://www.blet602.org/Historic_accidents/Mt.%20Pulaski_6.1.1958.pdf|archive-date=1 November 2020}}</ref> After much testing{{citation needed|date=February 2024}}, it was realized that nitromethane was a more energetic high explosive than [[Trinitrotoluene|TNT]]{{citation needed|date=February 2024}}, although TNT has a higher [[Detonation velocity|velocity of detonation]] (VoD) and [[brisance]]{{citation needed|date=February 2024}}. Both of these explosives are oxygen-poor, and some benefits are gained from mixing with an [[oxidizer]], such as [[ammonium nitrate]]. Large amounts of these explosives were used in [[Operation Plowshare]] that mainly focused on nuclear explosions.


If mixed with [[ammonium nitrate]], which is used as an oxidizer, it forms an explosive mixture known as [[ANFO#ANNM|ANNM]].
Pure nitromethane is an insensitive explosive with a VoD of approximately {{convert|6400|m/s|ft/s|abbr=on}}, but even so inhibitors may be used to reduce the hazards. The tank car explosion was speculated{{citation needed|date=February 2024}} to be due to [[Adiabatic process|adiabatic]] compression, a hazard common to all liquid explosives. This is when small entrained air bubbles compress and superheat with rapid rises in pressure. It was thought that an operator rapidly snapped shut a valve creating a "[[water hammer|hammer-lock]]" pressure surge.{{Citation needed|date=April 2022}}


Nitromethane is used as a model explosive, along with TNT. It has several advantages as a model explosive over TNT, namely its uniform density and lack of solid post-detonation species that complicate the determination of equation of state and further calculations.
Nitromethane is used as a model explosive, along with TNT. It has several advantages as a model explosive over TNT, namely its uniform density and lack of solid post-detonation species that complicate the determination of equation of state and further calculations.
Line 179: Line 185:


Nitromethane's reaction with solid sodium hydroxide is [[Hypergolic propellant|hypergolic]].
Nitromethane's reaction with solid sodium hydroxide is [[Hypergolic propellant|hypergolic]].
=== Regulation ===
Under the Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA),nitromethane is a hazardous chemical substance that has a federal reportable quantity of 1000 pounds. Any release of this chemical at or above this amount has to be reported within a 24-hour period.<ref>{{Cite web |last=US EPA |first=NATIONAL CENTER FOR ENVIRONMENTAL ASSESSMENT |date=2002-05-24 |title=Health And Environmental Effects Profile for Nitromethane |url=https://assessments.epa.gov/risk/document/&deid%3D44872 |access-date=2025-12-16 |website=US EPA |language=en}}</ref>
=== Human exposure ===
Data from the United States National Health and Nutrition Examination Survey(NHANES) about the chemical states that Nitromethane has been detected in a lot of blood sample tests from smokers. Analyzing this data found that smoking half a pack of cigarettes per day could cause a 150ng/L increase in nitromethane inside of your blood stream compared to non smokers.<ref>{{Cite journal |last=Espenship |first=Michael F. |last2=Silva |first2=Lalith K. |last3=Smith |first3=Mitchell M. |last4=Capella |first4=Kimberly M. |last5=Reese |first5=Christopher M. |last6=Rasio |first6=Jonathan P. |last7=Woodford |first7=Andrew M. |last8=Geldner |first8=Nathan B. |last9=Rey deCastro |first9=B. |last10=De Jesús |first10=Víctor R. |last11=Blount |first11=Benjamin C. |date=2019-02-19 |title=Nitromethane Exposure from Tobacco Smoke and Diet in the U.S. Population: NHANES, 2007-2012 |url=https://pubmed.ncbi.nlm.nih.gov/30672285 |journal=Environmental Science & Technology |volume=53 |issue=4 |pages=2134–2140 |doi=10.1021/acs.est.8b05579 |issn=1520-5851 |pmc=6737526 |pmid=30672285}}</ref>


==See also==
==See also==
Line 193: Line 205:


==Cited sources==
==Cited sources==
*{{cite book | editor= Haynes, William M. | year = 2011 | title = CRC Handbook of Chemistry and Physics | edition = 92nd | publisher = [[CRC Press]] | isbn = 978-1439855119| title-link = CRC Handbook of Chemistry and Physics }}
*{{cite book | editor= Haynes, William M. | year = 2011 | title = CRC Handbook of Chemistry and Physics | edition = 92nd | publisher = [[CRC Press]] | isbn = 978-1-4398-5511-9| title-link = CRC Handbook of Chemistry and Physics }}


== Further reading ==
== Further reading ==

Latest revision as of 03:16, 1 January 2026

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Template:Chembox AllOtherNamesTemplate:Chembox headerbarTemplate:Chembox IndexlistTemplate:Chembox JmolTemplate:Chembox ChEMBLTemplate:Chembox ECHATemplate:Chembox E numberTemplate:Chembox IUPHAR ligandTemplate:Chembox UNIITemplate:Chembox CompToxTemplate:Chembox headerbarTemplate:Chembox CriticalTPTemplate:Chembox SolubilityInWaterTemplate:Chembox headerbarTemplate:Chembox headerbarTemplate:Chembox DeltaGfreeTemplate:Chembox HazardsTemplate:Chembox headerbarTemplate:Chembox Datapage checkTemplate:Yesno
Nitromethane
Template:Chembox image sbs cell
Template:Longitem Template:Unbulleted list
ChEBI Template:Unbulleted list
ChemSpider Template:Unbulleted list
DrugBank Template:Unbulleted list
EC Number Template:Unbulleted list
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Script error: No such module "collapsible list".
Script error: No such module "collapsible list".
Template:Longitem Template:Chem2
Molar mass 61.04 g/mol
Appearance colorless, oily liquid[2]
Odor Light, fruity[2]
Density 1.1371 g/cm3 (20 °C)[3]
Melting point Template:Chembox CalcTemperatures
Boiling point Template:Chembox CalcTemperatures
Solubility miscible in diethyl ether, acetone, ethanol, methanol[3]
Vapor pressure 28 mmHg (20 °C)[2]
Acidity (pKa) Template:Unbulleted list
Template:Longitem −21.0·10−6 cm3/mol[5]
Thermal conductivity 0.204 W/(m·K) at 25 °C[6]
Template:Longitem 1.3817 (20 °C)[3]
Viscosity 0.63 cP at 25 °C[6]
Template:Longitem 3.46[7]
Shock sensitivity Low
Friction sensitivity Low
Detonation velocity 6400 m/s
Template:Longitem 106.6 J/(mol·K)
Template:Longitem 171.8 J/(mol·K)
Template:Longitem −112.6 kJ/mol
Template:Longitem nitroethane
Template:Longitem methyl nitrite
methyl nitrate

Template:Chembox Footer/tracking container onlyScript error: No such module "TemplatePar".Template:Short description

Nitromethane, sometimes shortened to simply "nitro", is an organic compound with the chemical formula Template:Chem2. It is the simplest organic nitro compound. It is a polar liquid commonly used as a solvent in a variety of industrial applications such as in extractions, as a reaction medium, and as a cleaning solvent. As an intermediate in organic synthesis, it is used widely in the manufacture of pesticides, explosives, fibers, and coatings.[8] Nitromethane is used as a fuel additive in various motorsports and hobbies, e.g. Top Fuel drag racing and miniature internal combustion engines in radio control, control line and free flight model aircraft.

Preparation

Nitromethane is produced industrially by combining propane and nitric acid in the gas phase at Script error: No such module "convert".. This exothermic reaction produces the four industrially significant nitroalkanes: nitromethane, nitroethane, 1-nitropropane, and 2-nitropropane. The reaction involves free radicals, including the alkoxyl radicals of the type Template:Chem2, which arise via homolysis of the corresponding nitrite ester. These alkoxy radicals are susceptible to C—C fragmentation reactions, which explains the formation of a mixture of products.[8]

Laboratory methods

It can also be prepared by other methods that are of instructional value. The reaction of sodium chloroacetate with sodium nitrite in aqueous solution produces this compound, along with sodium chloride and sodium bicarbonate:[9]

Template:Chem2

Uses

The dominant use of the nitromethane is as a precursor reagent. A major derivative is chloropicrin (Template:Chem2), a widely used pesticide. It condenses with formaldehyde (Henry reaction) to eventually give tris(hydroxymethyl)aminomethane ("tris"), a widely used buffer and ingredient in alkyd resins.[8]

Solvent and stabilizer

The major application is as a stabilizer in chlorinated solvents. As an organic solvent, nitromethane has an unusual combination of properties: highly polar (εr = 36 at 20 °C and μ = 3.5 Debye) but aprotic and weakly basic. This combination makes it useful for dissolving positively charged, strongly electrophilic species. It is a solvent for acrylate monomers, such as cyanoacrylates (more commonly known as "super-glues").[8]

Fuel

Although a minor application in terms of volume,[8] nitromethane also is used as a fuel or fuel additive for sports and hobby. For some applications, it is mixed with methanol in racing cars, boats, and model engines.

Nitromethane is used as a fuel in motor racing, particularly drag racing, as well as for radio-controlled model power boats, cars, planes and helicopters. In this context, nitromethane is commonly referred to as "nitro fuel" or simply "nitro", and is the principal ingredient for fuel used in the "Top Fuel" category of drag racing.[10]

The oxygen content of nitromethane enables it to burn with much less atmospheric oxygen than conventional fuels.[11] During nitromethane combustion, nitric oxide (NO) is one of the major emission products along with CO2 and H2O.[12] Nitric oxide contributes to air pollution, acid rain, and ozone layer depletion. Recent (2020) studies[13] suggest the correct stoichiometric equation for the burning of nitromethane is:

Template:Chem2

The amount of air required to burn Script error: No such module "convert". of gasoline is Script error: No such module "convert"., but only Script error: No such module "convert". of air is required for 1 kg of nitromethane. Since an engine's cylinder can only contain a limited amount of air on each stroke, 8.6 times as much nitromethane as gasoline can be burned in one stroke. Nitromethane, however, has a lower specific energy: gasoline provides about 42–44 MJ/kg, whereas nitromethane provides only 11.3 MJ/kg.Script error: No such module "Unsubst". This analysis indicates that nitromethane generates about 2.3 times the power of gasoline when combined with a given amount of oxygen.Script error: No such module "Unsubst".

Nitromethane can also be used as a monopropellant, i.e., a propellant that decomposes to release energy without added oxygen. It was first tested as rocket monopropellant in 1930s by Template:Ill from the Italian Rocket Society.[14][15] There is a renewed interest in nitromethane as safer replacement of hydrazine monopropellant.[16] The following equation describes this process:

Template:Chem2

Nitromethane has a laminar combustion velocity of approximately 0.5 m/s, somewhat higher than gasoline, thus making it suitable for high-speed engines. It also has a somewhat higher flame temperature of about Script error: No such module "convert".. The high heat of vaporization of 0.56 MJ/kg together with the high fuel flow provides significant cooling of the incoming charge (about twice that of methanol), resulting in reasonably low temperatures.Script error: No such module "Unsubst".

Nitromethane is usually used with rich air–fuel mixtures because it provides power even in the absence of atmospheric oxygen. When rich air–fuel mixtures are used, hydrogen and carbon monoxide are two of the combustion products. These gases often ignite, sometimes spectacularly, as the normally very rich mixtures of the still burning fuel exits the exhaust ports. Very rich mixtures are necessary to reduce the temperature of combustion chamber hot parts in order to control pre-ignition and subsequent detonation. Operational details depend on the particular mixture and engine characteristics.Script error: No such module "Unsubst".

A small amount of hydrazine blended in nitromethane can increase the power output even further. With nitromethane, hydrazine forms an explosive salt that is again a monopropellant. This unstable mixture poses a severe safety hazard. The National Hot Rod Association and Academy of Model Aeronautics do not permit its use in competitions.[17]

In model aircraft and car glow fuel, the primary ingredient is generally methanol with some nitromethane (0% to 65%, but rarely over 30%, and 10–20% lubricants (usually castor oil and/or synthetic oil)). Even moderate amounts of nitromethane tend to increase the power created by the engine (as the limiting factor is often the air intake), making the engine easier to tune (adjust for the proper air/fuel ratio).

Former uses

It formerly was used in the explosives industry as a component in a binary explosive formulation with ammonium nitrate and in shaped charges, and it was used as a chemical stabilizer to prevent decomposition of various halogenated hydrocarbons.[18]

Other

It can be used as an explosive, when gelled with several percent of gelling agent. This type of mixture is called PLX. Other mixtures include ANNM and ANNMAl – explosive mixtures of ammonium nitrate, nitromethane and aluminium powder.

Reactions

Acid-base properties

Nitromethane is a relatively acidic carbon acid. It has a pKa of 17.2 in DMSO solution. This value indicates an aqueous pKa of about 11.[19] It is so acidic because the anion admits an alternate, stabilizing resonance structure:

Resonance with the aci form.

The acid deprotonates only slowly. Protonation of the conjugate base Template:Chem2, which is nearly isosteric with nitrate, occurs initially at oxygen.[20]

Organic reactions

In organic synthesis nitromethane is employed as a one carbon building block.[21][22] Its acidity allows it to undergo deprotonation, enabling condensation reactions analogous to those of carbonyl compounds, and acting as a Michael donor. Thus, under base catalysis, nitromethane adds to aldehydes in 1,2-addition in the nitroaldol reaction and condenses with itself to make Template:Ill.

Some important derivatives include the pesticides chloropicrin Template:Chem2, beta-nitrostyrene, and tris(hydroxymethyl)nitromethane Template:Chem2. Reduction of the latter gives tris(hydroxymethyl)aminomethane, Template:Chem2, better known as tris, a widely used buffer.

Purification

Nitromethane is a popular solvent in organic and electroanalytical chemistry. It can be purified by cooling below its freezing point, washing the solid with cold diethyl ether, followed by distillation.[23]

Safety

Nitromethane has a modest acute toxicity. LD50 (oral, rats) is 1210±322 mg/kg.[8]

Nitromethane is "reasonably anticipated to be a human carcinogen" according to a U.S. government report.[24] In the United States, Nitromethane is regulated under the Department of Homeland Security, specifically under the Chemical Facilities Anti-Terrorism Standards (CFATS). [25] Their program ensures that high-risk facilities take appropriate security measures to reduce overall risk associated with certain chemicals. [25] The Department of Homeland Security considers chemicals such as Nitromethane to be "chemicals of interest" (COI) due to their hazardous nature. [25] Due to this, CFATS requires specific protocols to be taken for marking, labeling, and transporting this material. [26] Additionally, within any facility that possesses over 42 gallons or more of Nitromethane must report and implement CFATS security measures accordingly.[25]

Explosive properties

Nitromethane was not known to be a high explosive until a railroad tank car loaded with it exploded on June 1, 1958.[27] After much testingScript error: No such module "Unsubst"., it was realized that nitromethane was a more energetic high explosive than TNTScript error: No such module "Unsubst"., although TNT has a higher velocity of detonation (VoD) and brisanceScript error: No such module "Unsubst".. Both of these explosives are oxygen-poor, and some benefits are gained from mixing with an oxidizer, such as ammonium nitrate. Large amounts of these explosives were used in Operation Plowshare that mainly focused on nuclear explosions.

Pure nitromethane is an insensitive explosive with a VoD of approximately Script error: No such module "convert"., but even so inhibitors may be used to reduce the hazards. The tank car explosion was speculatedScript error: No such module "Unsubst". to be due to adiabatic compression, a hazard common to all liquid explosives. This is when small entrained air bubbles compress and superheat with rapid rises in pressure. It was thought that an operator rapidly snapped shut a valve creating a "hammer-lock" pressure surge.Script error: No such module "Unsubst".

Nitromethane is used as a model explosive, along with TNT. It has several advantages as a model explosive over TNT, namely its uniform density and lack of solid post-detonation species that complicate the determination of equation of state and further calculations.

Nitromethane reacts with solutions of sodium hydroxide or methoxide in alcohol to produce an insoluble salt of nitromethane. This substance is a sensitive explosive which reverts to nitromethane under acidic conditions and decomposes in water to form another explosive compound, sodium methazonate, which has a reddish-brown color:

Template:Chem2

Nitromethane's reaction with solid sodium hydroxide is hypergolic.

Regulation

Under the Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA),nitromethane is a hazardous chemical substance that has a federal reportable quantity of 1000 pounds. Any release of this chemical at or above this amount has to be reported within a 24-hour period.[28]

Human exposure

Data from the United States National Health and Nutrition Examination Survey(NHANES) about the chemical states that Nitromethane has been detected in a lot of blood sample tests from smokers. Analyzing this data found that smoking half a pack of cigarettes per day could cause a 150ng/L increase in nitromethane inside of your blood stream compared to non smokers.[29]

See also

References

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  1. Script error: No such module "citation/CS1".
  2. a b c Cite error: Script error: No such module "Namespace detect".Script error: No such module "Namespace detect".
  3. a b c Haynes, p. 3.414
  4. Haynes, p. 6.69
  5. Haynes, p. 3.576
  6. a b Haynes, p. 6.231
  7. Haynes, p. 15.19
  8. a b c d e f Script error: No such module "citation/CS1".
  9. Script error: No such module "Citation/CS1".; Script error: No such module "citation/CS1"..
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  25. a b c d https://www.cisa.gov/sites/default/files/publications/20171103-fl-nitromethane-508_0.pdf https://web.archive.org/web/20221110000428/https://www.cisa.gov/sites/default/files/publications/20171103-fl-nitromethane-508_0.pdf Department of Homeland Security, Chemical Facility Anti-Terrorism Standards: Nitromethane
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Further reading

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External links

Template:Motor fuel

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