Hexanitrohexaazaisowurtzitane: Difference between revisions

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	{{Chembox		{{Chembox
			\| Verifiedfields = changed
	\| Watchedfields = changed		\| Watchedfields = changed
	\| verifiedrevid = ~~399723511~~		\| verifiedrevid = 451734664
	\| ImageFileL1 = CL-20.svg		\| ImageFileL1 = CL-20.svg
	\| ImageFileL1_Ref = {{chemboximage\|correct\|??}}		\| ImageFileL1_Ref = {{chemboximage\|correct\|??}}
Line 9:		Line 10:
	\| ImageFileR1_Ref = {{chemboximage\|correct\|??}}		\| ImageFileR1_Ref = {{chemboximage\|correct\|??}}
	\| ImageSizeR1 = 121		\| ImageSizeR1 = 121
	\| ImageNameR1 = Ball and stick model of ~~hexanitrohexaazaisowurtzitane~~		\| ImageNameR1 = Ball and stick model of hexazaisowurtzitane
	\| IUPACName = 2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-~~hexaazaisowurtzitane{{Citation needed\|date = May 2011}}~~		\| IUPACName = 2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-hexaazatetracyclododecane
	\| OtherNames = ~~CL-20~~		\| OtherNames = {{Unbulleted list
			\| CL-20
	\| Section1 = {{Chembox Identifiers
			\| Hexanitrohexaazaisowurtzitane
	\| Abbreviations = CL-20, HNIW
			\| 2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane
	\| CASNo = 135285-90-4
			\| Octahydro-1,3,4,7,8,10-hexanitro-5,2,6-(iminomethenimino)-1H-imidazopyrazine
	\| PubChem = 9889323
			\| HNIW
	\| PubChem_Ref = {{Pubchemcite\|correct\|pubchem}}
			}}
	\| PubChem1 = 11048432
			\|Section1={{Chembox Identifiers
	\| PubChem1_Ref = {{Pubchemcite\|correct\|pubchem}}
			\| Abbreviations = CL-20, HNIW
	\| PubChem1_Comment = <small>(3''R'',9''R'')-dodec</small>
			\| CASNo_Ref = {{cascite\|correct\|??}}
	\| PubChem2 = 11419235
			\| CASNo = 135285-90-4
	\| PubChem2_Ref = {{Pubchemcite\|correct\|pubchem}}
			\| UNII_Ref = {{fdacite\|correct\|FDA}}
	\| PubChem2_Comment = <small>(3''R'',5''S'',9''R'',11''S'')- dodec</small>
			\| UNII = RQM82X0CL7
	\| ChemSpiderID = 8064994
			\| PubChem = 9889323
	\| ChemSpiderID_Ref = {{chemspidercite\|correct\|chemspider}}
			\| PubChem1 = 11048432
	\| ChemSpiderID1 = 9223599
			\| PubChem1_Comment = <small>(3''R'',9''R'')-dodec</small>
	\| ChemSpiderID1_Ref = {{chemspidercite\|correct\|chemspider}}
			\| PubChem2 = 11419235
	\| ChemSpiderID1_Comment = <small>(3''R'',9''R'')-dodec</small>
			\| PubChem2_Comment = <small>(3''R'',5''S'',9''R'',11''S'')- dodec</small>
	\| ChemSpiderID2 = 9594121
			\| ChemSpiderID = 8064994
	\| ChemSpiderID2_Ref = {{chemspidercite\|correct\|chemspider}}
			\| ChemSpiderID_Ref = {{chemspidercite\|correct\|chemspider}}
	\| ChemSpiderID2_Comment = <small>(3''R'',5''S'',9''R'',11''S'')- dodec</small>
			\| ChemSpiderID1 = 9223599
	\| SMILES = o:n(:o)N1C2C3N(C4C(N3n(:o):o)N(C(C1N4n(:o):o)N2n(:o):o)n(:o):o)n(:o):o
			\| ChemSpiderID1_Ref = {{chemspidercite\|correct\|chemspider}}
	\| SMILES1 = (=O)N1C2C3N(C4C(N3()=O)N(C(C1N4()=O)N2()=O)()=O)()=O
			\| ChemSpiderID1_Comment = <small>(3''R'',9''R'')-dodec</small>
	\| StdInChI = 1S/C6H6N12O12/c19-13(20)7-1-2-8(14(21)22)5(7)6-9(15(23)24)3(11(1)17(27)28)4(10(6)16(25)26)12(2)18(29)30/h1-6H
			\| ChemSpiderID2 = 9594121
	\| StdInChI_Ref = {{stdinchicite\|correct\|chemspider}}
			\| ChemSpiderID2_Ref = {{chemspidercite\|correct\|chemspider}}
	\| StdInChIKey = NDYLCHGXSQOGMS-UHFFFAOYSA-N
			\| ChemSpiderID2_Comment = <small>(3''R'',5''S'',9''R'',11''S'')- dodec</small>
	\| StdInChIKey_Ref = {{stdinchicite\|correct\|chemspider}}
			\| ChEBI_Ref = {{ebicite\|changed\|EBI}}
			\| ChEBI = 77327
			\| SMILES = (=O)N1C2C3N(C4C(N3()=O)N(C(C1N4()=O)N2()=O)()=O)()=O
			\| StdInChI = 1S/C6H6N12O12/c19-13(20)7-1-2-8(14(21)22)5(7)6-9(15(23)24)3(11(1)17(27)28)4(10(6)16(25)26)12(2)18(29)30/h1-6H
			\| StdInChI_Ref = {{stdinchicite\|correct\|chemspider}}
			\| StdInChIKey = NDYLCHGXSQOGMS-UHFFFAOYSA-N
			\| StdInChIKey_Ref = {{stdinchicite\|correct\|chemspider}}
	}}		}}
	\| Section2 = {{Chembox Properties		\|Section2={{Chembox Properties
	\| Formula = {{Chem\|C\|6\|N\|12\|H\|6\|O\|12}}		\| Formula = {{Chem\|C\|6\|N\|12\|H\|6\|O\|12}}
	\| MolarMass = 438.1850 g mol<sup>-1</sup>		\| MolarMass = 438.1850 g mol<sup>−1</sup>
	\| ~~ExactMass~~ = ~~438~~.~~022813716~~ g ~~mol~~<sup>-1</sup>		\| Density = 2.044 g cm<sup>−3</sup>
	}}
	\| Section6 = {{Chembox Explosive
	\| ExplosiveV = 9.38 km s<sup>-1</sup>
	}}		}}
			\|Section6={{Chembox Explosive
			\| DetonationV = 9,500 ]
			\| REFactor = 1.9 }}
	}}		}}

	'''~~2,4,6,8,10,12-hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane~~''', also called '''HNIW''', and '''CL-20''', is a ] explosive with the formula ~~C<sub>6</sub>H<sub>6</sub>N<sub>12</sub>O<sub>12</sub>, developed by the ] facility, primarily to be used in ]s~~. It has a better ]-to-] ratio than conventional ] or ]. It ~~produces~~ 20% more energy than traditional HMX-based propellants~~, and is widely superior to conventional high-energy propellants and explosives~~.		'''Hexanitrohexaazaisowurtzitane''', also called '''HNIW''' and '''CL-20''', is a ] ] explosive with the formula {{chem2\|C6H6N12O12}}. It has a better ]-to-] ratio than conventional ] or ]. It releases 20% more energy than traditional HMX-based propellants.

			== History and use ==
	While most development of CL-20 has been fielded by the ], the ] (through ]) has also been interested in CL-20 for use in ]s, such as for ], as it has lower observability characteristics (e.g., less visible smoke).<ref></ref>
			In the 1980s, CL-20 was developed by the ] facility, primarily to be used in ]s.<ref>{{cite web \| last=Kadam \| first=Tanmay \| title=Pioneered By The US, China 'Racing Ahead' Of Its Arch Rival In 'CL-20' Tech That Propels PLA's Deadly Missiles \| website=Eurasian Times \| date=2023-03-11 \| url=https://eurasiantimes.com/pioneered-by-the-us-china-races-ahead-of-its-arch-rival/}}</ref>

			While most development of CL-20 has been fielded by the ], the ] (through ]) has also been interested in CL-20 for use in ]s, such as for ], as it has lower observability characteristics such as less visible smoke.<ref>{{cite web \|url=http://www.physorg.com/news/2011-09-university-chemists-stabilize-explosive-cl-.html \|title=University chemists devise means to stabilize explosive CL-20 \|first=Bob \|last=Yirka \|publisher=Physorg.com \|date=9 September 2011 \|accessdate=8 July 2012 \|archive-date=25 January 2021 \|archive-url=https://web.archive.org/web/20210125151129/https://phys.org/news/2011-09-university-chemists-stabilize-explosive-cl-.html \|url-status=live }}</ref>
	CL-20 has not yet been fielded in any production weapons system, but is presently undergoing testing for stability, production capabilities, and other weapons characteristics.

			Thus far, CL-20 has only been used in the ] 300 “kamikaze” drone, but is undergoing testing for use in the Lockheed Martin ]C Long Range Anti-Ship Missile (LRASM) and AGM-158B Joint Air-to-Surface Standoff Missile-Extended Range (JASSM-ER).<ref>{{Cite web \|last=Wolfe \|first=Frank \|date=2023-03-28 \|title=CL-20 Used in Switchblade 300, May See Wider Use in JASSM-ER, LRASM, Other Munitions \|url=https://www.defensedaily.com/cl-20-used-in-switchblade-300-may-see-wider-use-in-jassm-er-lrasm-other-munitions/advanced-transformational-technology/ \|access-date=2024-04-26 \|website=Defense Daily \|language=en-US}}</ref>
	==Synthesis==
	It is made from ], ], ], and white fuming ] by combining these chemicals.

			The ] have also looked into CL-20.<ref>{{cite web \| url=https://pib.gov.in/newsite/PrintRelease.aspx?relid=67872 \| title=Pune Based DRDO Lab Makes Most Powerful Conventional Explosive }}</ref>
	]

			The Taiwanese ] innaugerated a CL-20 production facility in 2022 with reported integration into the ] and ] product lines.<ref>{{cite web \|last1=Tien-pin \|first1=Lo \|last2=Chung \|first2=Jake \|title=Institute develops powerful explosive \|url=https://www.taipeitimes.com/News/front/archives/2024/07/06/2003820398 \|website=taipeitimes.com \|date=6 July 2024 \|publisher=Taipei Times \|access-date=7 July 2024}}</ref>

			== Synthesis ==
			]

			First, ] ('''1''') is condensed with ] ('''2''') under acidic and dehydrating conditions to yield the first intermediate compound.('''3'''). Four benzyl groups selectively undergo ] using ] and hydrogen. The amino groups are then acetylated during the same step using ] as the solvent. ('''4'''). Finally, compound '''4''' is reacted with ] and ], resulting in HNIW.<ref>{{cite journal\|journal = ]\|year = 2005\|volume = 41\|issue = 2\|pages = 121–132\|title = Hexanitrohexaazaisowurtzitane (CL-20) and CL-20-based formulations (review)\|first1 = U. R.\|last1 = Nair\|first2 = R.\|last2 = Sivabalan\|first3 = G. M.\|last3 = Gore\|first4 = M.\|last4 = Geetha\|first5 = S. N.\|last5 = Asthana\|first6 = H.\|last6 = Singh\|doi = 10.1007/s10573-005-0014-2\|s2cid = 95545484}}</ref>

			==Cocrystals==
			In August 2011, ] and ] published results showing that a ] of CL-20 and ] had twice the stability of CL-20—safe enough to transport, but when heated to {{convert\|136\|°C\|°F}} the cocrystal may separate into liquid TNT and a crystal form of CL-20 with structural defects that is somewhat less stable than CL-20.<ref>{{cite journal\|doi=10.1002/anie.201104164 \| pmid=21901797 \| volume=50 \| issue=38 \| title=Improved Stability and Smart-Material Functionality Realized in an Energetic Cocrystal \| year=2011 \| journal=Angewandte Chemie International Edition \| pages=8960–8963 \| last1 = Bolton \| first1 = Onas\| hdl=2027.42/86799 \| hdl-access=free }}</ref><ref>{{Cite web \|url=https://www.science.org/content/blog-post/things-i-won-t-work-hexanitrohexaazaisowurtzitane \|title=Things I Won't Work With: Hexanitrohexaazaisowurtzitane \|date=11 November 2011 \|access-date=2016-01-04 \|archive-date=2015-09-03 \|archive-url=https://web.archive.org/web/20150903002615/http://blogs.sciencemag.org/pipeline/archives/2011/11/11/things_i_wont_work_with_hexanitrohexaazaisowurtzitane \|url-status=live }}</ref>

			In August 2012, ] et al. published results showing that a ] of 2 parts CL-20 and 1 part ] had similar safety properties to HMX, but with a greater firing power closer to CL-20.<ref>{{cite journal\|doi=10.1021/cg3010882 \| volume=12 \| issue=9 \| title=High Power Explosive with Good Sensitivity: A 2:1 Cocrystal of CL-20:HMX \| year=2012 \| journal= Crystal Growth & Design\| pages=4311–4314 \| last1 = Bolton \| first1 = Onas}}</ref><ref>{{cite web \| title=Powerful new explosive could replace today's state-of-the-art military explosive \| website=spacewar.com \| date=2012-09-06 \| url=http://www.spacewar.com/reports/Powerful_new_explosive_could_replace_todays_state_of_the_art_military_explosive_999.html \| archive-url=https://web.archive.org/web/20120909160217/http://www.spacewar.com/reports/Powerful_new_explosive_could_replace_todays_state_of_the_art_military_explosive_999.html \| archive-date=2012-09-09 \| url-status=live}}</ref>

			==Polymeric derivatives==
			In 2017, K.P. Katin and M.M. Maslov designed one-dimensional covalent chains based on the CL-20 molecules.<ref name=katin2017>{{cite journal\|doi=10.1016/j.jpcs.2017.04.020 \| volume=108 \| title=Toward CL-20 crystalline covalent solids: On the dependence of energy and electronic properties on the effective size of CL-20 chains \| year=2017 \| journal=] \| pages=82–87 \| last1 = Katin \| first1 = Konstantin P. \| last2 = Maslov \| first2 = Mikhail M.\| arxiv=1611.08623 \| bibcode=2017JPCS..108...82K \| s2cid=100118824 }}</ref> Such chains were constructed using {{chem\|CH\|2}} molecular bridges for the covalent bonding between the isolated CL-20 fragments. It was theoretically predicted that their stability increased with efficient length growth. A year later, M.A. Gimaldinova and colleagues demonstrated the versatility of {{chem\|CH\|2}} molecular bridges.<ref name=gimaldinova2018>{{cite journal \| doi=10.1039/c8ce00763b \| volume=20 \| issue=30 \| title=Electronic and reactivity characteristics of CL-20 covalent chains and networks: a density functional theory study \| year=2018 \| journal=] \| pages=4336–4344 \| last1 = Gimaldinova \| first1 = Margarita A. \| last2 = Maslov \| first2 = Mikhail M. \| last3 = Katin \| first3 = Konstantin P. }}</ref> It is shown that the use of {{chem\|CH\|2}} bridges is the universal technique to connect both CL-20 fragments in the chain and the chains together to make a network (linear or zigzag). It is confirmed that the increase of the effective sizes and dimensionality of the CL-20 covalent systems leads to their thermodynamic stability growth. Therefore, the formation of CL-20 crystalline covalent solids seems to be energetically favorable, and CL-20 molecules are capable of forming not only molecular crystals but bulk covalent structures as well. Numerical calculations of CL-20 chains and networks' electronic characteristics revealed that they were wide-bandgap semiconductors.<ref name="katin2017" /><ref name="gimaldinova2018" />

	==See also==		==See also==
			{{div col begin}}
	*]
			* ]
	*] (DDF)
			* ] (DDF)
	*]
			* ] (HNB)
	*]
			* ] (HNC)
	*]
			* ]
			* ] (N8)
			* ] (Wurtzitane)
			* ] (ONC)
			* ]
			* ]
			{{div col end}}

	==References==		== References ==

	{{Reflist}}
			{{reflist}}

			== Further reading ==

			* {{cite journal \|title=Improved Stability and Smart-Material Functionality Realized in an Energetic Cocrystal \|last=Bolton \|first=Onas \|author2=Adam J. Matzger \|journal=] \|volume=123 \|issue=38 \|pages=9122–9125 \|date=September 12, 2011 \|doi=10.1002/ange.201104164\|pmid=21901797 \|bibcode=2011AngCh.123.9122B \|hdl=2027.42/86799 \|hdl-access=free }}
			* Lowe, Derek (11 November 2011)

	]
	]		]
	]		]
			]

	]
	]
	]
	]
	]
	]
	]
	]
	]
	]
	]

Latest revision as of 15:58, 8 January 2025

Hexanitrohexaazaisowurtzitane

Ball and stick model of hexazaisowurtzitane

Names

IUPAC name 2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-hexaazatetracyclododecane

Other names

CL-20
Hexanitrohexaazaisowurtzitane
2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane
Octahydro-1,3,4,7,8,10-hexanitro-5,2,6-(iminomethenimino)-1H-imidazopyrazine
HNIW

Identifiers

CAS Number

135285-90-4

3D model (JSmol)

Interactive image

Abbreviations

CL-20, HNIW

ChEBI

CHEBI:77327

ChemSpider

8064994
9223599 (3R,9R)-dodec
9594121 (3R,5S,9R,11S)- dodec

ECHA InfoCard

100.114.169

PubChem CID

9889323
11048432 (3R,9R)-dodec
11419235 (3R,5S,9R,11S)- dodec

UNII

RQM82X0CL7

CompTox Dashboard (EPA)

DTXSID90873482

InChI

InChI=1S/C6H6N12O12/c19-13(20)7-1-2-8(14(21)22)5(7)6-9(15(23)24)3(11(1)17(27)28)4(10(6)16(25)26)12(2)18(29)30/h1-6HKey: NDYLCHGXSQOGMS-UHFFFAOYSA-N

SMILES

(=O)N1C2C3N(C4C(N3()=O)N(C(C1N4()=O)N2()=O)()=O)()=O

Properties

Chemical formula

C
₆N
₁₂H
₆O
₁₂

Molar mass

438.1850 g mol

Density

2.044 g cm

Explosive data

Detonation velocity

9,500 m/s

RE factor

1.9

Except where otherwise noted, data are given for materials in their standard state (at 25 °C , 100 kPa).

N verify (what is ?) Infobox references

Chemical compound

Hexanitrohexaazaisowurtzitane, also called HNIW and CL-20, is a polycyclic nitroamine explosive with the formula C₆H₆N₁₂O₁₂. It has a better oxidizer-to-fuel ratio than conventional HMX or RDX. It releases 20% more energy than traditional HMX-based propellants.

History and use

In the 1980s, CL-20 was developed by the China Lake facility, primarily to be used in propellants.

While most development of CL-20 has been fielded by the Thiokol Corporation, the US Navy (through ONR) has also been interested in CL-20 for use in rocket propellants, such as for missiles, as it has lower observability characteristics such as less visible smoke.

Thus far, CL-20 has only been used in the AeroVironment Switchblade 300 “kamikaze” drone, but is undergoing testing for use in the Lockheed Martin AGM-158C Long Range Anti-Ship Missile (LRASM) and AGM-158B Joint Air-to-Surface Standoff Missile-Extended Range (JASSM-ER).

The Indian Armed Forces have also looked into CL-20.

The Taiwanese National Chung-Shan Institute of Science and Technology innaugerated a CL-20 production facility in 2022 with reported integration into the HF-2 and HF-3 product lines.

Synthesis

First, benzylamine (1) is condensed with glyoxal (2) under acidic and dehydrating conditions to yield the first intermediate compound.(3). Four benzyl groups selectively undergo hydrogenolysis using palladium on carbon and hydrogen. The amino groups are then acetylated during the same step using acetic anhydride as the solvent. (4). Finally, compound 4 is reacted with nitronium tetrafluoroborate and nitrosonium tetrafluoroborate, resulting in HNIW.

Cocrystals

In August 2011, Adam Matzger and Onas Bolton published results showing that a cocrystal of CL-20 and TNT had twice the stability of CL-20—safe enough to transport, but when heated to 136 °C (277 °F) the cocrystal may separate into liquid TNT and a crystal form of CL-20 with structural defects that is somewhat less stable than CL-20.

In August 2012, Onas Bolton et al. published results showing that a cocrystal of 2 parts CL-20 and 1 part HMX had similar safety properties to HMX, but with a greater firing power closer to CL-20.

Polymeric derivatives

In 2017, K.P. Katin and M.M. Maslov designed one-dimensional covalent chains based on the CL-20 molecules. Such chains were constructed using CH
₂ molecular bridges for the covalent bonding between the isolated CL-20 fragments. It was theoretically predicted that their stability increased with efficient length growth. A year later, M.A. Gimaldinova and colleagues demonstrated the versatility of CH
₂ molecular bridges. It is shown that the use of CH
₂ bridges is the universal technique to connect both CL-20 fragments in the chain and the chains together to make a network (linear or zigzag). It is confirmed that the increase of the effective sizes and dimensionality of the CL-20 covalent systems leads to their thermodynamic stability growth. Therefore, the formation of CL-20 crystalline covalent solids seems to be energetically favorable, and CL-20 molecules are capable of forming not only molecular crystals but bulk covalent structures as well. Numerical calculations of CL-20 chains and networks' electronic characteristics revealed that they were wide-bandgap semiconductors.

References

Kadam, Tanmay (2023-03-11). "Pioneered By The US, China 'Racing Ahead' Of Its Arch Rival In 'CL-20' Tech That Propels PLA's Deadly Missiles". Eurasian Times.
Yirka, Bob (9 September 2011). "University chemists devise means to stabilize explosive CL-20". Physorg.com. Archived from the original on 25 January 2021. Retrieved 8 July 2012.
Wolfe, Frank (2023-03-28). "CL-20 Used in Switchblade 300, May See Wider Use in JASSM-ER, LRASM, Other Munitions". Defense Daily. Retrieved 2024-04-26.
"Pune Based DRDO Lab Makes Most Powerful Conventional Explosive".
Tien-pin, Lo; Chung, Jake (6 July 2024). "Institute develops powerful explosive". taipeitimes.com. Taipei Times. Retrieved 7 July 2024.
Nair, U. R.; Sivabalan, R.; Gore, G. M.; Geetha, M.; Asthana, S. N.; Singh, H. (2005). "Hexanitrohexaazaisowurtzitane (CL-20) and CL-20-based formulations (review)". Combust. Explos. Shock Waves. 41 (2): 121–132. doi:10.1007/s10573-005-0014-2. S2CID 95545484.
Bolton, Onas (2011). "Improved Stability and Smart-Material Functionality Realized in an Energetic Cocrystal". Angewandte Chemie International Edition. 50 (38): 8960–8963. doi:10.1002/anie.201104164. hdl:2027.42/86799. PMID 21901797.
"Things I Won't Work With: Hexanitrohexaazaisowurtzitane". 11 November 2011. Archived from the original on 2015-09-03. Retrieved 2016-01-04.
Bolton, Onas (2012). "High Power Explosive with Good Sensitivity: A 2:1 Cocrystal of CL-20:HMX". Crystal Growth & Design. 12 (9): 4311–4314. doi:10.1021/cg3010882.
"Powerful new explosive could replace today's state-of-the-art military explosive". spacewar.com. 2012-09-06. Archived from the original on 2012-09-09.
^ Katin, Konstantin P.; Maslov, Mikhail M. (2017). "Toward CL-20 crystalline covalent solids: On the dependence of energy and electronic properties on the effective size of CL-20 chains". Journal of Physics and Chemistry of Solids. 108: 82–87. arXiv:1611.08623. Bibcode:2017JPCS..108...82K. doi:10.1016/j.jpcs.2017.04.020. S2CID 100118824.
^ Gimaldinova, Margarita A.; Maslov, Mikhail M.; Katin, Konstantin P. (2018). "Electronic and reactivity characteristics of CL-20 covalent chains and networks: a density functional theory study". CrystEngComm. 20 (30): 4336–4344. doi:10.1039/c8ce00763b.