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Dodecahedrane

January 01, 1970

Dodecahedrane is a chemical compound, a hydrocarbon with formula C20H20, whose carbon atoms are arranged as the vertices (corners) of a regular dodecahedron. Each carbon is bound to three neighbouring carbon atoms and to a hydrogen atom. This compound is one of the three possible Platonic hydrocarbons, the other two being cubane and tetrahedrane.

Dodecahedrane
Names
IUPAC names
(C20-Ih)[5]fullerane
hexadecahydro-1,6,5,2,4,3-(epibutane[1,1,2,3,4,4]hexayl)dipentaleno[2,1,6-gha:2′,1′,6′-cde]pentalene
Systematic IUPAC name
undecacyclo[9.9.0.02,9.03,7.04,20.05,18.06,16.08,15.010,14.012,19.013,17]icosane
Identifiers
  • 4493-23-6 Y
3D model (JSmol)
  • Interactive image
  • Interactive image
1880116
ChEBI
  • CHEBI:33013 Y
ChemSpider
  • 109833 Y
1326921
  • 123218
UNII
  • FBO87C776P Y
  • DTXSID90196340
  • InChI=1S/C20H20/c1-2-5-7-3(1)9-10-4(1)8-6(2)12-11(5)17-13(7)15(9)19-16(10)14(8)18(12)20(17)19/h1-20H Y
    Key: OOHPORRAEMMMCX-UHFFFAOYSA-N Y
  • InChI=1/C20H20/c1-2-5-7-3(1)9-10-4(1)8-6(2)12-11(5)17-13(7)15(9)19-16(10)14(8)18(12)20(17)19/h1-20H
    Key: OOHPORRAEMMMCX-UHFFFAOYAM
  • C12C3C4C5C1C6C7C2C8C3C9C4C1C5C6C2C7C8C9C12
  • C31C%10C2C5C%11C6C8C(C1C9C4C7C(C2C34)C5C6C7C89)C%10%11
Properties
C20H20
Molar mass 260.380 g·mol−1
Melting point 430±10°C[1]
Related compounds
Related hydrocarbons
 Cubane
Tetrahedrane
Pagodane (an isomer of dodecahedrane)
Prismane
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)

Dodecahedrane does not occur in nature and has no significant uses. It was synthesized by Leo Paquette in 1982, primarily for the "aesthetically pleasing symmetry of the dodecahedral framework".[2]

For many years, dodecahedrane was the simplest real carbon-based molecule with full icosahedral symmetry. Buckminsterfullerene (C60), discovered in 1985, also has the same symmetry, but has three times as many carbons and 50% more atoms overall. The synthesis of the C20 fullerene C20 in 2000, from brominated dodecahedrane,[3] may have demoted C20H20 to second place.

Structure edit

The angle between the C-C bonds in each carbon atom is 108°, which is the angle between adjacent sides of a regular pentagon. That value is quite close to the 109.5° central angle of a regular tetrahedron—the ideal angle between the bonds on an atom that has sp3 hybridisation. As a result, there is minimal angle strain. However, the molecule has significant levels of torsional strain as a result of the eclipsed conformation along each edge of the structure.[4]

The molecule has perfect icosahedral (Ih) symmetry, as evidenced by its proton NMR spectrum in which all hydrogen atoms appear at a single chemical shift of 3.38 ppm. Unlike buckminsterfullerene, dodecahedrane has no delocalized electrons and hence has no aromaticity.

History edit

For over 30 years, several research groups actively pursued the total synthesis of dodecahedrane. A review article published in 1978 described the different strategies that existed up to then.[5] The first attempt was initiated in 1964 by R.B. Woodward with the synthesis of the compound triquinacene which was thought to be able to simply dimerize to dodecahedrane. Other groups were also in the race, for example that of Philip Eaton and Paul von Ragué Schleyer.

Leo Paquette's group at Ohio State University was the first to succeed, by a complex 29-step route that mostly builds the dodecahedral skeleton one ring at a time, and finally closes the last hole.[2]

In 1987, more versatile alternative synthesis route was found by the Horst Prinzbach's group.[6][7] Their approach was based on the isomerization pagodane, obtained from isodrin (isomer of aldrin) as starting material i.a. through [6+6]photocycloaddition. Schleyer had followed a similar approach in his synthesis of adamantane.

Following that idea, joint efforts of the Prinzbach team and the Schleyer group succeeded but obtained only 8% yield for the conversion at best. In the following decade the group greatly optimized that route, so that dodecahedrane could be obtained in multi-gram quantities. The new route also made it easier to obtain derivatives with selected substitutions and unsaturated carbon-carbon bonds. Two significant developments were the discovery of σ-bishomoaromaticity[8] and the formation of C20 fullerene from highly brominated dodecahedrane species.[3][9]

Synthesis edit

Original route edit

Paquette's 1982 organic synthesis takes about 29 steps with raw materials cyclopentadiene (2 equivalents 10 carbon atoms), dimethyl acetylenedicarboxylate (4 carbon atoms) and allyltrimethylsilane (2 equivalents, 6 carbon atoms).

In the first leg of the procedure [10] two molecules of cyclopentadiene 1 are coupled together by reaction with elemental sodium (forming the cyclopentadienyl complex) and iodine to dihydrofulvalene 2. Next up is a tandem Diels–Alder reaction with dimethyl acetylenedicarboxylate 3 with desired sequence pentadiene-acetylene-pentadiene as in symmetrical adduct 4. An equal amount of asymmetric pentadiene-pentadiene-acetylene compound (4b) is formed and discarded.

   
Dodecahedrane synthesis part I Dodecahedrane synthesis part II

In the next step of the sequence [11] iodine is temporarily introduced via an iodolactonization of the diacid of 4 to dilactone 5. The ester group is cleaved next by methanol to the halohydrin 6, the alcohol groups converted to ketone groups in 7 by Jones oxidation and the iodine groups reduced by a zinc-copper couple in 8.

   
Dodecahedrane synthesis part III Dodecahedrane synthesis part IV

The final 6 carbon atoms are inserted in a nucleophilic addition to the ketone groups of the carbanion 10 generated from allyltrimethylsilane 9 and n-butyllithium. In the next step the vinyl silane 11 reacts with peracetic acid in acetic acid in a radical substitution to the dilactone 12 followed by an intramolecular Friedel-Crafts alkylation with phosphorus pentoxide to diketone 13. This molecule contains all required 20 carbon atoms and is also symmetrical which facilitates the construction of the remaining 5 carbon-carbon bonds.

Reduction of the double bonds in 13 to 14 is accomplished with hydrogenation with palladium on carbon and that of the ketone groups to alcohol groups in 15 by sodium borohydride. Replacement of hydroxyl by chlorine in 17 via nucleophilic aliphatic substitution takes place through the dilactone 16 (tosyl chloride). The first C–C bond forming reaction is a kind of Birch alkylation (lithium, ammonia) with the immediate reaction product trapped with chloromethyl phenyl ether,[12] the other chlorine atom in 17 is simply reduced. This temporary appendix will in a later stage prevent unwanted enolization. The newly formed ketone group then forms another C–C bond by photochemical Norrish reaction to 19 whose alcohol group is induced to eliminate with TsOH to alkene 20.

   
Dodecahedrane synthesis part V Dodecahedrane synthesis part VI

The double bond is reduced with hydrazine and sequential diisobutylaluminum hydride reduction and pyridinium chlorochromate oxidation of 21 forms the aldehyde 22. A second Norrish reaction then adds another C–C bond to alcohol 23 and having served its purpose the phenoxy tail is removed in several steps: a Birch reduction to diol 24, oxidation with pyridinium chlorochromate to ketoaldehyde 25 and a reverse Claisen condensation to ketone 26. A third Norrish reaction produces alcohol 27 and a second dehydration 28 and another reduction 29 at which point the synthesis is left completely without functional groups. The missing C-C bond is put in place by hydrogen pressurized dehydrogenation with palladium on carbon at 250 °C to dodecahedrane 30.

Pagodane route edit

In Prinzbach's optimized route from pagodane to dodecahedrane, the original low-yielding isomerization of parent pagodane to dodecahedrane is replaced by a longer but higher yielding sequence - which nevertheless still relies heavily on pagodane derivatives. In the scheme below, the divergence from the original happens after compound 16.

 
Optimized route to dodecahedrane

Derivatives edit

A variety of dodecahedrane derivatives have been synthesized and reported in the literature.

Hydrogen substitution edit

Substitution of all 20 hydrogens by fluorine atoms yields the relatively unstable perfluorododecahedrane C20F20, which was obtained in milligram quantities. Trace amounts of the analogous perchlorododecahedrane C20Cl20 were obtained, among other partially chlorinated derivatives, by reacting C20H20 dissolved in liquid chlorine under pressure at about 140 °C and under intense light for five days. Complete replacement by heavier halogens seems increasingly difficult due to their larger size. Half or more of the hydrogen atoms can be substituted by hydroxyl groups to yield polyols, but the extreme compound C20(OH)20 remained elusive as of 2006.[13] Amino-dodecahedranes comparable to amantadine have been prepared, but were more toxic and with weaker antiviral effects.[14]

Annulated dodecahedrane structures have been proposed.[15][16]

Encapsulation edit

Molecules whose framework forms a closed cage, like dodecahedrane and buckminsterfullerene, can encapsulate atoms and small molecules in the hollow space within. Those insertions are not chemically bonded to the caging compound, but merely mechanically trapped in it.

Cross, Saunders and Prinzbach succeeded in encapsulating helium atoms in dodecahedrane by shooting He+ ions at a film of the compound. They obtained microgram quantities of He@C20H20 (the "@" being the standard notation for encapsulation), which they described as a quite stable substance.[17] The molecule has been described as "the world's smallest helium balloon".[18]

References edit

  1. ^ Lindberg, Thomas (2012-12-02). Strategies and Tactics in Organic Synthesis. ISBN 9780323152938.
  2. ^ a b Ternansky, Robert J.; Balogh, Douglas W.; Paquette, Leo A. (1982). "Dodecahedrane". J. Am. Chem. Soc. 104 (16): 4503–4504. doi:10.1021/ja00380a040.
  3. ^ a b Prinzbach, Horst; Weiler, Andreas; Landenberger, Peter; Wahl, Fabian; Wörth, Jürgen; Scott, Lawrence T.; Gelmont, Marc; Olevano, Daniela; Issendorff, Bernd von (7 September 2000). "Gas-phase production and photoelectron spectroscopy of the smallest fullerene, C20". Nature. 407 (6800): 60–63. Bibcode:2000Natur.407...60P. doi:10.1038/35024037. PMID 10993070. S2CID 4355045.
  4. ^ Paquette, Leo (1982). "Dodecahedrane-The chemical transliteration of Plato's universe (A Review)". Proc Natl Acad Sci U S A. 79 (14): 4495–4500. Bibcode:1982PNAS...79.4495P. doi:10.1073/pnas.79.14.4495. PMC 346698.
  5. ^ Eaton, Philip E. (1979). "Towards dodecahedrane". Tetrahedron. 35 (19): 2189–2223. doi:10.1016/0040-4020(79)80114-3.
  6. ^ Fessner, Wolf-Dieter; Murty, Bulusu A. R. C.; Prinzbach, Horst (1987). "The Pagodane Route to Dodecahedranes – Thermal, Reductive, and Oxidative Transformations of Pagodanes". Angew. Chem. Int. Ed. Engl. 26 (5): 451–452. doi:10.1002/anie.198704511.
  7. ^ Fessner, Wolf-Dieter; Murty, Bulusu A. R. C.; Wörth, Jürgen; Hunkler, Dieter; Fritz, Hans; Prinzbach, Horst; Roth, Wolfgang D.; Schleyer, Paul von Ragué; McEwen, Alan B.; Maier, Wilhelm F. (1987). "Dodecahedranes from [1.1.1.1]Pagodanes". Angew. Chem. Int. Ed. Engl. 26 (5): 452–454. doi:10.1002/anie.198704521.
  8. ^ Prakash, G. K. S.; Krishnamurthy, V. V.; Herges, R.; Bau, R.; Yuan, H.; Olah, G. A.; Fessner, W.-D.; Prinzbach, H. (1988). "[1.1.1.1]- and [2.2.1.1]Pagodane Dications: Frozen Two-Electron Woodward–Hoffmann Transition State Models". J. Am. Chem. Soc. 110 (23): 7764–7772. doi:10.1021/ja00231a029.
  9. ^ Prinzbach, H.; Wahl, F.; Weiler, A.; Landenberger, P.; Wörth, J.; Scott, L. T.; Gelmont, M.; Olevano, D.; Sommer, F.; Issendorff, B. von (2006). "C20 Carbon Clusters: Fullerene–Boat–Sheet Generation, Mass Selection, PE Characterization". Chem. Eur. J. 12 (24): 6268–6280. doi:10.1002/chem.200501611. PMID 16823785.
  10. ^ Paquette, Leo A.; Wyvratt, Matthew J. (1974). "Domino Diels–Alder reactions. I. Applications to the rapid construction of polyfused cyclopentanoid systems". J. Am. Chem. Soc. 96 (14): 4671–4673. doi:10.1021/ja00821a052.
  11. ^ Paquette, Leo A.; Wyvratt, Matthew J.; Schallner, Otto; Muthard, Jean L.; Begley, William J.; Blankenship, Robert M.; Balogh, Douglas (1979). "Topologically spherical molecules. Synthesis of a pair of C2-symmetric hexaquinane dilactones and insights into their chemical reactivity. An efficient π-mediated 1,6-dicarbonyl reduction". J. Org. Chem. 44 (21): 3616–3630. doi:10.1021/jo01335a003.
  12. ^ Paquette, Leo A.; Ternansky, Robert J.; Balogh, Douglas W.; Kentgen, Gary (1983). "Total synthesis of dodecahedrane". J. Am. Chem. Soc. 105 (16): 5446–5450. doi:10.1021/ja00354a043.
  13. ^ Wahl, Fabian; Weiler, Andreas; Landenberger, Peter; Sackers, Emmerich; Voss, Torsten; Haas, Alois; Lieb, Max; Hunkler, Dieter; Wörth, Jürgen; Knothe, Lothar; Prinzbach, Horst (2006). "Towards Perfunctionalized Dodecahedranes—En Route to C20 Fullerene". Chem. Eur. J. 12 (24): 6255–6267. doi:10.1002/chem.200501618. PMID 16807931.
  14. ^ Weber JC, Paquette LA. Synthesis of amino-substituted dodecahedranes, secododecahedranes, and homododecahedranes, and their antiviral relationship to 1-aminoadamantane. J. Org. Chem. 1988; 53(22): 5315-5320. doi:10.1021/jo00257a021
  15. ^ Banfalvia, Gaspar (2014). "Dodecahedrane minibead polymers". RSC Adv. 4 (6): 3003–3008. Bibcode:2014RSCAd...4.3003B. doi:10.1039/C3RA43628D.
  16. ^ Liu, Feng-Ling (26 July 2004). "DFT study on a molecule C25H20 with a dodecahedrane cage and a pentaprismane cage sharing the same pentagon". J. Mol. Struct.: Theochem. 681 (1–3): 51–55. doi:10.1016/j.theochem.2004.04.051.
  17. ^ Cross, R. James; Saunders, Martin; Prinzbach, Horst (1999). "Putting Helium Inside Dodecahedrane". Org. Lett. 1 (9): 1479–1481. doi:10.1021/ol991037v.
  18. ^ Putz, Mihai V.; Mirica, Marius Constantin (2016). "4". Sustainable Nanosystems Development, Properties, and Applications. IGI Global. p. 124. ISBN 978-1-5225-0493-1.

External links edit

  • Paquette's dodecahedrane synthesis at SynArchive.com
  • Full text of Paquette's paper

January 01, 1970
dodecahedrane, chemical, compound, hydrocarbon, with, formula, c20h20, whose, carbon, atoms, arranged, vertices, corners, regular, dodecahedron, each, carbon, bound, three, neighbouring, carbon, atoms, hydrogen, atom, this, compound, three, possible, platonic,. Dodecahedrane is a chemical compound a hydrocarbon with formula C20H20 whose carbon atoms are arranged as the vertices corners of a regular dodecahedron Each carbon is bound to three neighbouring carbon atoms and to a hydrogen atom This compound is one of the three possible Platonic hydrocarbons the other two being cubane and tetrahedrane Dodecahedrane Names IUPAC names C20 Ih 5 fulleranehexadecahydro 1 6 5 2 4 3 epibutane 1 1 2 3 4 4 hexayl dipentaleno 2 1 6 gha 2 1 6 cde pentalene Systematic IUPAC name undecacyclo 9 9 0 02 9 03 7 04 20 05 18 06 16 08 15 010 14 012 19 013 17 icosane Identifiers CAS Number 4493 23 6 Y 3D model JSmol Interactive imageInteractive image Beilstein Reference 1880116 ChEBI CHEBI 33013 Y ChemSpider 109833 Y Gmelin Reference 1326921 PubChem CID 123218 UNII FBO87C776P Y CompTox Dashboard EPA DTXSID90196340 InChI InChI 1S C20H20 c1 2 5 7 3 1 9 10 4 1 8 6 2 12 11 5 17 13 7 15 9 19 16 10 14 8 18 12 20 17 19 h1 20H YKey OOHPORRAEMMMCX UHFFFAOYSA N YInChI 1 C20H20 c1 2 5 7 3 1 9 10 4 1 8 6 2 12 11 5 17 13 7 15 9 19 16 10 14 8 18 12 20 17 19 h1 20HKey OOHPORRAEMMMCX UHFFFAOYAM SMILES C12C3C4C5C1C6C7C2C8C3C9C4C1C5C6C2C7C8C9C12C31C 10C2C5C 11C6C8C C1C9C4C7C C2C34 C5C6C7C89 C 10 11 Properties Chemical formula C 20H 20 Molar mass 260 380 g mol 1 Melting point 430 10 C 1 Related compounds Related hydrocarbons CubaneTetrahedranePagodane an isomer of dodecahedrane Prismane Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Y verify what is Y N Infobox references Dodecahedrane does not occur in nature and has no significant uses It was synthesized by Leo Paquette in 1982 primarily for the aesthetically pleasing symmetry of the dodecahedral framework 2 For many years dodecahedrane was the simplest real carbon based molecule with full icosahedral symmetry Buckminsterfullerene C60 discovered in 1985 also has the same symmetry but has three times as many carbons and 50 more atoms overall The synthesis of the C20 fullerene C20 in 2000 from brominated dodecahedrane 3 may have demoted C20H20 to second place Contents 1 Structure 2 History 3 Synthesis 3 1 Original route 3 2 Pagodane route 4 Derivatives 4 1 Hydrogen substitution 4 2 Encapsulation 5 References 6 External linksStructure editThe angle between the C C bonds in each carbon atom is 108 which is the angle between adjacent sides of a regular pentagon That value is quite close to the 109 5 central angle of a regular tetrahedron the ideal angle between the bonds on an atom that has sp3 hybridisation As a result there is minimal angle strain However the molecule has significant levels of torsional strain as a result of the eclipsed conformation along each edge of the structure 4 The molecule has perfect icosahedral Ih symmetry as evidenced by its proton NMR spectrum in which all hydrogen atoms appear at a single chemical shift of 3 38 ppm Unlike buckminsterfullerene dodecahedrane has no delocalized electrons and hence has no aromaticity History editFor over 30 years several research groups actively pursued the total synthesis of dodecahedrane A review article published in 1978 described the different strategies that existed up to then 5 The first attempt was initiated in 1964 by R B Woodward with the synthesis of the compound triquinacene which was thought to be able to simply dimerize to dodecahedrane Other groups were also in the race for example that of Philip Eaton and Paul von Rague Schleyer Leo Paquette s group at Ohio State University was the first to succeed by a complex 29 step route that mostly builds the dodecahedral skeleton one ring at a time and finally closes the last hole 2 In 1987 more versatile alternative synthesis route was found by the Horst Prinzbach s group 6 7 Their approach was based on the isomerization pagodane obtained from isodrin isomer of aldrin as starting material i a through 6 6 photocycloaddition Schleyer had followed a similar approach in his synthesis of adamantane Following that idea joint efforts of the Prinzbach team and the Schleyer group succeeded but obtained only 8 yield for the conversion at best In the following decade the group greatly optimized that route so that dodecahedrane could be obtained in multi gram quantities The new route also made it easier to obtain derivatives with selected substitutions and unsaturated carbon carbon bonds Two significant developments were the discovery of s bishomoaromaticity 8 and the formation of C20 fullerene from highly brominated dodecahedrane species 3 9 Synthesis editOriginal route edit Paquette s 1982 organic synthesis takes about 29 steps with raw materials cyclopentadiene 2 equivalents 10 carbon atoms dimethyl acetylenedicarboxylate 4 carbon atoms and allyltrimethylsilane 2 equivalents 6 carbon atoms In the first leg of the procedure 10 two molecules of cyclopentadiene 1 are coupled together by reaction with elemental sodium forming the cyclopentadienyl complex and iodine to dihydrofulvalene 2 Next up is a tandem Diels Alder reaction with dimethyl acetylenedicarboxylate 3 with desired sequence pentadiene acetylene pentadiene as in symmetrical adduct 4 An equal amount of asymmetric pentadiene pentadiene acetylene compound 4b is formed and discarded nbsp nbsp Dodecahedrane synthesis part I Dodecahedrane synthesis part II In the next step of the sequence 11 iodine is temporarily introduced via an iodolactonization of the diacid of 4 to dilactone 5 The ester group is cleaved next by methanol to the halohydrin 6 the alcohol groups converted to ketone groups in 7 by Jones oxidation and the iodine groups reduced by a zinc copper couple in 8 nbsp nbsp Dodecahedrane synthesis part III Dodecahedrane synthesis part IV The final 6 carbon atoms are inserted in a nucleophilic addition to the ketone groups of the carbanion 10 generated from allyltrimethylsilane 9 and n butyllithium In the next step the vinyl silane 11 reacts with peracetic acid in acetic acid in a radical substitution to the dilactone 12 followed by an intramolecular Friedel Crafts alkylation with phosphorus pentoxide to diketone 13 This molecule contains all required 20 carbon atoms and is also symmetrical which facilitates the construction of the remaining 5 carbon carbon bonds Reduction of the double bonds in 13 to 14 is accomplished with hydrogenation with palladium on carbon and that of the ketone groups to alcohol groups in 15 by sodium borohydride Replacement of hydroxyl by chlorine in 17 via nucleophilic aliphatic substitution takes place through the dilactone 16 tosyl chloride The first C C bond forming reaction is a kind of Birch alkylation lithium ammonia with the immediate reaction product trapped with chloromethyl phenyl ether 12 the other chlorine atom in 17 is simply reduced This temporary appendix will in a later stage prevent unwanted enolization The newly formed ketone group then forms another C C bond by photochemical Norrish reaction to 19 whose alcohol group is induced to eliminate with TsOH to alkene 20 nbsp nbsp Dodecahedrane synthesis part V Dodecahedrane synthesis part VI The double bond is reduced with hydrazine and sequential diisobutylaluminum hydride reduction and pyridinium chlorochromate oxidation of 21 forms the aldehyde 22 A second Norrish reaction then adds another C C bond to alcohol 23 and having served its purpose the phenoxy tail is removed in several steps a Birch reduction to diol 24 oxidation with pyridinium chlorochromate to ketoaldehyde 25 and a reverse Claisen condensation to ketone 26 A third Norrish reaction produces alcohol 27 and a second dehydration 28 and another reduction 29 at which point the synthesis is left completely without functional groups The missing C C bond is put in place by hydrogen pressurized dehydrogenation with palladium on carbon at 250 C to dodecahedrane 30 Pagodane route edit In Prinzbach s optimized route from pagodane to dodecahedrane the original low yielding isomerization of parent pagodane to dodecahedrane is replaced by a longer but higher yielding sequence which nevertheless still relies heavily on pagodane derivatives In the scheme below the divergence from the original happens after compound 16 nbsp Optimized route to dodecahedraneDerivatives editA variety of dodecahedrane derivatives have been synthesized and reported in the literature Hydrogen substitution edit Substitution of all 20 hydrogens by fluorine atoms yields the relatively unstable perfluorododecahedrane C20F20 which was obtained in milligram quantities Trace amounts of the analogous perchlorododecahedrane C20Cl20 were obtained among other partially chlorinated derivatives by reacting C20H20 dissolved in liquid chlorine under pressure at about 140 C and under intense light for five days Complete replacement by heavier halogens seems increasingly difficult due to their larger size Half or more of the hydrogen atoms can be substituted by hydroxyl groups to yield polyols but the extreme compound C20 OH 20 remained elusive as of 2006 13 Amino dodecahedranes comparable to amantadine have been prepared but were more toxic and with weaker antiviral effects 14 Annulated dodecahedrane structures have been proposed 15 16 Encapsulation edit Molecules whose framework forms a closed cage like dodecahedrane and buckminsterfullerene can encapsulate atoms and small molecules in the hollow space within Those insertions are not chemically bonded to the caging compound but merely mechanically trapped in it Cross Saunders and Prinzbach succeeded in encapsulating helium atoms in dodecahedrane by shooting He ions at a film of the compound They obtained microgram quantities of He C20H20 the being the standard notation for encapsulation which they described as a quite stable substance 17 The molecule has been described as the world s smallest helium balloon 18 References edit Lindberg Thomas 2012 12 02 Strategies and Tactics in Organic Synthesis ISBN 9780323152938 a b Ternansky Robert J Balogh Douglas W Paquette Leo A 1982 Dodecahedrane J Am Chem Soc 104 16 4503 4504 doi 10 1021 ja00380a040 a b Prinzbach Horst Weiler Andreas Landenberger Peter Wahl Fabian Worth Jurgen Scott Lawrence T Gelmont Marc Olevano Daniela Issendorff Bernd von 7 September 2000 Gas phase production and photoelectron spectroscopy of the smallest fullerene C20 Nature 407 6800 60 63 Bibcode 2000Natur 407 60P doi 10 1038 35024037 PMID 10993070 S2CID 4355045 Paquette Leo 1982 Dodecahedrane The chemical transliteration of Plato s universe A Review Proc Natl Acad Sci U S A 79 14 4495 4500 Bibcode 1982PNAS 79 4495P doi 10 1073 pnas 79 14 4495 PMC 346698 Eaton Philip E 1979 Towards dodecahedrane Tetrahedron 35 19 2189 2223 doi 10 1016 0040 4020 79 80114 3 Fessner Wolf Dieter Murty Bulusu A R C Prinzbach Horst 1987 The Pagodane Route to Dodecahedranes Thermal Reductive and Oxidative Transformations of Pagodanes Angew Chem Int Ed Engl 26 5 451 452 doi 10 1002 anie 198704511 Fessner Wolf Dieter Murty Bulusu A R C Worth Jurgen Hunkler Dieter Fritz Hans Prinzbach Horst Roth Wolfgang D Schleyer Paul von Rague McEwen Alan B Maier Wilhelm F 1987 Dodecahedranes from 1 1 1 1 Pagodanes Angew Chem Int Ed Engl 26 5 452 454 doi 10 1002 anie 198704521 Prakash G K S Krishnamurthy V V Herges R Bau R Yuan H Olah G A Fessner W D Prinzbach H 1988 1 1 1 1 and 2 2 1 1 Pagodane Dications Frozen Two Electron Woodward Hoffmann Transition State Models J Am Chem Soc 110 23 7764 7772 doi 10 1021 ja00231a029 Prinzbach H Wahl F Weiler A Landenberger P Worth J Scott L T Gelmont M Olevano D Sommer F Issendorff B von 2006 C20 Carbon Clusters Fullerene Boat Sheet Generation Mass Selection PE Characterization Chem Eur J 12 24 6268 6280 doi 10 1002 chem 200501611 PMID 16823785 Paquette Leo A Wyvratt Matthew J 1974 Domino Diels Alder reactions I Applications to the rapid construction of polyfused cyclopentanoid systems J Am Chem Soc 96 14 4671 4673 doi 10 1021 ja00821a052 Paquette Leo A Wyvratt Matthew J Schallner Otto Muthard Jean L Begley William J Blankenship Robert M Balogh Douglas 1979 Topologically spherical molecules Synthesis of a pair of C2 symmetric hexaquinane dilactones and insights into their chemical reactivity An efficient p mediated 1 6 dicarbonyl reduction J Org Chem 44 21 3616 3630 doi 10 1021 jo01335a003 Paquette Leo A Ternansky Robert J Balogh Douglas W Kentgen Gary 1983 Total synthesis of dodecahedrane J Am Chem Soc 105 16 5446 5450 doi 10 1021 ja00354a043 Wahl Fabian Weiler Andreas Landenberger Peter Sackers Emmerich Voss Torsten Haas Alois Lieb Max Hunkler Dieter Worth Jurgen Knothe Lothar Prinzbach Horst 2006 Towards Perfunctionalized Dodecahedranes En Route to C20 Fullerene Chem Eur J 12 24 6255 6267 doi 10 1002 chem 200501618 PMID 16807931 Weber JC Paquette LA Synthesis of amino substituted dodecahedranes secododecahedranes and homododecahedranes and their antiviral relationship to 1 aminoadamantane J Org Chem 1988 53 22 5315 5320 doi 10 1021 jo00257a021 Banfalvia Gaspar 2014 Dodecahedrane minibead polymers RSC Adv 4 6 3003 3008 Bibcode 2014RSCAd 4 3003B doi 10 1039 C3RA43628D Liu Feng Ling 26 July 2004 DFT study on a molecule C25H20 with a dodecahedrane cage and a pentaprismane cage sharing the same pentagon J Mol Struct Theochem 681 1 3 51 55 doi 10 1016 j theochem 2004 04 051 Cross R James Saunders Martin Prinzbach Horst 1999 Putting Helium Inside Dodecahedrane Org Lett 1 9 1479 1481 doi 10 1021 ol991037v Putz Mihai V Mirica Marius Constantin 2016 4 Sustainable Nanosystems Development Properties and Applications IGI Global p 124 ISBN 978 1 5225 0493 1 External links editPaquette s dodecahedrane synthesis at SynArchive com 2D and 3D models of dodecahedrane and cuneane assemblies Full text of Paquette s paper Retrieved from https en wikipedia org w index php title Dodecahedrane amp oldid 1209396815, wikipedia, wiki, book, books, library,

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