Photoacetylation of Diamondoids: Selectivities and Mechanism

Fokin, Andrey A.; Gunchenko, Pavel A.; Novikovsky, Anatoliy A.; Shubina, Tatyana E.; Chernyaev, B. V.; Dahl, Jeremy E. P.; Carlson, Robert M. K.; Yurchenko, A. G.; Schreiner, Peter R.

doi:10.1002/ejoc.200900600

Cited by 25 publications

(14 citation statements)

References 38 publications

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“…They form a homologous series of well-defined, saturated hydrocarbons and are the smallest possible units of diamond . Many of their properties, such as the chemical inertness, mechanical hardness, or optical transparency are comparable to those of diamond. − Besides choosing diamondoids with respect to their structures and sizes, − covalent functionalization tailors desired properties of diamondoids for various applications. − For instance, it was shown that the optical gap can be significantly tuned by covalent functionalization. − The inclusion of CC double bonds is another route to tune the electronic properties of diamondoids. − sp 2 –sp 3 Diamondoid oligomers have been synthesized recently . They exhibit an unsaturated bridge between diamondoids, with highly localized π and π* orbitals leading to a significant decrease of optical transition energies. − In the solid phase the diamondoid dimers form van der Waals crystals further lowering optical transition energies due to van der Waals interactions of adjacent molecules in the periodic lattice. , Tailoring the optical properties of diamondoid crystallites by the chemical functionalization of their constituents is therefore a possible path for new wide-gap semiconductors.…”

Section: Introductionmentioning

confidence: 99%

Electronic and Vibrational Properties of Diamondoid Oligomers

et al. 2017

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We analyzed the vibrational and electronic properties of diamondoid oligomers via resonance Raman spectroscopy. The compounds consist of lower diamondoids such as adamantane or diamantane that are interconnected with double bonds. Therefore, all oligomers have ethylene-like centers strongly influencing the character of the optical transitions. The double bond localizes the HOMO (highest occupied moluecular orbital) in between the diamondoids accompanied by a significant decrease of optical transition energies. Comparing Raman spectra of the compounds to pristine diamondoids, we find several characteristic modes originating from the ethylene moieties. Supported by DFT (density functional theory) computations, we attribute these modes to highly localized vibrations that can partially be derived from the vibrational modes of parent ethylene. We further observe two new Raman modes in the compounds: a dimer breathing mode and a rotational mode of the entire ethylene moieties.

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Section: Introductionmentioning

confidence: 99%

Electronic and Vibrational Properties of Diamondoid Oligomers

et al. 2017

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“…5 The extraordinary physical and chemical properties of diamondoids, such as low surface energies, high densities as well as hydrophobicities, thermal stabilities, and resistance to oxidation, 1,6 paved the way for the use of 1 and 2, which are the most accessible and readily synthesized diamondoids, also in polymer chemistry. 7 As nanometer-sized building blocks (0.5-2 nm) that can be selectively functionalized both at their periphery (CH bond substitutions) [8][9][10] and internally (by replacing the methylene groups with heteroatoms), 11 diamondoids possess unique properties with high potential value for nanotechnology. For instance, diamondoid thiols selfassembled on gold and silver metal surfaces are highly ordered 12 and display pronounced electron emission prop-erties (NEA, negative electron affinity), providing a source of nearly monochromatic photoemitted electrons.…”

mentioning

confidence: 99%

Synthesis of Diamondoid Carboxylic Acids

Fokina¹,

Tkachenko²,

Dahl³

et al. 2011

Synthesis

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Procedures for the synthesis of apical mono-, di-, and tricarboxylic acids of triamantane, [121]tetramantane, and [1(2,3)4]pentamantane, apical diacetic acids of diamantane and triamantane, as well as medial propionic acids of diamantane and triamantane were elaborated starting from the corresponding alcohols and bromides. The obtained diamondoid acids were characterized as their methyl ester derivatives. Diamondoids (nanodiamonds), which belong to a group of nanoscale carbon materials, are cage hydrocarbons with structures resembling the diamond lattice. 1 Adamantane (1), diamantane (2), and triamantane (3) belong to the lower diamondoids; the higher diamondoids, such as tetramantane (4) and pentamantane (5) show isomerism ( Figure 1). 2 Extensive studies of these hydrocarbons have been facilitated only recently after sizable amounts of diamondoids were found in oil, and by their successful isolation and isomer separation from deep natural gas condensates. 3 Adamantane (1), the first member of the diamondoid family, has been broadly studied and has found many practical applications. 4 The efficiency of adamantane amino derivatives as antiviral agents and for the treatment of diseases of the central nervous system has been well recognized. 5 The extraordinary physical and chemical properties of diamondoids, such as low surface energies, high densities as well as hydrophobicities, thermal stabilities, and resistance to oxidation, 1,6 paved the way for the use of 1 and 2, which are the most accessible and readily synthesized diamondoids, also in polymer chemistry. 7As nanometer-sized building blocks (0.5-2 nm) that can be selectively functionalized both at their periphery (CH bond substitutions) 8-10 and internally (by replacing the methylene groups with heteroatoms), 11 diamondoids possess unique properties with high potential value for nanotechnology. For instance, diamondoid thiols selfassembled on gold and silver metal surfaces are highly ordered 12 and display pronounced electron emission properties (NEA, negative electron affinity), providing a source of nearly monochromatic photoemitted electrons. 13 This makes them promising candidates for electron emission devices and in field-emission displays as well as in electron microscopes. 14 Suitably designed diamondoid derivatives have also been suggested for use in molecularscale electronics such as unimolecular rectifiers, where electron acceptors are covalently attached to functionalized diamondoids. Figure 1 Adamantane (1), diamantane (2), triamantane (3), [121]tetramantane (4), and [1(2,3)4]pentamantane (5) To make possible the selective derivatization of diamondoids and to develop applications that benefit from the attractive properties of these novel nanomaterials, the choice of functional groups is essential. For instance, in the area of metal-organic frameworks (MOFs) the first examples of hybrid inorganic-organic materials comprising diamondoids as rigid organic building blocks were presented recently. 15 Because diamondoids have welldefined three-dimen...

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“…Functionalized diamondoids obtained by regioselective reactions offer a wide range of possible shapes in three dimensions. [14][15][16]21,22 In order to specify the location and stereochemistry of substituents, the von Baeyer nomenclature enhanced by stereochemical descriptors as advocated here is the best available system.…”

Section: Stereochemical Aspects In Perimantanes That Have As Dualistsmentioning

confidence: 99%

Helical [n]catamantanes and all-trans-perhydroacenic [n]perimantanes: structures and von Baeyer IUPAC numbering of carbon atoms

Balaban¹,

Rücker²

2013

Arkivoc

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Abstract[n]Diamondoids are hydrocarbons whose carbon skeleton is a portion of the diamond lattice, and contains n adamantane cells (or units) sharing chair-shaped hexagons of carbon atoms. When centers of these adamantane units are connected by lines, the resulting construction is called the dualist of the diamondoid, and it also is similar to a portion of the diamond lattice. While these hydrocarbons can be distinguished by the Balaban-Schleyer nomenclature system, substituted derivatives are to be described by the IUPAC von Baeyer nomenclature that attributes a unique number (locant) to each carbon atom within a molecule. In this paper, von Baeyer names and corresponding atom numberings were obtained by the computer program POLCYC for members of two classes of diamondoids: [n]catamantanes whose dualists are tight helices, and [n]perimantanes whose dualists are all-trans-perhydroacenes; general numbering schemes were derived for these compound classes. The structures and some regularities in their structural properties are discussed.

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Photoacetylation of Diamondoids: Selectivities and Mechanism

Cited by 25 publications

References 38 publications

Electronic and Vibrational Properties of Diamondoid Oligomers

Electronic and Vibrational Properties of Diamondoid Oligomers

Synthesis of Diamondoid Carboxylic Acids

Helical [n]catamantanes and all-trans-perhydroacenic [n]perimantanes: structures and von Baeyer IUPAC numbering of carbon atoms

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