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Carbon nanothread

January 01, 1970

A carbon nanothread (also called diamond nanothread) is a sp3-bonded, one-dimensional carbon crystalline nanomaterial. The tetrahedral sp3-bonding of its carbon is similar to that of diamond. Nanothreads are only a few atoms across, more than 300,000 times thinner than a human hair. They consist of a stiff, strong carbon core surrounded by hydrogen atoms. Carbon nanotubes, although also one-dimensional nanomaterials, in contrast have sp2-carbon bonding as is found in graphite. The smallest carbon nanothread has a diameter of only 0.2 nanometers, much smaller than the diameter of a single-wall carbon nanotube. [1]

Synthesis edit

Nanothreads are synthesized by compressing liquid benzene to an extreme pressure of 20 GPa (around 200,000 times the air pressure at the surface of the Earth), and then slowly relieving that pressure.[2] The mechanochemical[3] synthesis reaction can be considered a form of organic solid state chemistry. The benzene chains form extremely thin, tight rings of carbon that are structurally similar to diamonds.[4] Researchers at Cornell University have traced pathways from benzene to nanothreads, which may involve a series of organic [4+2] cycloaddition reactions along stacks of benzene molecules, followed by further reactions of unsaturated bonds.[5] Recently synthesis of macroscopic single crystal arrays of nanothreads hundreds of microns in size has been reported.[3] The order and lack of grain boundaries in single crystals is often very desirable because it facilitates both applications and characterization. In contrast, carbon nanotubes form only thin crystalline ropes. Control of the rate of compression and/or decompression appears to be important to the synthesis of polycrystalline and single crystal nanothreads.[2][3] Slow compression/decompression may favor low energy reaction pathways.[3] If the synthesis pressure for nanothreads can be reduced to 5 to 6 GPa, which is the pressure used for synthesis of industrial diamond, production on a large scale of >106 kg/yr would be possible. Recent advance on using strained cage-like molecules such as cubane as a precursor has successfully brought down the synthesis pressure to 12 GPa. Expanding the precursor library to non-aromatic, strained molecules offers new avenues to explore scalable production of carbon nanothreads.[6]

The formation of nanothread crystals appears to be guided by uniaxial stress (mechanical stress in a particular single direction), to which the nanothreads consistently align.[3] Reaction to form the crystals is not topochemical,[7] as it involves a major rearrangement from a lower symmetry monoclinic benzene crystal to a higher symmetry hexagonal nanothread crystal. Topochemical reactions generally require commensuration between the periodicities and interatomic distances between reactant and product. The distances between benzene molecules with van der Waals separations between them must shrink by 40% or more as the short, strong covalent carbon-carbon bonds between them form during the nanothread synthesis reaction. Such large changes in geometry usual break up crystal order, but the nanothread reaction instead creates it. Even polycrystalline benzene reacts to form macroscopic single crystal packings of nanothreads hundreds of microns across.[3] Topochemical solid state reactions such as the formation of single crystal polydiacetylenes from diacetylenes usually require a single crystal reactant to form a single crystal product.

The impetus for the formation of a hexagonal crystal appears to be the packing of circular cross section threads.[3] The details of how it is possible to transform from a monoclinic benzene crystal to a hexagonal nanothread crystal are not yet fully understood. Further development of the theory of the effect of pressure on reactions may help.[8]

Organic synthesis efforts towards polytwistane nanothreads have been reported.[9]

 
Rotating polytwistane, a prototypical nanothread structure.[10][11] Black atoms are carbon. Light grey atoms are hydrogen.
 
Polytwistane crystal viewed down its hexagonal c axis. Black atoms are carbon and pink atoms are hydrogen. The length of the threads is going into the page, showing their circular cross section and hexagonal packing that (experimentally) extends over hundreds of microns in crystals. The outline of the hexagonal unit cell is shown in blue. These crystals exfoliate into bundles of nanothreads.[3]

History edit

In popular culture, diamond threads were first described by Arthur C. Clarke in his sci-fi novel The Fountains of Paradise set in the 22nd century, written in 1979.

Nanothreads were first investigated theoretically in 2001 by researchers at Penn State University[12] and later by researchers at Cornell University.[13] In 2014, researchers at Penn State University created the first sp3-carbon nanothreads in collaboration with Oak Ridge National Laboratory and the Carnegie Institution for Science.[2] Prior to 2014, and despite a century of investigation, benzene was thought to produce only hydrogenated amorphous carbon when compressed.[14] As of 2015, threads at least 90 nanometers in length had been created (compared to .5 meters for CNTs).

Structure edit

Since “diamond nanothreads” are sp3-bonded and one-dimensional they are unique in the matrix of hybridization (sp2/sp3) and dimensionality (0D/1D/2D/3D) for carbon nanomaterials.[15]

Assuming a topological unit cell of one or two benzene rings with at least two bonds interconnecting each adjacent pair of rings, 50 topologically distinct nanothreads have been enumerated. 15 of these are within 80 meV/carbon atom of the most stable member.[11] Some of the more commonly discussed nanothread structures are known informally as polytwistane, tube (3,0), and Polymer I. Polytwistane is chiral.[11][10] Tube (3,0) can be thought of as the thinnest possible thread that can be carved out of the diamond structure, consisting of stacked cyclohexane rings.[12] Polymer I was predicted to form from benzene at high pressure.[13]

Although there is compelling evidence from two dimensional X-ray diffraction patterns, transmission electron diffraction, and solid-state nuclear magnetic resonance (NMR) for a structure consisting of hexagonally packed crystals of 6.5 Angstrom diameter nanothreads with largely (75 to 80%) sp3-bonding,[2][3] the atomic structure of nanothreads is still under investigation. Nanothreads have also been observed by transmission electron microscopy.[2] Individual threads have been observed to pack in hexagonal crystals and layer-lines indicative of order along their length have been observed.[16]

Nanothreads have also been classified by their degree of saturation.[5] Fully saturated degree 6 nanothreads have no double bonds remaining. Three bonds form between each pair of benzene molecules. Degree 4 nanothreads have a double bond remaining from benzene and thus only two bonds formed between each pair of benzene molecules. Degree 2 have two double bonds remaining. Unless otherwise specified the term nanothread is assumed to refer to a degree six structure.

NMR has revealed that nanothread crystals consist of both degree 6 and degree 4 threads.[17] Moreover, spin diffusion experiments show that the sections of the threads that are fully saturated degree 6 must be at least 2.5 nm long, if not longer. NMR also shows that no second hydrocarbon or carbon phase is present in nanothread crystals. Thus all of the sp2 carbon is either in degree 4 nanothreads or small amounts of aromatic linker molecules, or even smaller amounts of C=O groups. NMR provides the chemical structural information necessary to refine syntheses towards pure degree 6 nanothreads, which are stronger than the partially saturated ones.[18]

Carbon nitride nanothreads edit

Pyridine compressed slowly under pressure forms carbon nitride C5H5N nanothread crystals.[19] They exhibit the six-fold diffraction "signature" of nanothread formation. NMR, chemical analysis and infrared spectroscopy provide further evidence for the synthesis of nanothreads from pyridine. Pyridine nanothreads incorporate significant amounts of nitrogen directly into their backbone. In contrast sp2 carbon nanotubes can only be doped with a small amount of nitrogen. A wide range of other functionalized nanothreads may be possible,[20] as well as nanothreads from polycyclic aromatic hydrocarbon molecules.[21]

Smallest nanothreads edit

Extending the ability to design and create nanothread architecture from a non-aromatic, saturated molecule has been a recent interest in order to achieve an entirely sp3-bonded nanothread structure. Hypothetical nanothread architectures built from the smallest diamondoids (adamantane) have been proposed to have higher mechanical strength than benzene nanothreads.[22] The first experimental synthesis of a novel purely sp3 bonded one-dimensional carbon nanomaterial is realized via an endogenous solid-state polymerization of cubane. Pre-arranged cubane monomers in the bulk crystal undergo diradical polymerization guided by applied uniaxial stress, similar to benzene, produce a single-crystalline carbon nanomaterial. The cubane-derived nanothread exhibits a linear diamond structure with subnanometre-diameter of 0.2 nm, which is considered as the smallest member in the carbon nanothread family; thus, they promise to form the stiffest one-dimensional system known.[23]

Properties edit

Every type of nanothread has a very high Young's modulus (stiffness). The value for the strongest type of nanothread is around 900 GPa compared to steel at 200 GPa and diamond at over 1,200 GPa.[24] The strength of carbon nanothreads may rival or exceed that of carbon nanotubes (CNTs). Molecular dynamics and Density functional theory simulations have indicated a stiffness on the order of carbon nanotubes (approx. 850 GPa) and a specific strength of approx. 4 × 107 N·m/kg.[25][18]

Much as graphite exfoliates into sheets and ultimately graphene, nanothread crystals exfoliate into fibers, consistent with their structure consisting of stiff, straight threads with a persistence length of ~100 nm[25] that are held together with van der Waals forces. These fibers exhibit birefringence, as would be expected from their low dimensional character.[3] In contrast, most polymers are much more flexible and often fold into crystalline lamella (see Crystallization of polymers) rather than forming into crystals that readily exfoliate.

Modeling suggests certain nanothreads may be auxetic, with a negative Poisson ratio.[26] The thermal conductivity of nanothreads has been modeled.[27][28][29] Modeling indicates their Bandgaps are tunable with strain over a wide range.[30] The electrical conductivity of fully saturated nanothreads, driven by topology, may be much higher than expected.[31]

Potential applications edit

Nanothreads can be thought of essentially as "flexible diamond". The extremely high specific strength predicted for them by modeling has attracted attention for applications such as space elevators and would be useful in other applications related to transportation, aerospace, and sports equipment. They may uniquely combine extreme strength, flexibility, and resilience.[25][32] Chemically substituted nanothreads may facilitate load transfer between neighbors through covalent bonding to transfer their mechanical strength to a surrounding matrix.[2] Modeling also suggests that the kinks associated with Stone-Wales transformations in nanothreads may facilitate interfacial load transfer to a surrounding matrix, making them useful for high strength composites.[33] In contrast to carbon nanotubes, bonds to the exterior of nanothreads need not disrupt their carbon core because only three of the four tetrahedral bonds are needed form it. The “extra” bond usually formed to hydrogen could be instead be linked to another nanothread or another molecule or atom.[2] Nanothreads may thus be thought of as "hybrids" that are both hydrocarbon molecules and carbon nanomaterials. Bonds to carbon nanotubes require their carbon to change from near planar sp2-bonding to tetrahedral sp3-bonding, thus disrupting their tubular geometry and possibly weakening them. Nanothreads may be less susceptible to loss of strength through defects than carbon nanotubes.[25] Thus far the extreme strength predicted for carbon nanotubes has largely not been realized in practical applications because of issues with load transfer to the surroundings and defects at various length scales from that of atoms on up.

Exfoliation into individual nanothreads may be possible, facilitating further functionalization and assembly into functional materials.[3] Theory indicates that "caged saturated hydrocarbons offering multiple σ-conductance channels (such as nanothreads) afford transmission far beyond what could be expected based upon conventional superposition laws, particularly if these pathways are composed entirely from quaternary carbon atoms."[34]

The carbon core of nanothreads is very stiff relative to the backbone of conventional polymers. They should thus be able to precisely orient molecular functions attached along their length (by substitution of hydrogen) relative to each other and to heteroatoms or unsaturated bonds in their backbone. These features may enable biological applications,[35] for example. Defects, functional groups, and/or heteroatoms[20] incorporated either into or exterior to the backbone of nanothreads with controlled orientation and distance between them may allow for robust, well controlled fluorescence. Doping and incorporation of heteroatoms such as nitrogen or boron into the nanothread backbone may allow for enhanced conducting or semiconducting properties[18] of nanothreads that allow for application as photocatalysts, electron emitters,[2] or possibly superconductors.

Modeling suggests carbon nanothread resonators exhibit low dissipation and may be useful as chemical sensors that can detect very small mass changes.[36]

Energy storage edit

Simulations show some achiral nanothread bundles may have specific energy density (when twisted) higher than lithium batteries.[37]

See also edit

External links edit

  • Forget Graphene and Carbon Nanotubes, Get Ready for Diamond Nanothread technologyreview.com
  • Synthesizing Carbon Nanothreads from Benzene spie.org
  • Liquid Benzene Squeezed to Form Diamond Nanothreads Scientific American
  • Carbon Nanothread Bibliography
  • Center for Nanothread Chemistry

References edit

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January 01, 1970
carbon, nanothread, carbon, nanothread, also, called, diamond, nanothread, bonded, dimensional, carbon, crystalline, nanomaterial, tetrahedral, bonding, carbon, similar, that, diamond, nanothreads, only, atoms, across, more, than, times, thinner, than, human, . A carbon nanothread also called diamond nanothread is a sp3 bonded one dimensional carbon crystalline nanomaterial The tetrahedral sp3 bonding of its carbon is similar to that of diamond Nanothreads are only a few atoms across more than 300 000 times thinner than a human hair They consist of a stiff strong carbon core surrounded by hydrogen atoms Carbon nanotubes although also one dimensional nanomaterials in contrast have sp2 carbon bonding as is found in graphite The smallest carbon nanothread has a diameter of only 0 2 nanometers much smaller than the diameter of a single wall carbon nanotube 1 Contents 1 Synthesis 2 History 3 Structure 4 Carbon nitride nanothreads 5 Smallest nanothreads 6 Properties 7 Potential applications 7 1 Energy storage 8 See also 9 External links 10 ReferencesSynthesis editNanothreads are synthesized by compressing liquid benzene to an extreme pressure of 20 GPa around 200 000 times the air pressure at the surface of the Earth and then slowly relieving that pressure 2 The mechanochemical 3 synthesis reaction can be considered a form of organic solid state chemistry The benzene chains form extremely thin tight rings of carbon that are structurally similar to diamonds 4 Researchers at Cornell University have traced pathways from benzene to nanothreads which may involve a series of organic 4 2 cycloaddition reactions along stacks of benzene molecules followed by further reactions of unsaturated bonds 5 Recently synthesis of macroscopic single crystal arrays of nanothreads hundreds of microns in size has been reported 3 The order and lack of grain boundaries in single crystals is often very desirable because it facilitates both applications and characterization In contrast carbon nanotubes form only thin crystalline ropes Control of the rate of compression and or decompression appears to be important to the synthesis of polycrystalline and single crystal nanothreads 2 3 Slow compression decompression may favor low energy reaction pathways 3 If the synthesis pressure for nanothreads can be reduced to 5 to 6 GPa which is the pressure used for synthesis of industrial diamond production on a large scale of gt 106 kg yr would be possible Recent advance on using strained cage like molecules such as cubane as a precursor has successfully brought down the synthesis pressure to 12 GPa Expanding the precursor library to non aromatic strained molecules offers new avenues to explore scalable production of carbon nanothreads 6 The formation of nanothread crystals appears to be guided by uniaxial stress mechanical stress in a particular single direction to which the nanothreads consistently align 3 Reaction to form the crystals is not topochemical 7 as it involves a major rearrangement from a lower symmetry monoclinic benzene crystal to a higher symmetry hexagonal nanothread crystal Topochemical reactions generally require commensuration between the periodicities and interatomic distances between reactant and product The distances between benzene molecules with van der Waals separations between them must shrink by 40 or more as the short strong covalent carbon carbon bonds between them form during the nanothread synthesis reaction Such large changes in geometry usual break up crystal order but the nanothread reaction instead creates it Even polycrystalline benzene reacts to form macroscopic single crystal packings of nanothreads hundreds of microns across 3 Topochemical solid state reactions such as the formation of single crystal polydiacetylenes from diacetylenes usually require a single crystal reactant to form a single crystal product The impetus for the formation of a hexagonal crystal appears to be the packing of circular cross section threads 3 The details of how it is possible to transform from a monoclinic benzene crystal to a hexagonal nanothread crystal are not yet fully understood Further development of the theory of the effect of pressure on reactions may help 8 Organic synthesis efforts towards polytwistane nanothreads have been reported 9 nbsp Rotating polytwistane a prototypical nanothread structure 10 11 Black atoms are carbon Light grey atoms are hydrogen nbsp Polytwistane crystal viewed down its hexagonal c axis Black atoms are carbon and pink atoms are hydrogen The length of the threads is going into the page showing their circular cross section and hexagonal packing that experimentally extends over hundreds of microns in crystals The outline of the hexagonal unit cell is shown in blue These crystals exfoliate into bundles of nanothreads 3 History editIn popular culture diamond threads were first described by Arthur C Clarke in his sci fi novel The Fountains of Paradise set in the 22nd century written in 1979 Nanothreads were first investigated theoretically in 2001 by researchers at Penn State University 12 and later by researchers at Cornell University 13 In 2014 researchers at Penn State University created the first sp3 carbon nanothreads in collaboration with Oak Ridge National Laboratory and the Carnegie Institution for Science 2 Prior to 2014 and despite a century of investigation benzene was thought to produce only hydrogenated amorphous carbon when compressed 14 As of 2015 threads at least 90 nanometers in length had been created compared to 5 meters for CNTs Structure editSince diamond nanothreads are sp3 bonded and one dimensional they are unique in the matrix of hybridization sp2 sp3 and dimensionality 0D 1D 2D 3D for carbon nanomaterials 15 Assuming a topological unit cell of one or two benzene rings with at least two bonds interconnecting each adjacent pair of rings 50 topologically distinct nanothreads have been enumerated 15 of these are within 80 meV carbon atom of the most stable member 11 Some of the more commonly discussed nanothread structures are known informally as polytwistane tube 3 0 and Polymer I Polytwistane is chiral 11 10 Tube 3 0 can be thought of as the thinnest possible thread that can be carved out of the diamond structure consisting of stacked cyclohexane rings 12 Polymer I was predicted to form from benzene at high pressure 13 Although there is compelling evidence from two dimensional X ray diffraction patterns transmission electron diffraction and solid state nuclear magnetic resonance NMR for a structure consisting of hexagonally packed crystals of 6 5 Angstrom diameter nanothreads with largely 75 to 80 sp3 bonding 2 3 the atomic structure of nanothreads is still under investigation Nanothreads have also been observed by transmission electron microscopy 2 Individual threads have been observed to pack in hexagonal crystals and layer lines indicative of order along their length have been observed 16 Nanothreads have also been classified by their degree of saturation 5 Fully saturated degree 6 nanothreads have no double bonds remaining Three bonds form between each pair of benzene molecules Degree 4 nanothreads have a double bond remaining from benzene and thus only two bonds formed between each pair of benzene molecules Degree 2 have two double bonds remaining Unless otherwise specified the term nanothread is assumed to refer to a degree six structure NMR has revealed that nanothread crystals consist of both degree 6 and degree 4 threads 17 Moreover spin diffusion experiments show that the sections of the threads that are fully saturated degree 6 must be at least 2 5 nm long if not longer NMR also shows that no second hydrocarbon or carbon phase is present in nanothread crystals Thus all of the sp2 carbon is either in degree 4 nanothreads or small amounts of aromatic linker molecules or even smaller amounts of C O groups NMR provides the chemical structural information necessary to refine syntheses towards pure degree 6 nanothreads which are stronger than the partially saturated ones 18 Carbon nitride nanothreads editPyridine compressed slowly under pressure forms carbon nitride C5H5N nanothread crystals 19 They exhibit the six fold diffraction signature of nanothread formation NMR chemical analysis and infrared spectroscopy provide further evidence for the synthesis of nanothreads from pyridine Pyridine nanothreads incorporate significant amounts of nitrogen directly into their backbone In contrast sp2 carbon nanotubes can only be doped with a small amount of nitrogen A wide range of other functionalized nanothreads may be possible 20 as well as nanothreads from polycyclic aromatic hydrocarbon molecules 21 Smallest nanothreads editExtending the ability to design and create nanothread architecture from a non aromatic saturated molecule has been a recent interest in order to achieve an entirely sp3 bonded nanothread structure Hypothetical nanothread architectures built from the smallest diamondoids adamantane have been proposed to have higher mechanical strength than benzene nanothreads 22 The first experimental synthesis of a novel purely sp3 bonded one dimensional carbon nanomaterial is realized via an endogenous solid state polymerization of cubane Pre arranged cubane monomers in the bulk crystal undergo diradical polymerization guided by applied uniaxial stress similar to benzene produce a single crystalline carbon nanomaterial The cubane derived nanothread exhibits a linear diamond structure with subnanometre diameter of 0 2 nm which is considered as the smallest member in the carbon nanothread family thus they promise to form the stiffest one dimensional system known 23 Properties editEvery type of nanothread has a very high Young s modulus stiffness The value for the strongest type of nanothread is around 900 GPa compared to steel at 200 GPa and diamond at over 1 200 GPa 24 The strength of carbon nanothreads may rival or exceed that of carbon nanotubes CNTs Molecular dynamics and Density functional theory simulations have indicated a stiffness on the order of carbon nanotubes approx 850 GPa and a specific strength of approx 4 107 N m kg 25 18 Much as graphite exfoliates into sheets and ultimately graphene nanothread crystals exfoliate into fibers consistent with their structure consisting of stiff straight threads with a persistence length of 100 nm 25 that are held together with van der Waals forces These fibers exhibit birefringence as would be expected from their low dimensional character 3 In contrast most polymers are much more flexible and often fold into crystalline lamella see Crystallization of polymers rather than forming into crystals that readily exfoliate Modeling suggests certain nanothreads may be auxetic with a negative Poisson ratio 26 The thermal conductivity of nanothreads has been modeled 27 28 29 Modeling indicates their Bandgaps are tunable with strain over a wide range 30 The electrical conductivity of fully saturated nanothreads driven by topology may be much higher than expected 31 Potential applications editNanothreads can be thought of essentially as flexible diamond The extremely high specific strength predicted for them by modeling has attracted attention for applications such as space elevators and would be useful in other applications related to transportation aerospace and sports equipment They may uniquely combine extreme strength flexibility and resilience 25 32 Chemically substituted nanothreads may facilitate load transfer between neighbors through covalent bonding to transfer their mechanical strength to a surrounding matrix 2 Modeling also suggests that the kinks associated with Stone Wales transformations in nanothreads may facilitate interfacial load transfer to a surrounding matrix making them useful for high strength composites 33 In contrast to carbon nanotubes bonds to the exterior of nanothreads need not disrupt their carbon core because only three of the four tetrahedral bonds are needed form it The extra bond usually formed to hydrogen could be instead be linked to another nanothread or another molecule or atom 2 Nanothreads may thus be thought of as hybrids that are both hydrocarbon molecules and carbon nanomaterials Bonds to carbon nanotubes require their carbon to change from near planar sp2 bonding to tetrahedral sp3 bonding thus disrupting their tubular geometry and possibly weakening them Nanothreads may be less susceptible to loss of strength through defects than carbon nanotubes 25 Thus far the extreme strength predicted for carbon nanotubes has largely not been realized in practical applications because of issues with load transfer to the surroundings and defects at various length scales from that of atoms on up Exfoliation into individual nanothreads may be possible facilitating further functionalization and assembly into functional materials 3 Theory indicates that caged saturated hydrocarbons offering multiple s conductance channels such as nanothreads afford transmission far beyond what could be expected based upon conventional superposition laws particularly if these pathways are composed entirely from quaternary carbon atoms 34 The carbon core of nanothreads is very stiff relative to the backbone of conventional polymers They should thus be able to precisely orient molecular functions attached along their length by substitution of hydrogen relative to each other and to heteroatoms or unsaturated bonds in their backbone These features may enable biological applications 35 for example Defects functional groups and or heteroatoms 20 incorporated either into or exterior to the backbone of nanothreads with controlled orientation and distance between them may allow for robust well controlled fluorescence Doping and incorporation of heteroatoms such as nitrogen or boron into the nanothread backbone may allow for enhanced conducting or semiconducting properties 18 of nanothreads that allow for application as photocatalysts electron emitters 2 or possibly superconductors Modeling suggests carbon nanothread resonators exhibit low dissipation and may be useful as chemical sensors that can detect very small mass changes 36 Energy storage edit Simulations show some achiral nanothread bundles may have specific energy density when twisted higher than lithium batteries 37 See also edit nbsp Science portal nbsp Technology portal Carbon nanotube Boron nitride nanotube Buckypaper Carbide derived carbon Carbon nanocone Carbon nanofibers Carbon nanoparticles Carbon nanoscrolls Carbon nanotube chemistry Colossal carbon tube Filamentous carbon Graphene oxide paper List of software for nanostructures modeling Molecular modelling Nanoflower Diamondoid Graphene Graphane Ninithi nanotube modelling software Organic semiconductor Selective chemistry of single walled nanotubes Silicon nanotubes Timeline of carbon nanotubes Vantablack a substance produced in 2014 the blackest substance knownExternal links editForget Graphene and Carbon Nanotubes Get Ready for Diamond Nanothread technologyreview com Synthesizing Carbon Nanothreads from Benzene spie org Liquid Benzene Squeezed to Form Diamond Nanothreads Scientific American Carbon Nanothread Bibliography Center for Nanothread ChemistryReferences edit Huang Haw Tyng Zhu Li Ward Matthew D Wang Tao Chen Bo Chaloux Brian L Wang Qianqian Biswas Arani Gray Jennifer L Kuei Brooke Cody George D Epshteyn Albert Crespi Vincent H Badding John V Strobel Timothy A 21 January 2020 Nanoarchitecture through Strained Molecules Cubane Derived Scaffolds and the Smallest Carbon Nanothreads Journal of the American Chemical Society 142 42 17944 17955 doi 10 1021 jacs 9b12352 ISSN 0002 7863 PMID 31961671 S2CID 210870993 a b c d e f g h T C Fitzgibbons et al Benzene derived carbon nanothreads Nature Materials September 21 2014 a b c d e f g h i j k Li Xiang Baldini Maria Wang Tao Chen Bo Xu En shi Vermilyea Brian Crespi Vincent H Hoffmann Roald Molaison Jamie J 2017 11 15 Mechanochemical Synthesis of Carbon Nanothread Single Crystals Journal of the American Chemical Society 139 45 16343 16349 doi 10 1021 jacs 7b09311 ISSN 0002 7863 PMID 29040804 Scientists Might Have Accidentally Solved The Hardest Part Of Building Space Elevators Business Insider 13 October 2014 Ajai Raj a b Chen Bo Hoffmann Roald Ashcroft N W Badding John Xu Enshi Crespi Vincent 2015 11 18 Linearly Polymerized Benzene Arrays As Intermediates Tracing Pathways to Carbon Nanothreads Journal of the American Chemical Society 137 45 14373 14386 doi 10 1021 jacs 5b09053 ISSN 0002 7863 PMID 26488180 Huang Haw Tyng Zhu Li Ward Matthew D Wang Tao Chen Bo Chaloux Brian L Wang Qianqian Biswas Arani Gray Jennifer L Kuei Brooke Cody George D Epshteyn Albert Crespi Vincent H Badding John V Strobel Timothy A 21 January 2020 Nanoarchitecture through Strained Molecules Cubane Derived Scaffolds and the Smallest Carbon Nanothreads Journal of the American Chemical Society 142 42 17944 17955 doi 10 1021 jacs 9b12352 ISSN 0002 7863 PMID 31961671 S2CID 210870993 Lauher Joseph W Fowler Frank W Goroff Nancy S 2008 09 16 Single Crystal to Single Crystal Topochemical Polymerizations by Design Accounts of Chemical Research 41 9 1215 1229 doi 10 1021 ar8001427 ISSN 0001 4842 PMID 18712885 Chen Bo Hoffmann Roald Cammi Roberto 2017 09 04 The Effect of Pressure on Organic Reactions in Fluids a New Theoretical Perspective Angewandte Chemie International Edition 56 37 11126 11142 doi 10 1002 anie 201705427 ISSN 1521 3773 PMID 28738450 Olbrich Martin Mayer Peter Trauner Dirk 2015 02 20 Synthetic Studies toward Polytwistane Hydrocarbon Nanorods The Journal of Organic Chemistry 80 4 2042 2055 doi 10 1021 jo502618g ISSN 0022 3263 PMID 25511971 a b Barua Shiblee R Quanz Henrik Olbrich Martin Schreiner Peter R Trauner Dirk Allen Wesley D 2014 02 03 Polytwistane Chemistry A European Journal 20 6 1638 1645 doi 10 1002 chem 201303081 ISSN 1521 3765 PMID 24402729 a b c Xu En shi Lammert Paul E Crespi Vincent H 2015 08 12 Systematic Enumeration of sp3 Nanothreads Nano Letters 15 8 5124 5130 Bibcode 2015NanoL 15 5124X doi 10 1021 acs nanolett 5b01343 ISSN 1530 6984 PMID 26207926 a b Stojkovic Dragan 2001 Smallest Nanotube Breaking the Symmetry of 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diamond nanothread Nanoscale 8 21 11177 11184 arXiv 1511 01583 Bibcode 2016Nanos 811177Z doi 10 1039 c6nr02414a ISSN 2040 3372 PMID 27181833 S2CID 18849867 Zhan Haifei Zhang Gang Tan Vincent B C Gu Yuantong 2017 03 17 The best features of diamond nanothread for nanofibre applications Nature Communications 8 14863 arXiv 1709 08326 Bibcode 2017NatCo 814863Z doi 10 1038 ncomms14863 ISSN 2041 1723 PMC 5357841 PMID 28303887 Corminboeuf Clemence Gryn ova Ganna 2019 01 22 Topology Driven Single Molecule Conductance of Carbon Nanothreads The Journal of Physical Chemistry Letters 10 4 825 830 doi 10 1021 acs jpclett 8b03556 ISSN 1948 7185 PMID 30668127 S2CID 58949557 Hong Guosong Diao Shuo Antaris Alexander L Dai Hongjie 2015 10 14 Carbon Nanomaterials for Biological Imaging and Nanomedicinal Therapy Chemical Reviews 115 19 10816 10906 doi 10 1021 acs chemrev 5b00008 ISSN 0009 2665 PMID 25997028 Duan Ke Li Yijun Li Li Hu Yujin Wang Xuelin 2018 05 03 Diamond nanothreads based resonators ultrahigh sensitivity and low dissipation Nanoscale 10 17 8058 8065 doi 10 1039 C8NR00502H ISSN 2040 3372 PMID 29671436 Zhan Haifei Zhang Gang Bell John M Tan Vincent B C Gu Yuantong 2020 High density mechanical energy storage with carbon nanothread bundle Nature Communications 11 1 1905 doi 10 1038 s41467 020 15807 7 PMC 7171126 PMID 32312980 Retrieved from https en wikipedia org w index php title Carbon nanothread amp oldid 1217854362, wikipedia, wiki, book, books, library,

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