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Amorphous carbon

November 14, 2023

Amorphous carbon is free, reactive carbon that has no crystalline structure. Amorphous carbon materials may be stabilized by terminating dangling-π bonds with hydrogen. As with other amorphous solids, some short-range order can be observed. Amorphous carbon is often abbreviated to aC for general amorphous carbon, aC:H or HAC for hydrogenated amorphous carbon, or to ta-C for tetrahedral amorphous carbon (also called diamond-like carbon).[1]

In mineralogy edit

In mineralogy, amorphous carbon is the name used for coal, carbide-derived carbon, and other impure forms of carbon that are neither graphite nor diamond. In a crystallographic sense, however, the materials are not truly amorphous but rather polycrystalline materials of graphite or diamond[2] within an amorphous carbon matrix. Commercial carbon also usually contains significant quantities of other elements, which may also form crystalline impurities.

In modern science edit

With the development of modern thin film deposition and growth techniques in the latter half of the 20th century, such as chemical vapour deposition, sputter deposition, and cathodic arc deposition, it became possible to fabricate truly amorphous carbon materials.

True amorphous carbon has localized π electrons (as opposed to the aromatic π bonds in graphite), and its bonds form with lengths and distances that are inconsistent with any other allotrope of carbon. It also contains a high concentration of dangling bonds; these cause deviations in interatomic spacing (as measured using diffraction) of more than 5% as well as noticeable variation in bond angle.[2]

The properties of amorphous carbon films vary depending on the parameters used during deposition. The primary method for characterizing amorphous carbon is through the ratio of sp2 to sp3 hybridized bonds present in the material. Graphite consists purely of sp2 hybridized bonds, whereas diamond consists purely of sp3 hybridized bonds. Materials that are high in sp3 hybridized bonds are referred to as tetrahedral amorphous carbon, owing to the tetrahedral shape formed by sp3 hybridized bonds, or as diamond-like carbon (owing to the similarity of many physical properties to those of diamond).

Experimentally, sp2 to sp3 ratios can be determined by comparing the relative intensities of various spectroscopic peaks (including EELS, XPS, and Raman spectroscopy) to those expected for graphite or diamond. In theoretical works, the sp2 to sp3 ratios are often obtained by counting the number of carbon atoms with three bonded neighbors versus those with four bonded neighbors. (This technique requires deciding on a somewhat arbitrary metric for determining whether neighboring atoms are considered bonded or not, and is therefore merely used as an indication of the relative sp2-sp3 ratio.)

Although the characterization of amorphous carbon materials by the sp2-sp3 ratio may seem to indicate a one-dimensional range of properties between graphite and diamond, this is most definitely not the case. Research is currently ongoing into ways to characterize and expand on the range of properties offered by amorphous carbon materials.

All practical forms of hydrogenated carbon (e.g. smoke, chimney soot, mined coal such as bitumen and anthracite) contain large amounts of polycyclic aromatic hydrocarbon tars, and are therefore almost certainly carcinogenic.

Q-carbon edit

Q-carbon, short for quenched carbon, is claimed to be a type of amorphous carbon that is ferromagnetic, electrically conductive, harder than diamond,[3] and able to exhibit high-temperature superconductivity.[4] A research group led by Professor Jagdish Narayan and graduate student Anagh Bhaumik at North Carolina State University announced the discovery of Q-carbon in 2015.[5] They have published numerous papers on the synthesis and characterization of Q-carbon,[6] but years later, there is no independent experimental confirmation of this substance and its properties.

According to the researchers, Q-carbon exhibits a random amorphous structure that is a mix of 3-way (sp2) and 4-way (sp3) bonding, rather than the uniform sp3 bonding found in diamonds.[7] Carbon is melted using nanosecond laser pulses, then quenched rapidly to form Q-carbon, or a mixture of Q-carbon and diamond. Q-carbon can be made to take multiple forms, from nanoneedles to large-area diamond films. The researchers also reported the creation of nitrogen-vacancy nanodiamonds[8] and Q-boron nitride (Q-BN), as well as the conversion of carbon into diamond and h-BN into c-BN[9] at ambient temperatures and air pressures.[10] The group obtained patents on q-materials and intended to commercialize them.[11]

In 2018, a team at University of Texas at Austin used simulations to propose theoretical explanations of the reported properties of Q-carbon, including the record high-temperature superconductivity, ferromagnetism and hardness.[12][13] However, their simulations have not been verified by other researchers.

See also edit

References edit

  1. ^ Robertson, J. (1986). "Amorphous carbon". Advances in Physics. 35 (4): 317–374. Bibcode:1986AdPhy..35..317R. doi:10.1080/00018738600101911.
  2. ^ a b IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "diamond-like carbon films". doi:10.1351/goldbook.D01673
  3. ^ Narayan, Jagdish; Gupta, Siddharth; Bhaumik, Anagh; Sachan, Ritesh; Cellini, Filippo; Riedo, Elisa (2018). "Q-carbon harder than diamond". MRS Communications. 8 (2): 428–436. doi:10.1557/mrc.2018.35. ISSN 2159-6859.
  4. ^ Bromwich, Jonah (2015-12-03). "New Substance Is Harder Than Diamond, Scientists Say". The New York Times. ISSN 0362-4331. Retrieved Sep 22, 2019.
  5. ^ Narayan, Jagdish; Bhaumik, Anagh (2015-12-07). "Novel phase of carbon, ferromagnetism, and conversion into diamond". Journal of Applied Physics. 118 (21): 215303. Bibcode:2015JAP...118u5303N. doi:10.1063/1.4936595. ISSN 0021-8979.
  6. ^ "Researchers find new phase of carbon, make diamond at room temperature". Retrieved Sep 22, 2019.
  7. ^ "Q-carbon is harder than diamond, incredibly simple to make | ExtremeTech". ExtremeTech. Retrieved Sep 22, 2019.
  8. ^ Narayan, Jagdish; Bhaumik, Anagh (2016-11-02). "Novel synthesis and properties of pure and NV-doped nanodiamonds and other nanostructures". Materials Research Letters. 5 (4): 242–250. doi:10.1080/21663831.2016.1249805. ISSN 2166-3831.
  9. ^ Narayan, Jagdish; Bhaumik, Anagh (February 2016). "Research Update: Direct conversion of h-BN into pure c-BN at ambient temperatures and pressures in air". APL Materials. 4 (2): 020701. Bibcode:2016APLM....4b0701N. doi:10.1063/1.4941095. ISSN 2166-532X.
  10. ^ Narayan, Jagdish; Bhaumik, Anagh; Gupta, Siddharth; Haque, Ariful; Sachan, Ritesh (2018-04-06). "Progress in Q-carbon and related materials with extraordinary properties". Materials Research Letters. 6 (7): 353–364. doi:10.1080/21663831.2018.1458753. ISSN 2166-3831.
  11. ^ Gupta, Siddharth; Sachan, Ritesh; Bhaumik, Anagh; Pant, Punam; Narayan, Jagdish (June 2018). "Undercooling driven growth of Q-carbon, diamond, and graphite". MRS Communications. 8 (2): 533–540. doi:10.1557/mrc.2018.76. ISSN 2159-6859.
  12. ^ Sakai, Yuki; Chelikowsky, James R.; Cohen, Marvin L. (2018-02-01). "Simulating the effect of boron doping in superconducting carbon". Physical Review B. 97 (5): 054501. arXiv:1709.07125. Bibcode:2018PhRvB..97e4501S. doi:10.1103/PhysRevB.97.054501. S2CID 103252354.
  13. ^ Sakai, Yuki; Chelikowsky, James R.; Cohen, Marvin L. (2018-07-13). "Magnetism in amorphous carbon". Physical Review Materials. 2 (7): 074403. arXiv:1803.11336. Bibcode:2018PhRvM...2g4403S. doi:10.1103/PhysRevMaterials.2.074403. S2CID 103093007.

November 14, 2023
amorphous, carbon, free, reactive, carbon, that, crystalline, structure, materials, stabilized, terminating, dangling, bonds, with, hydrogen, with, other, amorphous, solids, some, short, range, order, observed, often, abbreviated, general, amorphous, carbon, h. Amorphous carbon is free reactive carbon that has no crystalline structure Amorphous carbon materials may be stabilized by terminating dangling p bonds with hydrogen As with other amorphous solids some short range order can be observed Amorphous carbon is often abbreviated to aC for general amorphous carbon aC H or HAC for hydrogenated amorphous carbon or to ta C for tetrahedral amorphous carbon also called diamond like carbon 1 Contents 1 In mineralogy 2 In modern science 3 Q carbon 4 See also 5 ReferencesIn mineralogy editThis article may need to be rewritten to comply with Wikipedia s quality standards You can help The talk page may contain suggestions December 2012 In mineralogy amorphous carbon is the name used for coal carbide derived carbon and other impure forms of carbon that are neither graphite nor diamond In a crystallographic sense however the materials are not truly amorphous but rather polycrystalline materials of graphite or diamond 2 within an amorphous carbon matrix Commercial carbon also usually contains significant quantities of other elements which may also form crystalline impurities In modern science editWith the development of modern thin film deposition and growth techniques in the latter half of the 20th century such as chemical vapour deposition sputter deposition and cathodic arc deposition it became possible to fabricate truly amorphous carbon materials True amorphous carbon has localized p electrons as opposed to the aromatic p bonds in graphite and its bonds form with lengths and distances that are inconsistent with any other allotrope of carbon It also contains a high concentration of dangling bonds these cause deviations in interatomic spacing as measured using diffraction of more than 5 as well as noticeable variation in bond angle 2 The properties of amorphous carbon films vary depending on the parameters used during deposition The primary method for characterizing amorphous carbon is through the ratio of sp2 to sp3 hybridized bonds present in the material Graphite consists purely of sp2 hybridized bonds whereas diamond consists purely of sp3 hybridized bonds Materials that are high in sp3 hybridized bonds are referred to as tetrahedral amorphous carbon owing to the tetrahedral shape formed by sp3 hybridized bonds or as diamond like carbon owing to the similarity of many physical properties to those of diamond Experimentally sp2 to sp3 ratios can be determined by comparing the relative intensities of various spectroscopic peaks including EELS XPS and Raman spectroscopy to those expected for graphite or diamond In theoretical works the sp2 to sp3 ratios are often obtained by counting the number of carbon atoms with three bonded neighbors versus those with four bonded neighbors This technique requires deciding on a somewhat arbitrary metric for determining whether neighboring atoms are considered bonded or not and is therefore merely used as an indication of the relative sp2 sp3 ratio Although the characterization of amorphous carbon materials by the sp2 sp3 ratio may seem to indicate a one dimensional range of properties between graphite and diamond this is most definitely not the case Research is currently ongoing into ways to characterize and expand on the range of properties offered by amorphous carbon materials All practical forms of hydrogenated carbon e g smoke chimney soot mined coal such as bitumen and anthracite contain large amounts of polycyclic aromatic hydrocarbon tars and are therefore almost certainly carcinogenic Q carbon editQ carbon short for quenched carbon is claimed to be a type of amorphous carbon that is ferromagnetic electrically conductive harder than diamond 3 and able to exhibit high temperature superconductivity 4 A research group led by Professor Jagdish Narayan and graduate student Anagh Bhaumik at North Carolina State University announced the discovery of Q carbon in 2015 5 They have published numerous papers on the synthesis and characterization of Q carbon 6 but years later there is no independent experimental confirmation of this substance and its properties According to the researchers Q carbon exhibits a random amorphous structure that is a mix of 3 way sp2 and 4 way sp3 bonding rather than the uniform sp3 bonding found in diamonds 7 Carbon is melted using nanosecond laser pulses then quenched rapidly to form Q carbon or a mixture of Q carbon and diamond Q carbon can be made to take multiple forms from nanoneedles to large area diamond films The researchers also reported the creation of nitrogen vacancy nanodiamonds 8 and Q boron nitride Q BN as well as the conversion of carbon into diamond and h BN into c BN 9 at ambient temperatures and air pressures 10 The group obtained patents on q materials and intended to commercialize them 11 In 2018 a team at University of Texas at Austin used simulations to propose theoretical explanations of the reported properties of Q carbon including the record high temperature superconductivity ferromagnetism and hardness 12 13 However their simulations have not been verified by other researchers See also editGlassy carbon Diamond like carbon Carbon black Soot CarbonReferences edit Robertson J 1986 Amorphous carbon Advances in Physics 35 4 317 374 Bibcode 1986AdPhy 35 317R doi 10 1080 00018738600101911 a b IUPAC Compendium of Chemical Terminology 2nd ed the Gold Book 1997 Online corrected version 2006 diamond like carbon films doi 10 1351 goldbook D01673 Narayan Jagdish Gupta Siddharth Bhaumik Anagh Sachan Ritesh Cellini Filippo Riedo Elisa 2018 Q carbon harder than diamond MRS Communications 8 2 428 436 doi 10 1557 mrc 2018 35 ISSN 2159 6859 Bromwich Jonah 2015 12 03 New Substance Is Harder Than Diamond Scientists Say The New York Times ISSN 0362 4331 Retrieved Sep 22 2019 Narayan Jagdish Bhaumik Anagh 2015 12 07 Novel phase of carbon ferromagnetism and conversion into diamond Journal of Applied Physics 118 21 215303 Bibcode 2015JAP 118u5303N doi 10 1063 1 4936595 ISSN 0021 8979 Researchers find new phase of carbon make diamond at room temperature Retrieved Sep 22 2019 Q carbon is harder than diamond incredibly simple to make ExtremeTech ExtremeTech Retrieved Sep 22 2019 Narayan Jagdish Bhaumik Anagh 2016 11 02 Novel synthesis and properties of pure and NV doped nanodiamonds and other nanostructures Materials Research Letters 5 4 242 250 doi 10 1080 21663831 2016 1249805 ISSN 2166 3831 Narayan Jagdish Bhaumik Anagh February 2016 Research Update Direct conversion of h BN into pure c BN at ambient temperatures and pressures in air APL Materials 4 2 020701 Bibcode 2016APLM 4b0701N doi 10 1063 1 4941095 ISSN 2166 532X Narayan Jagdish Bhaumik Anagh Gupta Siddharth Haque Ariful Sachan Ritesh 2018 04 06 Progress in Q carbon and related materials with extraordinary properties Materials Research Letters 6 7 353 364 doi 10 1080 21663831 2018 1458753 ISSN 2166 3831 Gupta Siddharth Sachan Ritesh Bhaumik Anagh Pant Punam Narayan Jagdish June 2018 Undercooling driven growth of Q carbon diamond and graphite MRS Communications 8 2 533 540 doi 10 1557 mrc 2018 76 ISSN 2159 6859 Sakai Yuki Chelikowsky James R Cohen Marvin L 2018 02 01 Simulating the effect of boron doping in superconducting carbon Physical Review B 97 5 054501 arXiv 1709 07125 Bibcode 2018PhRvB 97e4501S doi 10 1103 PhysRevB 97 054501 S2CID 103252354 Sakai Yuki Chelikowsky James R Cohen Marvin L 2018 07 13 Magnetism in amorphous carbon Physical Review Materials 2 7 074403 arXiv 1803 11336 Bibcode 2018PhRvM 2g4403S doi 10 1103 PhysRevMaterials 2 074403 S2CID 103093007 Retrieved from https en wikipedia org w index php title Amorphous carbon amp oldid 1150326475, wikipedia, wiki, book, books, library,

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