Hydrogenation of graphene nanoflakes and C–H bond dissociation of hydrogenated graphene nanoflakes: a density functional theory study

Sheng Tao , Hui-Ting Liu , Liu-Ming Yan , Bao-Hua Yue , Ai-Jun Li

Advances in Manufacturing ›› 2017, Vol. 5 ›› Issue (3) : 289 -298.

PDF
Advances in Manufacturing ›› 2017, Vol. 5 ›› Issue (3) : 289 -298. DOI: 10.1007/s40436-017-0180-y
Article

Hydrogenation of graphene nanoflakes and C–H bond dissociation of hydrogenated graphene nanoflakes: a density functional theory study

Author information +
History +
PDF

Abstract

The Gibbs free energy change for the hydrogenation of graphene nanoflakes C n (n = 24, 28, 30 and 32) and the C–H bond dissociation energy of hydrogenated graphene nanoflakes C nH m (n = 24, 28, 30 and 32; and m = 1, 2 and 3) are evaluated using density functional theory calculations. It is concluded that the graphene nanoflakes and hydrogenated graphene nanoflakes accept the orth-aryne structure with peripheral carbon atoms bonded via the most triple bonds and leaving the least unpaired dangling electrons. Five-membered rings are formed at the deep bay sites attributing to the stabilization effect from the pairing of dangling electrons. The hydrogenation reactions which eliminate one unpaired dangling electron and thus decrease the overall multiplicity of the graphene nanoflakes or hydrogenated graphene nanoflakes are spontaneous with negative or near zero Gibbs free energy change. And the resulting C–H bonds are stable with bond dissociation energy in the same range as those of aromatic compounds. The other C–H bonds are not as stable attributing to the excessive unpaired dangling electrons being filled into the C–H anti-bond orbital.

Keywords

Graphene nanoflake / Hydrogenated graphene nanoflake / Orth-aryne / Hydrogenation reaction / Bond dissociation energy / Density functional theory

Cite this article

Download citation ▾
Sheng Tao, Hui-Ting Liu, Liu-Ming Yan, Bao-Hua Yue, Ai-Jun Li. Hydrogenation of graphene nanoflakes and C–H bond dissociation of hydrogenated graphene nanoflakes: a density functional theory study. Advances in Manufacturing, 2017, 5(3): 289-298 DOI:10.1007/s40436-017-0180-y

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Geim AK, Novoselov KS. The rise of graphene. Nat Mater, 2007, 6(3): 183-191.

[2]

Wu J, Pisula W, Müllen K. Graphenes as potential material for electronics. Chem Rev, 2007, 107(3): 718-747.

[3]

Mochalin VN, Shenderova O, Ho D, et al. The properties and applications of nanodiamonds. Nat Nano, 2012, 7(1): 11-23.

[4]

Li H, Kang Z, Liu Y, et al. Carbon nanodots: synthesis, properties and applications. J Mater Chem, 2012, 22(46): 24230-24253.

[5]

Hirsch A. The era of carbon allotropes. Nat Mater, 2010, 9: 868-871.

[6]

Hou J, Shao Y, Ellis MW, et al. Graphene-based electrochemical energy conversion and storage: fuel cells, supercapacitors and lithium ion batteries. Phys Chem Chem Phys, 2011, 13(34): 15384-15402.

[7]

Börrnert F, Börrnert C, Gorantla S, et al. Single-wall-carbon-nanotube/single-carbon-chain molecular junctions. Phys Rev B, 2010, 81(8): 085439.

[8]

Eisler S, Slepkov AD, Elliott E, et al. Polyynes as a model for carbyne: synthesis, physical properties, and nonlinear optical response. J Am Chem Soc, 2005, 127(8): 2666-2676.

[9]

Novoselov KS, Geim AK, Morozov SV, et al. Electric field effect in atomically thin carbon films. Science, 2004, 306(5696): 666-669.

[10]

Mayani VJ, Mayani SV, Wook KS. Development of nanocarbon gold composite for heterogeneous catalytic oxidation. Mater Lett, 2012, 87: 90-93.

[11]

Liang Y, Li Y, Wang H, et al. Strongly coupled inorganic/nanocarbon hybrid materials for advanced electrocatalysis. J Am Chem Soc, 2013, 135(6): 2013-2036.

[12]

Zhao H, Chang Y, Liu M, et al. A universal immunosensing strategy based on regulation of the interaction between graphene and graphene quantum dots. Chem Commun, 2013, 49(3): 234-236.

[13]

Xin S, Guo YG, Wan LJ. Nanocarbon networks for advanced rechargeable lithium batteries. Acc Chem Res, 2012, 45(10): 1759-1769.

[14]

Dai L, Xue Y, Qu L, et al. Metal-free catalysts for oxygen reduction reaction. Chem Rev, 2015, 115(11): 4823-4892.

[15]

Zhang X, Liu Z. Recent advances in microwave initiated synthesis of nanocarbon materials. Nanoscale, 2012, 4(3): 707-714.

[16]

Jin YZ, Gao C, Hsu WK, et al. Large-scale synthesis and characterization of carbon spheres prepared by direct pyrolysis of hydrocarbons. Carbon, 2005, 43(9): 1944-1953.

[17]

Shaikjee A, Coville NJ. The role of the hydrocarbon source on the growth of carbon materials. Carbon, 2012, 50(10): 3376-3398.

[18]

Niu T, Zhou M, Zhang J, et al. Growth intermediates for CVD graphene on Cu(111): carbon clusters and defective graphene. J Am Chem Soc, 2013, 135(22): 8409-8414.

[19]

Boukhvalov DW, Feng X, Müllen K. First-principles modeling of the polycyclic aromatic hydrocarbons reduction. J Phys Chem C, 2011, 115(32): 16001-16005.

[20]

Kosimov DP, Dzhurakhalov AA, Peeters FM. Carbon clusters: from ring structures to nanographene. Phys Rev B, 2010, 81(19): 195414.

[21]

Liu H, Yan L, Yue B, et al. Hydrogen transfer reaction in polycyclic aromatic hydrocarbon radicals. J Phys Chem A, 2014, 118(25): 4405-4414.

[22]

Xie L, Yan L, Sun C, et al. Force field model and molecular dynamics simulation of polyynes. Comput Theor Chem, 2012, 997: 14-18.

[23]

Qi J, Zhu H. Theoretical study on the structures and properties of hydrogen-doped cationic carbon clusters C nH2 + (n = 3–10). Chem Phys, 2014, 431–432: 20-25.

[24]

Wohner N, Lam PK, Sattler K. Systematic energetics study of graphene nanoflakes: from armchair and zigzag to rough edges with pronounced protrusions and overcrowded bays. Carbon, 2015, 82: 523-537.

[25]

Hu W, Lin L, Yang C, et al. Electronic structure and aromaticity of large-scale hexagonal graphene nanoflakes. J Chem Phys, 2014, 141(21): 214704.

[26]

Frisch MJ, Trucks GW, Schlegel HB, et al. GAUSSIAN 09, Revision D.02, 2009, Wallingford: Gaussian Inc.
[27]

Grimme S, Antony J, Ehrlich S, et al. A consistent and accurate ab initio parametrization of density functional dispersion correction (DFT-D) for the 94 elements H-Pu. J Chem Phys, 2010, 132(15): 154104.

[28]

Frisch MJ, Pople JA, Binkley JS. Self-consistent molecular orbital methods 25. Supplementary functions for Gaussian basis sets. J Chem Phys, 1984, 80(7): 3265-3269.

[29]

Zhao Y, Truhlar DG. The M06 suite of density functionals for main group thermochemistry, thermochemical kinetics, noncovalent interactions, excited states, and transition elements: two new functionals and systematic testing of four M06-class functionals and 12 other functionals. Theor Chem Acc, 2008, 120(1–3): 215-241.

[30]

Feng C, Lin CS, Fan W, et al. Stacking of polycyclic aromatic hydrocarbons as prototype for graphene multilayers, studied using density functional theory augmented with a dispersion term. J Chem Phys, 2009, 131(19): 194702.

[31]

McMurry J (1992) Organic chemistry. 3rd edn. Pacific Grove, California, p 29
[32]

Blanksby SJ, Ellison GB. Bond dissociation energies of organic molecules. Acc Chem Res, 2003, 36(4): 255-263.

[33]

Davico GE, Bierbaum VM, DePuy CH, et al. The C–H bond energy of benzene. J Am Chem Soc, 1995, 117(9): 2590-2599.

[34]

Barckholtz C, Barckholtz TA, Hadad CM. C–H and N–H bond dissociation energies of small aromatic hydrocarbons. J Am Chem Soc, 1999, 121(3): 491-500.

Funding

National Natural Science Foundation of China http://dx.doi.org/10.13039/501100001809(21573143)

NSAF(U1630102)

AI Summary AI Mindmap
PDF

148

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/