Non-equivalent nature of acetylenic bonds in typical square graphynes and intricate negative differential resistance characteristics

The role of acetylenic linkage in determining the exotic band structures of 4, 12, 2- and 4, 12, 4- graphynes is reported. The Dirac bands, as confirmed by both density functional theory and tight-binding calculations, are robust and stable over a wide range of hopping parameters between sp-sp -hybridized carbon atoms. The shifting of the crossing points of the Dirac bands along the k-path of these two square graphynes is found to be in opposite direction with the hopping along with the acetylenic bond. A real space decimation scheme has also been adopted for understanding this interesting behavior of the band structure of these two graphynes. The condition for the appearance of a nodal ring in the band structure has been explored and critically tested by appropriate Boron-Nitrogen doping. Moreover, both the graphynes exhibit negative differential resistance in their current–voltage characteristics, with 4, 12, 2- graphynes showing superiority.

[1]  D. Jana,et al.  Application of the real space decimation method in determining intricate electronic phases of matter: a review. , 2023, Physical chemistry chemical physics : PCCP.

[2]  N. Clark,et al.  Synthesis of γ-graphyne using dynamic covalent chemistry , 2022, Nature Synthesis.

[3]  D. Jana,et al.  Intriguing features of Dirac cones in phagraphene with site specific doping , 2021, Applied Surface Science.

[4]  D. Jana,et al.  Emerging properties of carbon based 2D material beyond graphene , 2021, Journal of physics. Condensed matter : an Institute of Physics journal.

[5]  D. Jana,et al.  A new two-dimensional carbon system as a potential Li-adsorbent and its isostructural nitrides with Dirac fermions , 2021 .

[6]  Jiezhi Chen,et al.  Semiconducting Silicene: A Two-Dimensional Silicon Allotrope with Hybrid Honeycomb-Kagome Lattice , 2021, ACS Materials Letters.

[7]  D. Jana,et al.  Band engineering of non-hexagonal 2D tetragonal-silicene sheet and nanoribbons: A theoretical approach , 2021 .

[8]  A. Majumdar,et al.  8-16-4 graphyne: Square-lattice two-dimensional nodal line semimetal with a nontrivial topological Zak index , 2021 .

[9]  Yan‐Bing He,et al.  A review of graphynes: properties, applications and synthesis , 2020, Carbon.

[10]  D. Jana,et al.  Electronic and optical properties of non-hexagonal Dirac material S-graphene sheet and nanoribbons , 2020 .

[11]  D. Jana,et al.  A review on role of tetra-rings in graphene systems and their possible applications , 2020, Reports on progress in physics. Physical Society.

[12]  Yi Liu,et al.  Mirror symmetry origin of Dirac cone formation in rectangular two-dimensional materials. , 2020, Physical chemistry chemical physics : PCCP.

[13]  D. Jana,et al.  The topology and robustness of two Dirac cones in S-graphene: A tight binding approach , 2020, Scientific Reports.

[14]  U. Sarkar,et al.  Theoretical study of electronic transport through P-porphyrin and S-porphyrin nanoribbons. , 2020, Journal of molecular graphics & modelling.

[15]  Mengqiu Long,et al.  Perfect negative differential resistance, spin-filter and spin-rectification transport behaviors in zigzag-edged δ-graphyne nanoribbon-based magnetic devices , 2019, Journal of Magnetism and Magnetic Materials.

[16]  K. Mikkelsen,et al.  Synthesis of radiaannulene oligomers to model the elusive carbon allotrope 6,6,12-graphyne , 2019, Nature Communications.

[17]  D. Jana,et al.  Acetylenic linkage dependent electronic and optical behaviour of morphologically distinct '-ynes'. , 2019, Physical chemistry chemical physics : PCCP.

[18]  Zhongfan Liu,et al.  Exploring Approaches for the Synthesis of Few‐Layered Graphdiyne , 2019, Advanced materials.

[19]  Jun Kang,et al.  Graphyne and Its Family: Recent Theoretical Advances. , 2019, ACS applied materials & interfaces.

[20]  Mengqiu Long,et al.  First-principles study of electric field effect and spin-polarization transport properties of zigzag α-2 graphyne nanoribbons , 2018, Journal of Applied Physics.

[21]  U. Sarkar,et al.  The spin filtering effect and negative differential behavior of the graphene-pentalene-graphene molecular junction: a theoretical analysis , 2018, Journal of Molecular Modeling.

[22]  Mengqiu Long,et al.  Spin-charge transport properties of a Z-shaped α-graphyne nanoribbon junction with different edge passivations , 2018 .

[23]  Shi-Zhang Chen,et al.  Negative Differential Conductance in Polyporphyrin Oligomers with Nonlinear Backbones. , 2018, Journal of the American Chemical Society.

[24]  Stefano de Gironcoli,et al.  Advanced capabilities for materials modelling with Quantum ESPRESSO , 2017, Journal of physics. Condensed matter : an Institute of Physics journal.

[25]  R. Chauvin,et al.  carbo-Naphthalene: A Polycyclic carbo-Benzenoid Fragment of α-Graphyne. , 2016, Angewandte Chemie.

[26]  U. Sarkar,et al.  The Effect of Boron and Nitrogen Doping in Electronic, Magnetic, and Optical Properties of Graphyne , 2016 .

[27]  Alberto García,et al.  Improvements on non-equilibrium and transport Green function techniques: The next-generation transiesta , 2016, Comput. Phys. Commun..

[28]  Z. Shao,et al.  Optical properties of α-, β-, γ-, and 6,6,12-graphyne structures: First-principle calculations , 2015 .

[29]  R. Chauvin,et al.  "Carbo-aromaticity" and novel carbo-aromatic compounds. , 2015, Chemical Society reviews.

[30]  S. Du,et al.  Highly Anisotropic Dirac Fermions in Square Graphynes. , 2015, The journal of physical chemistry letters.

[31]  U. Sarkar,et al.  Electronic and optical properties of pristine and boron-nitrogen doped graphyne nanotubes. , 2015, Physical chemistry chemical physics : PCCP.

[32]  Mark A Ratner,et al.  Towards graphyne molecular electronics , 2015, Nature Communications.

[33]  A. D. Corso Pseudopotentials periodic table: From H to Pu , 2014 .

[34]  D. Yang,et al.  Crystal momentum-dependent anisotropy of the Dirac cone in the rectangular carbon allotropes , 2014 .

[35]  Anup Pramanik,et al.  Effect of edge states on the transport properties of pentacene-graphene nanojunctions , 2014 .

[36]  Hui Yan,et al.  Two dimensional Dirac carbon allotropes from graphene. , 2014, Nanoscale.

[37]  Mingwen Zhao,et al.  Two-dimensional carbon topological insulators superior to graphene , 2013, Scientific Reports.

[38]  W. Duan,et al.  Identifying Dirac cones in carbon allotropes with square symmetry. , 2013, The Journal of chemical physics.

[39]  Zhirong Liu,et al.  Dirac cones in two-dimensional systems: from hexagonal to square lattices. , 2013, Physical chemistry chemical physics : PCCP.

[40]  M. Wimmer,et al.  Kwant: a software package for quantum transport , 2013, 1309.2926.

[41]  Yo Shimizu,et al.  Syntheses and properties of graphyne fragments: trigonally expanded dehydrobenzo[12]annulenes. , 2013, Chemistry.

[42]  Jinyang Xi,et al.  Carrier Mobility in Graphyne Should Be Even Larger than That in Graphene: A Theoretical Prediction. , 2013, The journal of physical chemistry letters.

[43]  Li‐Min Liu,et al.  R-graphyne: a new two-dimension carbon allotrope with versatile Dirac-like point in nanoribbons , 2013, 1601.02221.

[44]  W. Duan,et al.  The existence/absence of Dirac cones in graphynes , 2013 .

[45]  Z. Fan,et al.  Controllable low-bias negative differential resistance and rectifying behaviors induced by symmetry breaking , 2013 .

[46]  S. Ciraci,et al.  Size Dependence in the Stabilities and Electronic Properties of α-Graphyne and Its Boron Nitride Analogue , 2013, 1301.2593.

[47]  Yu Liu,et al.  Structural and electronic properties of T graphene: a two-dimensional carbon allotrope with tetrarings. , 2013, Physical review letters.

[48]  Anup Pramanik,et al.  Electronic structure and transport properties of sulfur-passivated graphene nanoribbons , 2012 .

[49]  Lei Liu,et al.  A simple tight-binding model for typical graphyne structures , 2012 .

[50]  Z. Fan,et al.  The site effects of B or N doping on I-V characteristics of a single pyrene molecular device , 2012 .

[51]  Francesc Viñes,et al.  Competition for graphene: graphynes with direction-dependent Dirac cones. , 2012, Physical review letters.

[52]  H. Choi,et al.  Graphyne: Hexagonal network of carbon with versatile Dirac cones , 2011, 1112.2932.

[53]  Fengmin Wu,et al.  Elastic, Electronic, and Optical Properties of Two-Dimensional Graphyne Sheet , 2011 .

[54]  Qiang Sun,et al.  Electronic structures and bonding of graphyne sheet and its BN analog. , 2011, The Journal of chemical physics.

[55]  Lizhi Zhang,et al.  Graphyne- and Graphdiyne-based Nanoribbons: Density Functional Theory Calculations of Electronic Structures , 2011, 1211.4310.

[56]  A. Hirsch The era of carbon allotropes. , 2010, Nature materials.

[57]  Z. Fan,et al.  Negative differential resistance and rectifying behaviors in phenalenyl molecular device with different contact geometries , 2010 .

[58]  Stefano de Gironcoli,et al.  QUANTUM ESPRESSO: a modular and open-source software project for quantum simulations of materials , 2009, Journal of physics. Condensed matter : an Institute of Physics journal.

[59]  Charles A. Johnson,et al.  Carbon networks based on benzocyclynes. 6. synthesis of graphyne substructures via directed alkyne metathesis. , 2007, Organic letters.

[60]  R. Baughman,et al.  Families of carbon nanotubes: Graphyne-based nanotubes , 2003 .

[61]  K. Sonogashira,et al.  Development of Pd–Cu catalyzed cross-coupling of terminal acetylenes with sp2-carbon halides , 2002 .

[62]  P. Ordejón,et al.  Density-functional method for nonequilibrium electron transport , 2001, cond-mat/0110650.

[63]  Shugo Suzuki,et al.  Optimized geometries and electronic structures of graphyne and its family , 1998 .

[64]  Kiley,et al.  Carbon Networks Based on Dehydrobenzoannulenes: Synthesis of Graphdiyne Substructures , 1997 .

[65]  K. Burke,et al.  Generalized Gradient Approximation Made Simple [Phys. Rev. Lett. 77, 3865 (1996)] , 1997 .

[66]  Burke,et al.  Generalized Gradient Approximation Made Simple. , 1996, Physical review letters.

[67]  Soler,et al.  Self-consistent order-N density-functional calculations for very large systems. , 1996, Physical review. B, Condensed matter.

[68]  Blöchl,et al.  Projector augmented-wave method. , 1994, Physical review. B, Condensed matter.

[69]  J. Martins,et al.  A straightforward method for generating soft transferable pseudopotentials , 1990 .

[70]  T. Hiyama,et al.  Cross-coupling of organosilanes with organic halides mediated by a palladium catalyst and tris(diethylamino)sulfonium difluorotrimethylsilicate , 1988 .

[71]  Ray H. Baughman,et al.  Structure‐property predictions for new planar forms of carbon: Layered phases containing sp2 and sp atoms , 1987 .

[72]  R. Landauer,et al.  Generalized many-channel conductance formula with application to small rings. , 1985, Physical review. B, Condensed matter.

[73]  H. Monkhorst,et al.  SPECIAL POINTS FOR BRILLOUIN-ZONE INTEGRATIONS , 1976 .

[74]  Bog-Gi Kim,et al.  Comment on "Structural and electronic properties of T graphene: a two-dimensional carbon allotrope with tetrarings". , 2013, Physical review letters.

[75]  E. Negishi,et al.  Highly general stereo-, regio-, and chemo-selective synthesis of terminal and internal conjugated enynes by the Pd-catalysed reaction of alkynylzinc reagents with alkenyl halides , 1977 .

[76]  C. Glaser Untersuchungen über einige Derivate der Zimmtsäure , 1867 .