Solar cell design using graphene-based hollow nano-pillars

Raad, Shiva Hayati; Atlasbaf, Zahra

doi:10.1038/s41598-021-95684-2

Cited by 15 publications

(17 citation statements)

References 51 publications

(46 reference statements)

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“…Determined by high specific area and surface-tovolume ratio, low density and encapsulate option, hollow structures exhibit higher performance than their solid counterparts with the same composition and size that tremendously extends their application in the fields of plasmonics [3][4][5], catalysis [6][7][8][9][10][11], energy storing [12][13][14][15] and medicine [16][17][18]. For instance, hollow metal nanoparticles have significantly higher plasmonic properties than their solid counterparts due to so-called mechanism of plasmon hybridization.…”

Section: Functional Propertiesmentioning

confidence: 99%

“…13a, in the cases of SCPs 1 (α 0) = and IcPs 1 (α 0), > the vacancy concentration at the inner and outer surfaces satisfies the Gibbs-Thompson conditions [see Eqs. (10)]. Besides, in the latter case, a local increase of vacancy concentration occurs in vicinity of the void surface -the less is the value of 1 α the higher is the concentration value and the closer the peak position to the void surface.…”

Section: The Kinetic Models Of Void Formation In Multiply Twinned Par...mentioning

confidence: 99%

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Review on Theoretical Models of Void Evolution in Crystalline Particles

Krasnitckii,

Gutkin

2021

Rev Adv Mater Tech

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In the review, the up-to-date theoretical research of various aspects of void evolution problem in hollow crystalline micro- and nanostructures is summarized. A classification of hollow architectures of micro- and nanostructures distinguishing the main procedures of void (pore) production as well as the influence of the voids on functional properties of the devices based on hollow structures, is suggested. The factors responsible for the void evolution process are discussed. Finally, theoretical models of the void evolution describing shrinkage and growth processes in particles of various structures are considered in terms of kinetics and thermodynamics concepts.

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Section: Functional Propertiesmentioning

confidence: 99%

Section: The Kinetic Models Of Void Formation In Multiply Twinned Par...mentioning

confidence: 99%

Review on Theoretical Models of Void Evolution in Crystalline Particles

Krasnitckii,

Gutkin

2021

Rev Adv Mater Tech

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“…As we reach the quantum limit of silicon-based semiconductors, graphene-based materials have become the focus of intense research due to their applications in solar cells 1 , 2 , OLEDs 3 , bioengineering 4 , 5 , drug and gene delivery systems 6 , 7 , composite materials 8 , and energy storage devices 9 , 10 . Despite their extraordinary mechanical and optoelectronic properties, vanishing bandgaps in graphene limits its ability to replace silicon-based semiconductors.…”

Section: Introductionmentioning

confidence: 99%

Zwitterionic Bergman cyclization triggered polymerization gives access to metal-graphene nanoribbons using a boron metal couple

et al. 2023

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With the rapid growth in artificial intelligence, designing high-speed and low-power semiconducting materials is of utmost importance. This investigation provides a theoretical basis to access covalently bonded transition metal-graphene nanoribbon (TM-GNR) hybrid semiconductors whose DFT-computed bandgaps were much narrower than the commonly used pentacene. Systematic optimization of substrates containing remotely placed boryl groups and the transition metals produced the zwitterions via ionic Bergman cyclization (i-BC) and unlocked the polymerization of metal-substituted polyenynes. Aside from i-BC, the subsequent steps were barrierless, which involved structureless transition regions. Multivariate analysis revealed the strong dependence of activation energy and the cyclization mode on the electronic nature of boron and Au(I). Consequently, three regions corresponding to radical Bergman (r-BC), ionic Bergman (i-BC), and ionic Schreiner-Pascal (i-SP) cyclizations were identified. The boundaries between these regions corresponded to the mechanistic shift induced by the three-center-three-electron (3c-3e) hydrogen bond, three-center-four-electron (3c-4e) hydrogen bond, and vacant p-orbital on boron. The ideal combination for cascade polymerization was observed near the boundary between i-BC and i-SP.

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“…As we approach the quantum limit of silicon-based semiconductors, the discovery of unique electronic properties of graphene offered a lucrative alternative. In recent years, graphene-based materials have been the focus of intense research due to their application in solar cells, 1,2 organic light emitting diodes (OLEDs), 3 bioengineering, 4,5 drug and gene delivery system, 6,7 composite materials, 8 and energy storage devices. 9,10 However, despite the extraordinary mechanical and optoelectronic properties, the vanishing bandgaps in graphenes limit their scope to replace the silicon-based semiconductors.…”

Section: Introductionmentioning

confidence: 99%

“…An experimental study by Roth et al in 1994 corroborated the high activation enthalpy of 28.7 ± 0.5 kcal/mol at 200 o C as predicted by Bergman in early 1970s (H # = 32 kcal/mol; HR = 18 kcal/mol). 21,22,23 This is because, unlike concerted pericyclic process, the number of bonds broken (2) and formed (1) in the cycloaromatization step are not conserved, and the conversion of two -bonds into one -bond leads to the formation of a six-membered aromatic diradical that is orthogonal to the aromatic system, and cannot take advantage of adjacent conjugated system (Figure 2, top left). As a result, this diradical is highly reactive and capable of producing variety of fused cycloaromatic compounds.…”

Section: Introductionmentioning

confidence: 99%

Zwitterionic Bergman-Triggered Cascade Polymerization: A Plateau Reaction Leading to Metal-Graphene Nanoribbon Semiconductors Using Boron-Metal Couple

Vidhani

Ubeda

Sautie

et al. 2022

Preprint

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With a rapid growth in artificial intelligence, designing high-speed and low power semiconducting material is of utmost importance. This investigation provides a theoretical basis to access covalently-bonded transition metal-graphene nanoribbon (TM-GNR) hybrid semiconductors whose DFT-computed bandgaps were much narrower than the commonly used pentacene. A systematic optimization of substrates containing remotely-placed boronyl groups and the transition metals produced the zwitterions via ionic Bergman cyclization (i-BC) and unlocked the polymerization of metal-substituted polyenynes. Aside from i-BC, the subsequent steps showed plateau-TS involving structureless transition regions. A multivariate analysis revealed a strong dependence of activation energy and the cyclization mode on the electronic nature of boron and Au(I). Consequently, three regions corresponding to radical Bergman (r-BC), ionic Bergman (i-BC), and ionic Schreiner-Pascal (i-SP) cyclizations were identified. The boundaries between these regions corresponded to the mechanistic shift induced by three-center-three-electron (3c-3e) hydrogen bond, three-center-four-electron (3c-4e) hydrogen bond, and vacant p-orbital on boron. The ideal combination for cascade polymerization was observed near the boundary between i-BC and i-SP.

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Solar cell design using graphene-based hollow nano-pillars

Cited by 15 publications

References 51 publications

Review on Theoretical Models of Void Evolution in Crystalline Particles

Review on Theoretical Models of Void Evolution in Crystalline Particles

Zwitterionic Bergman cyclization triggered polymerization gives access to metal-graphene nanoribbons using a boron metal couple

Zwitterionic Bergman-Triggered Cascade Polymerization: A Plateau Reaction Leading to Metal-Graphene Nanoribbon Semiconductors Using Boron-Metal Couple

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