The Planar CoB<sub>18</sub><sup>−</sup> Cluster as a Motif for Metallo‐Borophenes

Li, Wan‐Lu; Jian, Tian; Chen, Xin; Chen, Teng‐Teng; Lopez, Gary V.; Li, Jun; Wang, Lai‐Sheng

doi:10.1002/ange.201601548

Cited by 34 publications

(16 citation statements)

References 65 publications

(72 reference statements)

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“…To aid in the simulation of PE spectra, a standalone program named AutoPES is also developed. Recent study on PrB 7 − , CoB 18 − , and Ln 2 B 8 − clusters shows that the TGMin‐2 program and the AutoPES program are powerful tools for the global minimum structure search of free and surface‐adsorbed molecules and nanoclusters. With these implementations and improvements, the TGMin‐2 program can become a useful tool for cluster science and heterogeneous catalysis.…”

Section: Discussionmentioning

confidence: 99%

“…For the boron clusters and metal‐doped boron clusters this observation also holds true: B x − ( x = 3–14) are all symmetric, and one of the two co‐existed lowest‐lying isomers of B 40 − even has a rather high D 2d symmetry . Similarly, CoB 18 − has C 2v and PrB 7 − has C 6v symmetry . When the initial seed structure is close in to the final global minimum isomer, BH‐based algorithms typically will use far less structures before obtaining the global minimum structure.…”

Section: Methodsmentioning

confidence: 99%

“…TGMin‐2 has been used to determine global minimum structures of several different metal‐doped boron clusters, which have been published or will be published soon . Here, we provide the global minimum search results of PrB 7 − and CoB 18 − as examples of the application of TGMin‐2.…”

Section: Methodsmentioning

confidence: 99%

“…The CoB 18 − cluster was originally searched by our previous release of TGMin and its global minimum structure was found to be a planar structure with C 2v symmetry and 1 A 1 state, as depicted in Figure …”

Section: Methodsmentioning

confidence: 99%

“…Until now, several global optimization programs based on the BH algorithm, in conjunction with density functional theory (DFT), tight‐binding DFT (DFTB), or (semi‐) empirical methods have been proposed . Tsinghua Global Minimum (TGMin), developed in 2011, is one of the most successful BH program as TGMin has already helped researchers identify tens of new clusters, including the hexagonal B 36 − cluster, the all‐boron borophenes and borospherenes B 40 − , B 26 − , B 28 − , B 30 − , B 35 − , B 39 − , metallo‐ borophenes, ‐borospherenes, and ‐nanotubes CoB 18 − , MnB 16 − , RhB 18 − , TaB 20 − , as well as the PrB 7 − , LnB 8 Ln (Ln = La, Pr) sandwich complexes, and others . TGMin was also used to identify atmospheric aerosol clusters and surface‐adsorbed species .…”

Section: Introductionmentioning

confidence: 99%

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TGMin: An efficient global minimum searching program for free and surface‐supported clusters

et al. 2018

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In this article, we introduce an efficient global-minimum structural search program named Tsinghua Global Minimum 2 (TGMin-2), which is the successor of the original TGMin algorithm that was developed in our group in 2011. We have introduced a number of new features and improvements into TGMin-2, including a symmetric structure generation algorithm that can produce good initial seeds for small-and medium-size clusters, the duplicated structure identification algorithm, and the improved structure adaption algorithm that was implemented in the original TGMin code. To predict the simulated photoelectron spectrum (PE spectrum) automatically, we also implemented a standalone program named AutoPES (Auto Photoelectron Spectroscopy), which can be used to simulate PE spectra and compare them with experimental results automatically. We have demonstrated that TGMin-2 and AutoPES are powerful tools for studying free and surface-supported molecules, clusters, and nanoclusters.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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TGMin: An efficient global minimum searching program for free and surface‐supported clusters

et al. 2018

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Two‐Dimensional Boron Crystals: Structural Stability, Tunable Properties, Fabrications and Applications

Sun

Liu

Yin

et al. 2016

Adv Funct Materials

170

106

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(1 of 22)allotropes of boron have been discovered up to now. Four of them are thermodynamically stable, including α-rhombohedral, [6] β-rhombohedral, [7] γ-orthorhombic, [1f,2d,8] and β-tetragonal boron crystals. [1d,9] These materials are often called boron-icosahedral cluster solids (B-ICSs), [5b,10] consisting of icosahedral closo-cluster B 12 to link with each other or with other clusters to form boron allotropes and B-rich compounds, such as various types of BN, [11] B 12 As 2 , [12] B 12 P 2 , [13] B 12 O 2 , [14] YB 66 , [15] AlB 12 , [16] and boron carbide. [17] Apart from three-dimensional (3D) boron icosahedral solids, 2D boron also exhibits many unique structures owning to its electron deficiency, different from other well-known 2D materials. Generally, 2D boron crystals can be classified into three categories: 1) graphene-like atomically monolayered boron sheets, [18] 2) 2D boron structures with thickness of a single or a few unit cells, [19] and 3) new kinds of 2D boron structures reported recently. [20] For the first category, "borophene" was coined to refer to a general class of atomically thin boron sheets, [21] unlike other structures with the suffix ene, where each name always corresponds to a certain structure. For example, graphene, as the most attractive 2D crystals, is a single monolayer of carbon atoms, while phosphorene (monolayered black phosphorus) exists with puckered layer structures in nature. Both graphene and phosphorene have corresponding bulk counterparts, allowing for facile access to 2D-layered van der Waals structures through mechanical exfoliations. Other elemental 2D materials, such as silicene, [22] germanene, [23] stanene, [24] arsenene, [25] and antimonene, [26] actually do not have layered bulk counterparts. Similarly, 2D single-layered boron could not be produced by exfoliating from its bulk materials because there is no layered bulk boron. As a result, it is suggested that 2D boron sheets can be synthesized via chemical vapor deposition, thermal evaporation deposition, or molecular beam epitaxy. In the past decade, extensive theoretical efforts have been paid to investigate possible boron sheets, many of which have been predicted to have potential applications in electronic devices, [18c,d] photoelectric devices, [27] superconductivity, [20a,28] field-emission (FE) materials, [29] hydrogen storage media, [30] and lithium-ion batteries. [31] However, the fabrication of 2D boron crystals is a great challenge. Until very recently, three types of monolayered Boron, as a unique element nearest to carbon in the periodic table, has been predicted to form many distinctive two-dimensional (2D) structures that significantly differ from other well-studied 2D materials, owning to its exceptional ability to form strong covalent two-center-two-electron bonds as well as stable electron-deficient multi-center-two-electron bonds. Until recently, the successful syntheses of atomically thin crystalline 2D boron sheets (i.e., borophenes) provoked growing passion in 2D boron crysta...

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Synthesis of Metalloborophene Nanoribbons on Cu(110)

Weng,

Zhu,

et al. 2024

Adv Funct Materials

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Metalloborophene, characterized by the presence of metal‐centered boron wheels denoted as M©Bn, has garnered considerable attention in recent years due to its versatile properties and potential applications in fields such as electronics, spintronics, and catalysis. However, the experimental verification of metalloborophene is challenging, mainly due to the unconventional 2D boron networks. In this study, scanning tunneling microscopy, X‐ray photoelectron spectroscopy, low energy electron diffraction, and first‐principles calculations are employed to unveil Cu©B8 metalloborophene nanoribbons formed via spontaneous alloying after the deposition of boron on a heated Cu(110) substrate under ultrahigh vacuum condition. The thermodynamically preferred precursor, the anchoring of boron network to metal atoms, and anisotropic lattice mismatch are identified as pivotal factors in the formation of these metalloborophene nanoribbons. This discovery expands the repertoire of 2D materials and offers a potential pathway for the synthesis of other metalloborophenes.

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The Planar CoB₁₈⁻ Cluster as a Motif for Metallo‐Borophenes

Cited by 34 publications

References 65 publications

TGMin: An efficient global minimum searching program for free and surface‐supported clusters

TGMin: An efficient global minimum searching program for free and surface‐supported clusters

Two‐Dimensional Boron Crystals: Structural Stability, Tunable Properties, Fabrications and Applications

Synthesis of Metalloborophene Nanoribbons on Cu(110)

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The Planar CoB18− Cluster as a Motif for Metallo‐Borophenes

Cited by 34 publications

References 65 publications

TGMin: An efficient global minimum searching program for free and surface‐supported clusters

TGMin: An efficient global minimum searching program for free and surface‐supported clusters

Two‐Dimensional Boron Crystals: Structural Stability, Tunable Properties, Fabrications and Applications

Synthesis of Metalloborophene Nanoribbons on Cu(110)

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The Planar CoB₁₈⁻ Cluster as a Motif for Metallo‐Borophenes