Structural Transformation and Stabilization of Metal–Organic Motifs Induced by Halogen Doping

Xie, Lei; Zhang, Chi; Ding, Yangfeng; Xu, Wei

doi:10.1002/anie.201702589

Cited by 24 publications

(22 citation statements)

References 38 publications

(18 reference statements)

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“…In this study, we report the manipulation of the magnetic state of a multiple-metal center in a molecular assembly by addition/removal of Br atoms. Based on our previous study, we chose a derivative of the guanine molecule (9-ethylguanine, abbreviated as G) and a NiBr 2 salt with the aim of fabricating a three-metal-center ( i.e. , Ni trimer, shortened as Ni 3 ) metal–organic system on the Au(111) surface.…”

supporting

confidence: 56%

“…This assignment is also confirmed by the Br removal experiment discussed below. The structural motif beneath the central Br atom coincides in size and shape with the structure of the basic motif of G 3 Ni 3 I 3 assemblies reported previously . Thus, we tentatively assign the G 3 Ni 3 Br 4 motif (Figure c) to a structure formed by a G 3 Ni 3 Br 3 base with an additional Br atom sitting on the hollow site of the central Ni 3 cluster.…”

Section: Resultsmentioning

confidence: 99%

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Switching the Spin on a Ni Trimer within a Metal–Organic Motif by Controlling the On-Top Bromine Atom

et al. 2019

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Controlling the spin of metal atoms embedded in molecular systems is a key step towards the realization of molecular electronics and spintronics. Many efforts have been devoted to explore the influencing factors dictating the survival or quenching of a magnetic moment in a metal-organic molecule, and among others, the spin control by axial ligand attachments is most promising. Herein, from the interplay of highresolution STM imaging/manipulation and STS measurements together with DFT calculations, we successfully demonstrate that a Ni trimer within a metal-organic motif acquires a net spin promoted by the adsorption of an on-top Br atom. The spin localization in the tri-metal centers bonded to Br was monitored via the Kondo effect.The removal of the Br ligand resulted in the switch from a Kondo ON to a Kondo OFF state. The magnetic state induced by the Br ligand is theoretically attributed to the enhanced Br 4p z and Ni 4dz 2 states due to the charge redistribution. The manipulation strategy reported here provides the possibility to explore potential applications of spin-tunable structures in spintronic devices.

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supporting

confidence: 56%

Section: Resultsmentioning

confidence: 99%

Switching the Spin on a Ni Trimer within a Metal–Organic Motif by Controlling the On-Top Bromine Atom

et al. 2019

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“…Additionally, the adsorption directions of the molecules are 15±2° off from the original ones. The dots are located close to hydrogen‐rich harbors, and such a behavior is regarded as characteristic of halogen atoms owing to electrostatic interactions . It is noteworthy that even at about 220 K, very few debr‐HBTP and locally dissociated Br atoms exist in the initial islands (Supporting Information, Figure S3).…”

Section: Resultsmentioning

confidence: 99%

Atomic‐Scale Visualization of the Stepwise Metal‐Mediated Dehalogenative Cycloaddition Reaction Pathways: Competition between Radicals and Organometallic Intermediates

2019

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Dehalogenative cycloaddition reaction is apowerful strategy to generate new ring scaffolds with p-conjugated features on as urface,a nd thus holds great promise toward atomically precise electronic devices or nanomaterials.T he ortho-dihalo substitution provides ag ood strategy to realize cycloaddition. However,t he limited understanding of intermediate states involved hinders mechanistic exploration for further precise design and optimization of reaction products. Now,t he evolutions of competing surface-stabilized radicals and organometallic intermediates in real space were visualized towardthe formation of dominant conjugated four-membered ring connections.F rom the interplay of scanning tunneling microscopya nd density functional theory calculations,t he stepwise metal-mediated dehalogenative cycloaddition pathway is elucidated both experimentally and theoretically.T he results provide fundamental insights into the intermediate states involved in on-surface synthesis.

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“…[76] . 图 10 G分子、镍原子、碘原子形成的金属-有机分子网格结构 [78] . (a~c) G 3 Ni 1 、G 2 Ni 2 和G 3 Ni 3 三种不同的结构, (e~g) 相应的原子结构图.…”

Section: 成多种自组装结构通过改变分子覆盖度两种有机分unclassified

“…(a~c) G 3 Ni 1 、G 2 Ni 2 和G 3 Ni 3 三种不同的结构, (e~g) 相应的原子结构图. (d) 沉积碘以后形成的G 3 Ni 3 I 3 蜂窝状网格结构, (h) 相应的高分辨率图像和原子结构图(网络版彩图) Figure 10 Self-assembled structures constructed by G molecules, nickel atoms and iodine atoms [78]. (a-c) Large-scale STM images showing different structures of G 3 Ni 1 , G 2 Ni 2 and G 3 Ni 3 .…”

Section: 成多种自组装结构通过改变分子覆盖度两种有机分unclassified

Construction and manipulation of self-assemble structures on solid surfaces

Lei¹,

Zhang²,

Du³

2019

Sci. Sin.-Chim

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Construction of two-dimensional (2D) molecular crystals on solid surfaces is an important way to synthesize supermolecular materials and functionalize solid surfaces. In this review, we provide an overview of the formation mechanism of the 2D self-assembled molecular crystals, and the control of the structures and electronic structures by combining theoretical calculations with scanning tunneling microscopy (STM). Here we focus on the molecular selfassembled structures dominated by weak interactions. Several key factors are listed, for example, the electronic structures of solid surfaces, the configuration of molecules, the interaction of molecules, the interaction between molecules and substrates, and the bromine adatom assisted self-assembly. Finally, we assess future directions of research in this field, where the overall consideration of all the aspects we discussed is important.

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Structural Transformation and Stabilization of Metal–Organic Motifs Induced by Halogen Doping

Cited by 24 publications

References 38 publications

Switching the Spin on a Ni Trimer within a Metal–Organic Motif by Controlling the On-Top Bromine Atom

Switching the Spin on a Ni Trimer within a Metal–Organic Motif by Controlling the On-Top Bromine Atom

Atomic‐Scale Visualization of the Stepwise Metal‐Mediated Dehalogenative Cycloaddition Reaction Pathways: Competition between Radicals and Organometallic Intermediates

Construction and manipulation of self-assemble structures on solid surfaces

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