Guided Molecular Assembly on a Locally Reactive 2D Material

Warner, Ben; Gill, Tobias G.; Caciuc, Vasile; Atodiresei, Nicolae; Fleurence, Antoine; Yoshida, Yasuo; Hasegawa, Yukio; Blügel, Stefan; Yamada‐Takamura, Yukiko; Hirjibehedin, Cyrus F.

doi:10.1002/adma.201703929

Cited by 7 publications

(5 citation statements)

References 54 publications

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“…As shown in figure 1(c), epitaxial silicene crystallizes in the domains in the planar-like structure in which five out of the six Si The repulsion between domain boundaries through the stress field they generate [28], induces the organization of the dislocations into a periodical array. As seen in figure 1(c), the partial dislocations are 3 √ 3a ZrB2 /2-wide (where a ZrB2 = 3.18 Å is the lattice parameter of the ZrB 2 (0001)) and are of two different types, symmetric with respect to each other in a mirror symmetry operation and perfectly alternated along the direction perpendicular to the stripe domains [29,30]. Their respective Burgers vectors are…”

Section: Partial Dislocations In Epitaxial Silicene On Zrb 2 (0001)mentioning

confidence: 99%

“…As a consequence, the resolution of the protrusions in STM images and the observation of the shift direction between neighboring domains allow for determining the positions of all Si atoms in the silicene sheet. Note that owing to different local densities of states in the domains and in the boundaries [30], the stripe domain structures can be easily visualized by choosing a proper bias voltage, even in large scale images such as the one in figure 1(a).…”

Section: Partial Dislocations In Epitaxial Silicene On Zrb 2 (0001)mentioning

confidence: 99%

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Adatom-induced dislocation annihilation in epitaxial silicene

Fleurence¹,

Yamada‐Takamura²

2021

2D Mater.

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The transformation of the stripe domain structure of spontaneously-formed epitaxial silicene on ZrB2 thin films into a single-domain driven by the adsorption of a fraction of a monolayer of silicon was used to investigate how dislocations react and eventually annihilate in a two-dimensional honeycomb structure. The in-situ real time scanning tunneling microscopy monitoring of the evolution of the domain structure after Si deposition revealed the mechanisms leading to the nucleation of a single-domain island into a domain structure through a stepwise reaction of partial dislocations. After its nucleation, the single-domain island extends by the propagation of edge dislocations at its frontiers. The identification of this particular nucleation-propagation formation of dislocation-free silicene sheet provides insights into how crystallographic defects can be healed in two-dimensional materials.

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Section: Partial Dislocations In Epitaxial Silicene On Zrb 2 (0001)mentioning

confidence: 99%

Section: Partial Dislocations In Epitaxial Silicene On Zrb 2 (0001)mentioning

confidence: 99%

Adatom-induced dislocation annihilation in epitaxial silicene

Fleurence¹,

Yamada‐Takamura²

2021

2D Mater.

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“…For example, phthalocyanine (H 2 Pc) was predicted to interact weakly with silicene/Ag(1 1 1) system [197]. Its family member, iron phthalocyanine (FePc) has been deposited on silicene/ZrB 2 and was shown to remain stable up to room temperature at the same time retaining its electronic states [198]. Nitrophenyl diazonium (NPD) on silicene is another example of functionalized system in which each NPD functional group is doped by 0.65 e, and exhibits spinpolarized ferrimagnetism [199].…”

Section: Adsorption Of Moleculesmentioning

confidence: 99%

Functionalization of group-14 two-dimensional materials

Krawiec

2018

J. Phys.: Condens. Matter

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The great success of graphene has boosted intensive search for other single-layer thick materials, mainly composed of group-14 atoms arranged in a honeycomb lattice. This new class of two-dimensional (2D) crystals, known as 2D-Xenes, has become an emerging field of intensive research due to their remarkable electronic properties and the promise for a future generation of nanoelectronics. In contrast to graphene, Xenes are not completely planar, and feature a low buckled geometry with two sublattices displaced vertically as a result of the interplay between sp and sp orbital hybridization. In spite of the buckling, the outstanding electronic properties of graphene governed by Dirac physics are preserved in Xenes too. The buckled structure also has several advantages over graphene. Together with the spin-orbit (SO) interaction it may lead to the emergence of various experimentally accessible topological phases, like the quantum spin Hall effect. This in turn would lead to designing and building new electronic and spintronic devices, like topological field effect transistors. In this regard an important issue concerns the electron energy gap, which for Xenes naturally exists owing to the buckling and SO interaction. The electronic properties, including the magnitude of the energy gap, can further be tuned and controlled by external means. Xenes can easily be functionalized by substrate, chemical adsorption, defects, charge doping, external electric field, periodic potential, in-plane uniaxial and biaxial stress, and out-of-plane long-range structural deformation, to name a few. This topical review explores structural, electronic and magnetic properties of Xenes and addresses the question of their functionalization in various ways, including external factors acting simultaneously. It also points to future directions to be explored in functionalization of Xenes. The results of experimental and theoretical studies obtained so far have many promising features making the 2D-Xene materials important players in the field of future nanoelectronics and spintronics.

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“…Accordingly, thin film materials are given high expectations, such as the regular structure of metal clusters and the high-density of memory units [ 3 , 4 , 5 ]. In recent years, atomic level technologies have increased the interest of researchers [ 6 ]. As the important substrate material, Si(111)-7 × 7 is a surface with well-established atomic and electronic structures [ 7 , 8 ].…”

Section: Introductionmentioning

confidence: 99%

Study on Formation Process and Models of Linear Fe Cluster Structure on a Si(111)-7 × 7-CH3OH Surface

Ding

et al. 2018

Materials

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STM results showed that Fe atoms were deposited on a Si(111)-7 × 7 reconstructed surface, which was saturated with CH3OH molecules. Fe atomic linear structure was composed of stable clusters and in-situ observed by the scanning tunneling microscopy (STM). The aim to improve its application of magnetic memory material, both formation process and models, has been explored in this paper. By combining surface images and mass spectrometer data, an intermediate layer model was established. In terms of thermal stability, the most favorable adsorption sites of CH3OH were further explored. After that, Fe atoms were deposited on the Si(111)-7 × 7-CH3OH surface, forming a linear cluster structure. On the one hand, a new Fe cluster model was put forward in this paper, which was established with height measurement and 3D surface display technology. This model is also affected by the evaporation temperature, which can be consistent with the atomic stacking pattern of face centered cubic structures. On the other hand, the slight height change suggested the stability of linear structures. Even in the condition of thin air introduction, Fe cluster showed a good performance, which suggested the possibility of magnetic memory application in the future. These investigations are believed to have, to a certain extent, increased the probability of forming Fe linear clusters on the surface of silicon substrate, especially according to the models and surface technology we adjusted.

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Guided Molecular Assembly on a Locally Reactive 2D Material

Cited by 7 publications

References 54 publications

Adatom-induced dislocation annihilation in epitaxial silicene

Adatom-induced dislocation annihilation in epitaxial silicene

Functionalization of group-14 two-dimensional materials

Study on Formation Process and Models of Linear Fe Cluster Structure on a Si(111)-7 × 7-CH3OH Surface

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