Bi ultra-thin crystalline films on InAs(1 1 1)A and B substrates: a combined core-level and valence-band angle-resolved and dichroic photoemission study

Nicolaï, Laurent; Mariot, J.‐M.; Djukic, Uros; Wang, Weimin; Heckmann, O.; Richter, Maria; Kanski, J.; Leandersson, M.; Balasubramanian, T.; Sadowski, J.; Braun, J.; Ebert, H.; Vobornik, I.; Fujii, Jun; Minář, J.; Hricovíni, K.

doi:10.1088/1367-2630/ab5c14

Cited by 5 publications

(11 citation statements)

References 48 publications

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“…And "Bi_RT_2" in Figure 3a, it becomes evident that a significantly larger amount of Bi can be found on the sample after extended room temperature deposition. This thicker Bi layer grown at room temperature should consist of metallic Bi, according to previous reports; 9,11 thus we attribute the peak at lower B.E. to metallic Bi.…”

Section: Resultssupporting

confidence: 75%

“…Combining STM and XPS results, we can conclude that Bi deposition on a heated GaAs(111)B surface results in the topmost As atoms bonding with Bi atoms, forming Bi–As covalent bonds. These Bi–As bonds and the corresponding Bi–As layer are qualitatively different from metallic Bi islands or Bi trimers in Bi-induced surface reconstructions which have been seen before upon Bi deposition on GaAs or other III–V semiconductors. ,,, Here, a large-scale, ordered 2D honeycomb structure is formed by Bi–As bonds, which even is stable upon annealing up to 400 °C.…”

Section: Resultsmentioning

confidence: 76%

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A 2D Bismuth-Induced Honeycomb Surface Structure on GaAs(111)

et al. 2023

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Two-dimensional (2D) topological insulators have fascinating physical properties which are promising for applications within spintronics. In order to realize spintronic devices working at room temperature, materials with a large nontrivial gap are needed. Bismuthene, a 2D layer of Bi atoms in a honeycomb structure, has recently attracted strong attention because of its record-large nontrivial gap, which is due to the strong spin−orbit coupling of Bi and the unusually strong interaction of the Bi atoms with the surface atoms of the substrate underneath. It would be a significant step forward to be able to form 2D materials with properties such as bismuthene on semiconductors such as GaAs, which has a band gap size relevant for electronics and a direct band gap for optical applications. Here, we present the successful formation of a 2D Bi honeycomb structure on GaAs, which fulfills these conditions. Bi atoms have been incorporated into a clean GaAs(111) surface, with As termination, based on Bi deposition under optimized growth conditions. Low-temperature scanning tunneling microscopy and spectroscopy (LT-STM/S) demonstrates a well-ordered large-scale honeycomb structure, consisting of Bi atoms in a √3 × √3 30°reconstruction on GaAs(111). X-ray photoelectron spectroscopy shows that the Bi atoms of the honeycomb structure only bond to the underlying As atoms. This is supported by calculations based on density functional theory that confirm the honeycomb structure with a large Bi−As binding energy and predict Biinduced electronic bands within the GaAs band gap that open up a gap of nontrivial topological nature. STS results support the existence of Bi-induced states within the GaAs band gap. The GaAs:Bi honeycomb layer found here has a similar structure as previously published bismuthene on SiC or on Ag, though with a significantly larger lattice constant and only weak Bi−Bi bonding. It can therefore be considered as an extreme case of bismuthene, which is fundamentally interesting. Furthermore, it has the same exciting electronic properties, opening a large nontrivial gap, which is the requirement for room-temperature spintronic applications, and it is directly integrated in GaAs, a direct band gap semiconductor with a large range of (opto)electronic devices.

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Section: Resultssupporting

confidence: 75%

Section: Resultsmentioning

confidence: 76%

A 2D Bismuth-Induced Honeycomb Surface Structure on GaAs(111)

et al. 2023

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“…Various technologies were used to obtain high-quality Bi layers: thermal evaporation [ 10 ], electrodeposition [ 11 ], magnetron sputtering [ 6 ], pulsed laser deposition [ 12 ], and molecular beam epitaxy (MBE) [ 13 ]. Epitaxial Bi layers were grown by MBE on a variety of substrates, such as graphene [ 14 ], highly oriented pyrolytic graphite [ 15 ], NaCl [ 6 ], InAs [ 16 ], SiC [ 17 ], and silicon [ 13 ]. Compatibility with existing silicon technology, the ability to grow full wafer-sized homogeneous layers of several nanometers thickness that can be transferred to other secondary substrates, has made Si (111) substrates [ 18 ] the most popular for growing Bi layers.…”

Section: Introductionmentioning

confidence: 99%

The Crystalline Structure of Thin Bismuth Layers Grown on Silicon (111) Substrates

et al. 2022

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Bismuth films with thicknesses between 6 and ∼30 nm were grown on Si (111) substrate by molecular beam epitaxy (MBE). Two main phases of bismuth — α-Bi and β-Bi — were identified from high-resolution X-ray diffraction (XRD) measurements. The crystal structure dependencies on the layer thicknesses of these films were analyzed. β-Bi layers were epitaxial and homogenous in lateral regions that are greater than 200 nm despite the layer thickness. Further, an increase in in-plane 2θ values showed the biaxial compressive strain. For comparison, α-Bi layers are misoriented in six in-plane directions and have β-Bi inserts in thicker layers. That leads to smaller (about 60 nm) lateral crystallites which are compressively strained in all three directions. Raman measurement confirmed the XRD results. The blue-sift of Raman signals compared with bulk Bi crystals occurs due to the phonon confinement effect, which is larger in the thinnest α-Bi layers due to higher compression.

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“…A thorough analysis combining ARPES measurements and fully-relativistic ab initio electronic band calculations of InBi(0 0 1), grown on the InAs(1 1 1)-A surface, indicates that the topmost Bi BL has the same structure as Bi in the space group No. 139 configuration [141]. Nonetheless, the mirror plane parallel to the (0 0 1) plane for Bi-139…”

Section: Possible Future Prospectsmentioning

confidence: 98%

“…Bi, while more than ∼ 30 BLs are needed for the B face[52].The surface termination controls as well atom mobility-driven structural changes after Bi deposition and upon subsequent annealing. On the A side, a morphology of circular patterns controlled by Bi atoms mobility is observed.…”

mentioning

confidence: 99%

Topological electronic structure and Rashba effect in Bi thin layers: theoretical predictions and experiments

Hricovíni¹,

Richter²,

Heckmann³

et al. 2019

J. Phys.: Condens. Matter

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The goal of the present review is to cross-compare theoretical predictions with selected experimental results of spin-and angle-resolved photoelectron spectroscopy on bismuth thin films exhibiting topological properties and a strong Rashba effect. Despite the bulk Bi crystal is topologically trivial, a single free-standing Bi(1 1 1) bilayer has been predicted by calculations to be a topological insulator. This triggered a large series of studies of ultrathin Bi(1 1 1) films grown on various substrates. Using selected examples we review theoretical predictions of atomic and electronic structure of Bi thin films exhibiting topological properties due to interaction with a substrate. We survey as well experimental signatures of topological surface states, as obtained namely by angle-resolved photoelectron spectroscopy.

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Bi ultra-thin crystalline films on InAs(1 1 1)A and B substrates: a combined core-level and valence-band angle-resolved and dichroic photoemission study

Cited by 5 publications

References 48 publications

A 2D Bismuth-Induced Honeycomb Surface Structure on GaAs(111)

A 2D Bismuth-Induced Honeycomb Surface Structure on GaAs(111)

The Crystalline Structure of Thin Bismuth Layers Grown on Silicon (111) Substrates

Topological electronic structure and Rashba effect in Bi thin layers: theoretical predictions and experiments

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