Selective Area Growth of PbTe Nanowire Networks on InP

Jung, Jason J.; Schellingerhout, Sander G.; Ritter, Markus F.; Kate, S. C. ten; Molen, Orson A. H. van der; Loijer, Sem de; Verheijen, Marcel A.; Riel, Heike; Nichele, Fabrizio; Bakkers, Erik P. A. M.

doi:10.1002/adfm.202208974

Cited by 16 publications

(29 citation statements)

References 49 publications

(63 reference statements)

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“…The structure is single-crystalline over the entire length, with contrast lines visible in the HRTEM due to small-angle mosaicity. [18] For different x-values, the same crystalline quality is found (see Figure S4, Supporting Information).…”

Section: Materials Analysissupporting

confidence: 60%

“…By continuing the deposition for longer times and/or considering smaller opening sizes, shapes from all compositions are found to converge to a tetrahedron defined only by {200} facets, as shown in Figure 1c for PbTe (see also Ref. [18]), and for SnTe islands, grown in 100 nm openings for 45 min. This latter shape, to be considered as the final, steady‐growth morphology, looks consistent with the equilibrium morphology (Figure 1d), as predicted on the basis of ab‐initio surface energy values for both PbTe [ 19 ] and SnTe [ 20 ] in a Te‐poor environment.…”

Section: Selective Area Growth Of Pb1 − Xsnxtementioning

confidence: 97%

“…Here, we investigate the in‐plane SAG of the Pb 1 − x Sn x Te ternary alloy over the full range of x from 0 to 1, by molecular beam epitaxy (MBE) growth, supported by phase‐field simulations. Growth is performed on InP(111)A substrates, as high quality PbTe growth has been shown on this specific substrate orientation in previous work, [ 18 ] and {111} facets can be readily exposed.…”

Section: Introductionmentioning

confidence: 99%

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In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb_{1 − x}Sn_xTe

Schellingerhout,

Bergamaschini,

Verheijen

et al. 2023

Adv Funct Materials

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Predicted topological crystalline insulators such as Pb1 − xSnxTe are an interesting candidate for applications in quantum technology, as they can host spin‐polarized surface states. Moreover, in the nanowire geometry, a quasi‐1D system can be realized with potential applications exploiting Majorana fermions. Herein, the selective area growth of Pb1 − xSnxTe islands and nanowires over the full range of x is demonstrated, and their in‐depth growth dynamics and faceting are analyzed. By transmission electron microscopy, the single‐crystalline and defect‐free nature of the grown material and the homogeneous, controllable Pb/Sn ratio in the nanowires is confirmed. With support of phase‐field growth simulations, it is shown that the crystal faceting mainly follows the driving force of surface energy minimization, favoring the lowest energy {200} surfaces. A kinetic enhancement of adatom incorporation on {110} facets is recognized to limit their extension with respect to {200} and {111} facets. After inspecting all possible in‐plane orientations, we identify the 〈110〉 directions as the optimal candidate for the growth of high‐quality and perfectly straight Pb1 − xSnxTe nanowires, enabling the design of complex networks due to their threefold symmetry. This work opens the way to systematic transport investigation of the carrier density in Pb1 − xSnxTe nanowires and can facilitate further optimization of the Pb1 − xSnxTe system.

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Section: Materials Analysissupporting

confidence: 60%

Section: Selective Area Growth Of Pb1 − Xsnxtementioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb_{1 − x}Sn_xTe

Schellingerhout,

Bergamaschini,

Verheijen

et al. 2023

Adv Funct Materials

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“…32 This may be attributed to the alkaline growth environment of QDs at high temperatures and pressures that promotes recondensation of silicates. 29,33,34 The black dots with a size of approximately 3 nm in the TEM image (Figure 1c) directly evidence the successful growth of CdTe QDs in the DMSN-template, and the lattice of CdTe QDs is around 0.3 nm (inset in Figure 1d). 23,35 Meanwhile, the highresolution TEM (HRTEM) image of UQSN-115 is shown in Figure S2.…”

Section: Resultsmentioning

confidence: 92%

“…The large-area SEM image (Figure S1) and the corresponding inset show that the UQSN-115 surface has no apparent pore size, probably originating from the further hydrolyzed and rapidly reorganized −Si–O- bonds on the surface of DMSN-MPA . This may be attributed to the alkaline growth environment of QDs at high temperatures and pressures that promotes recondensation of silicates. ,, The black dots with a size of approximately 3 nm in the TEM image (Figure c) directly evidence the successful growth of CdTe QDs in the DMSN-template, and the lattice of CdTe QDs is around 0.3 nm (inset in Figure d). , Meanwhile, the high-resolution TEM (HRTEM) image of UQSN-115 is shown in Figure S2. As indicated in the TEM-high-angle annular dark field (TEM-HAADF) image (Figure e) of UQSN-115, the numerous bright spots indicate the high loading and homogeneous distribution of CdTe in the silica matrix, which is further supported by the energy-dispersive X-ray spectroscopy (EDS) elemental mappings (Figure f).…”

Section: Resultsmentioning

confidence: 95%

CdTe/Silica Nanospheres in a Lateral Flow Immunoassay for Prostate-Specific Antigen

Zhang,

Zhao,

Yuan

et al. 2023

ACS Appl. Nano Mater.

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Selective‐Area Growth of Aligned Organic Semiconductor Nanowires and Their Device Integration

Wang,

Luo,

Liao

et al. 2023

Adv Funct Materials

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The simultaneous control of the orientation and position of organic semiconductor nanowires remains a major challenge when integrating them into monolithic devices. In this study, tris(8‐hydroxyquinoline)aluminum(III) (Alq3) molecules are self‐assembled into single‐crystalline nanowires with consistent orientation and predictable positions by selective‐area graphoepitaxial growth. The nanowire orientation is determined by parallel nanogrooves on a periodically modified faceted sapphire surface, and the position is simultaneously defined using a shadow mask. Computational fluid dynamics simulations showed that the mass flow field over the sapphire surface is tailored by the mask, resulting in preferential nanowire nucleation around the hole centers and leaving sufficient free space for the subsequent growth. Accordingly, the number, length, and density of the nanowires can be controlled by adjusting the mask layout. The good alignment and predictable positions of these nanowires facilitated their subsequent device integration, eliminating laborious assembly steps and potential damage after nanowire growth. Measurements from an in situ integrated two‐terminal device based on the Alq3 nanowires revealed that the nanowires exhibit a remarkable negative differential resistance and fast photoresponse in the UV region. Overall, selective‐area graphoepitaxial growth provides a versatile protocol for fabricating site‐ and orientation‐controlled organic semiconductor nanowires for the monolithic fabrication of nanowire‐based devices.

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Selective Area Growth of PbTe Nanowire Networks on InP

Cited by 16 publications

References 49 publications

In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb_{1 − x}Sn_xTe

In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb_{1 − x}Sn_xTe

CdTe/Silica Nanospheres in a Lateral Flow Immunoassay for Prostate-Specific Antigen

Selective‐Area Growth of Aligned Organic Semiconductor Nanowires and Their Device Integration

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Selective Area Growth of PbTe Nanowire Networks on InP

Cited by 16 publications

References 49 publications

In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb1 − xSnxTe

In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb1 − xSnxTe

CdTe/Silica Nanospheres in a Lateral Flow Immunoassay for Prostate-Specific Antigen

Selective‐Area Growth of Aligned Organic Semiconductor Nanowires and Their Device Integration

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Product

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In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb_{1 − x}Sn_xTe

In‐Plane Nanowire Growth of Topological Crystalline Insulator Pb_{1 − x}Sn_xTe