Growth of Ge1−xSnx Nanowires by Chemical Vapor Deposition via Vapor–Liquid–Solid Mechanism Using GeH4 and SnCl4

Haffner, T.; Zeghouane, Mohammed; Bassani, F.; Gentile, P.; Gassenq, A.; Chouchane, Fares; Pauc, N.; Martínez, E.; Robin, Éric; David, S.; Baron, T.; Salem, B.

doi:10.1002/pssa.201700743

Cited by 20 publications

(28 citation statements)

References 28 publications

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“…Figure 3 shows a tin-rich nanoparticle at the tip of a Ge 1−x Sn x nanowire, once again confirming the SLS growth mechanism. EDX line scanning and mapping revealed homogeneously distributed tin throughout the nanowire with no evidence of tin segregation or a tin-rich shell has been observed in other work [18]. EDS spot analysis was performed on more than twenty individual Ge 1−x Sn x nanowires at the seed (A), growing zone (B), middle (C) and tip (D) sections.…”

Section: Resultsmentioning

confidence: 81%

“…The synthesis of Ge 1−x Sn x is challenging due to the low solubility of tin in germanium (<1%) [16], large lattice mismatch (∼14%) and a tendency of metallic tin to segregate from germanium [17,18]. Ge 1−x Sn x alloys are commonly fabricated using ion implantation, laser melting [4,5,19], molecular beam epitaxy (MBE) [7], and chemical-vapor deposition(CVD) approaches [6,[20][21][22].…”

Section: Introductionmentioning

confidence: 99%

“…The most established synthetic approaches, for group IV nanowires (such as Ge and Ge 1−x Sn x ), involve the use of metal growth-promoters in bottom-up processes such as: vapour-liquid-solid (VLS), vapor-solid-solid (VSS), In-plane-solid-liquid-solid (IP-SLS), supercritical fluid-liquid-solid (SFLS) and solution-liquid-solid (SLS) mechanisms. [12,18,23,26,27,29]. Amongst these, the SLS approach offers benefits such as low equipment cost, high scalability, mild-reaction conditions, easy control, and access to non-flammable germanium precursors (such as triphenylchlorogermane) [30].…”

Section: Introductionmentioning

confidence: 99%

“…In order to fabricate Ge 1−x Sn x nanowires incorporating high tin content, non-equilibrium introduction of tin into the germanium lattice has been proposed and demonstrated by several groups. These used either a VLS mechanism from liquid-injection CVD upon Au [18] or AuAg catalysts [12,26], or IPSLS approach [23,27]. However, reports focused on self-seeded SLS growth of high quality Ge 1−x Sn x nanowires from tin catalyst are rare.…”

Section: Introductionmentioning

confidence: 99%

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Facile synthesis of Ge_1−xSn_x nanowires

Al-Salim

Lim

et al. 2020

Mater. Res. Express

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We report a facile one-pot solution phase synthesis of one-dimensional Ge 1−x Sn x nanowires. These nanowires were synthesized in situ via a solution-liquid-solid (SLS) approach in which triphenylchlorogermane was reduced by sodium borohydride in the presence of tin nanoparticle seeds. Straight Ge 1−x Sn x nanowires were obtained with an average diameter of 60±20 nm and an approximate aspect ratio of 100. Energy-dispersive x-ray spectroscopy (EDX) and powder x-ray diffraction (PXRD) analysis revealed that tin was homogeneously incorporated within the germanium lattices at levels up to 10 at%, resulting in a measured lattice constant of 0.5742 nm. The crystal structure and growth orientation of the nanowires were investigated using high-resolution transmission electron microscopy (HRTEM). The nanowires adopted a face-centred-cubic structure with individual wires exhibiting growth along either the 〈111〉, 〈110〉 or 〈112〉 directions, in common with other group IV nanowires. Growth in the 〈112〉 direction was found to be accompanied by longitudinal planar twin defects.

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Section: Resultsmentioning

confidence: 81%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Facile synthesis of Ge_1−xSn_x nanowires

Al-Salim

Lim

et al. 2020

Mater. Res. Express

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“…However, because of the large lattice mismatch between Ge and Sn (14%), the preservation of the crystallographic quality of the material appears as the main challenge prohibiting this goal [12, 13]. A potentially interesting solution to increase the emission wavelength and ensure better carrier confinements relay on lower dimensional structures such as nanowires [14–16], nanorods [17], and quantum dots [18]. Within the specific directness criteria, the direct bandgap interband emission wavelength is theoretically limited to 4.3 μm [19].…”

Section: Introductionmentioning

confidence: 99%

Design of Strain-Engineered GeSn/GeSiSn Quantum Dots for Mid-IR Direct Bandgap Emission on Si Substrate

et al. 2018

Self Cite

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Strain-engineered self-assembled GeSn/GeSiSn quantum dots in Ge matrix have been numerically investigated aiming to study their potentiality towards direct bandgap emission in the mid-IR range. The use of GeSiSn alloy as surrounding media for GeSn quantum dots (QD) allows adjusting the strain around the QD through the variation of Si and/or Sn composition. Accordingly, the lattice mismatch between the GeSn quantum dots and the GeSiSn surrounding layer has been tuned between − 2.3 and − 4.5% through the variation of the Sn barrier composition for different dome-shaped QD sizes. The obtained results show that the emission wavelength, fulfilling the specific QD directness criteria, can be successively tuned over a broad mid-IR range from 3 up to7 μm opening new perspectives for group IV laser sources fully integrated in Si photonic systems for sensing applications.

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High Aspect‐ratio Germanium‐Tin Alloy Nanowires: Potential as Highly Efficient Li‐Ion Battery Anodes

Garcia-Gil

Biswas

McNulty

et al. 2022

Adv Materials Inter

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Here, the fabrication of a high aspect ratio (>440) Ge1−xSnx nanowires with super‐thin (≈9 nm) diameter, much below the Bohr radius, using a simple solvothermal‐like growth method under supercritical toluene conditions at a reaction temperature of 440 °C is reported. Ge1−xSnx nanowires are grown with varying amounts of Sn in Ge lattice, between 3.1 to 10.2 at%. The growth of the Ge1−xSnx alloy nanowires is achieved without any additional catalysts, and directly on current collector substrates (titanium) for application as Li‐ion battery anodes. The electrochemical performance of the binder‐free Ge1−xSnx nanowires as an anode material for Li‐ion batteries is investigated via galvanostatic cycling and detailed analysis of differential capacity plots. The dimensions of the nanowires, and the amount of Sn in Ge, are critical to achieving a high specific capacity and capacity retention. Ge1−xSnx nanowires with the highest aspect ratios and with the lowest Sn content (3.1 at%) demonstrate exceptional capacity retention of ≈90% and 86% from the 10th to the 100th and 150th cycles respectively, while maintaining a very high specific capacity value of 1176 and 1127 mAh g−1 after the 100 and 150 cycles respectively.

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Growth of Ge_1−xSn_x Nanowires by Chemical Vapor Deposition via Vapor–Liquid–Solid Mechanism Using GeH₄ and SnCl₄

Cited by 20 publications

References 28 publications

Facile synthesis of Ge_1−xSn_x nanowires

Facile synthesis of Ge_1−xSn_x nanowires

Design of Strain-Engineered GeSn/GeSiSn Quantum Dots for Mid-IR Direct Bandgap Emission on Si Substrate

High Aspect‐ratio Germanium‐Tin Alloy Nanowires: Potential as Highly Efficient Li‐Ion Battery Anodes

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Growth of Ge1−xSnx Nanowires by Chemical Vapor Deposition via Vapor–Liquid–Solid Mechanism Using GeH4 and SnCl4

Cited by 20 publications

References 28 publications

Facile synthesis of Ge1−xSnx nanowires

Facile synthesis of Ge1−xSnx nanowires

Design of Strain-Engineered GeSn/GeSiSn Quantum Dots for Mid-IR Direct Bandgap Emission on Si Substrate

High Aspect‐ratio Germanium‐Tin Alloy Nanowires: Potential as Highly Efficient Li‐Ion Battery Anodes

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Growth of Ge_1−xSn_x Nanowires by Chemical Vapor Deposition via Vapor–Liquid–Solid Mechanism Using GeH₄ and SnCl₄

Facile synthesis of Ge_1−xSn_x nanowires

Facile synthesis of Ge_1−xSn_x nanowires