Large‐Scale Formation of Uniform Porous Ge Nanostructures with Tunable Physical Properties

Hanuš, Tadeáš; Arias-Zapata, J.; Ilahi, Bouraoui; Provost, Philippe‐Olivier; Cho, Jinyoun; Dessein, Kristof; Boucherif, Abderraouf

doi:10.1002/admi.202202495

Cited by 17 publications

(12 citation statements)

References 54 publications

(107 reference statements)

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“…The apparent waving of the cleaned surface represents a slight variation in the initial Ge bulk/PGe interface formed during the BEE process, as the bottoms of the pores are not all perfectly aligned. This effect is then partially mitigated directly by the first anodic step of the BEE process during the formation of the new PGe layer [43,48].…”

Section: Resultsmentioning

confidence: 99%

“…PGe layers were formed using an optimized bipolar electrochemical etching (BEE) process [43] on top of Ge substrates. The p-type gallium (Ga) doped, 100 mm Ge wafers oriented along the (100) axis, with 6 • off-axis miscut towards (111) orientation and resistivity of 8-30 mΩ•cm were used in this study.…”

Section: Sample Preparationmentioning

confidence: 99%

“…At the end of the process, PGe substrates were rinsed with EtOH (99 wt%), dried under N 2 flow, and subsequently placed into the loading chamber of the growth reactor under a vacuum. Further details on PGe formation can be found in our previous work [43].…”

Section: Sample Preparationmentioning

confidence: 99%

“…Among them, the porosification lift-off technique has recently received significant attention and development thanks to its potentially high-throughput and cost-effective process [20,25]. This approach involves the formation of a uniform and tunable porous Ge (PGe) layer [43] using electrochemical etching [44][45][46][47], followed by the deposition of a Ge membrane on top of it. The membrane can then be detached from the parent substrate through the weak nanostructured interface, forming a thin Ge FSM.…”

Section: Introductionmentioning

confidence: 99%

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Sustainable Production of Ultrathin Ge Freestanding Membranes

Hanuš,

Ilahi,

Cho

et al. 2024

Sustainability

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Germanium (Ge) is a critical material for applications in space solar cells, integrated photonics, infrared imaging, sensing, and photodetectors. However, the corresponding cost and limited availability hinder its potential for widespread applications. However, using Ge freestanding membranes (FSMs) allows for a significant reduction in the material consumption during device fabrication while offering additional advantages such as lightweight and flexible form factor for novel applications. In this work, we present the Ge FSM production process involving sequential porous Ge (PGe) structure formation, Ge membrane epitaxial growth, detachment, substrate cleaning, and subsequent reuse. This process enables the fabrication of multiple high-quality monocrystalline Ge FSMs from the same substrate through efficient substrate reuse at a 100 mm wafer scale by a simple and low-cost chemical cleaning process. A uniform, high-quality PGe layer is produced on the entire recovered substrate. By circumventing the use of conventional high-cost chemical–mechanical polishing or even substantial chemical wet-etching, and by using an optimized PGe structure with reduced thickness, the developed process allows for both cost and an environmental impact reduction in Ge FSMs production, lowering the amount of Ge used per membrane fabrication. Moreover, this process employs large-scale compatible techniques paving the way for the sustainable production of group IV FSMs for next-generation flexible optoelectronics.

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Section: Resultsmentioning

confidence: 99%

Section: Sample Preparationmentioning

confidence: 99%

Section: Sample Preparationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sustainable Production of Ultrathin Ge Freestanding Membranes

Hanuš,

Ilahi,

Cho

et al. 2024

Sustainability

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“…In the present work, we introduce the Porous germanium Efficient Epitaxial LayEr Release (PEELER) process for wafer-scale growth of monocrystalline Ge NMs and their detachment, compatible with Ge substrate reuse. This approach consists of four key steps: (i) wafer-scale porosification by bipolar electrochemical etching (BEE) of Ge wafer, 26 (ii) growth of a monocrystalline Ge NM on porous Ge (PGe), 25 (iii) Ge NM detachment from the substrate, (iv) substrate reconditioning by chemical etching to enable reuse of the substrate for production of multiple Ge NMs. 27 Here, we provide detailed structural investigations of the epitaxial Ge NMs by High-resolution transmission electron microscopy (HRTEM).…”

Section: Introductionmentioning

confidence: 99%

Wafer-scale detachable monocrystalline germanium nanomembranes for the growth of III–V materials and substrate reuse

et al. 2023

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High‐Efficiency GaAs Solar Cells Grown on Porous Germanium Substrate with PEELER Technology

Daniel,

Bidaud,

Chretien

et al. 2023

Solar RRL

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III‐V solar cells are mainly grown on GaAs or Ge substrate, which significantly contributes to the final cost and affects the sustainable use of these rare materials. We developed a so‐called PEELER process in which a porosification technique is used to create a weak layer between a Ge substrate and the epitaxial layers. This method enables the separation of the grown layers, allowing for the subsequent reuse of germanium and a reduction in the environmental and economic cost of optoelectronic devices. Technology validation using the device performance is important to assess the technology interest. For this purpose, we fabricated and compared the performance of 22 non‐detached single‐junction (s‐j) GaAs photovoltaic cells grown and manufactured on porosified 100mm Ge wafer without anti‐reflection coating (ARC). All the cells exhibit comparable performance to state‐of‐the‐art GaAs solar cells (grown or Ge or GaAs) with high efficiency (21.8% ± 0.78%) and thereby demonstrate the viability of growing high‐performance optoelectronic devices on detachable Ge films.This article is protected by copyright. All rights reserved.

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Large‐Scale Formation of Uniform Porous Ge Nanostructures with Tunable Physical Properties

Cited by 17 publications

References 54 publications

Sustainable Production of Ultrathin Ge Freestanding Membranes

Sustainable Production of Ultrathin Ge Freestanding Membranes

Wafer-scale detachable monocrystalline germanium nanomembranes for the growth of III–V materials and substrate reuse

High‐Efficiency GaAs Solar Cells Grown on Porous Germanium Substrate with PEELER Technology

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