Spectroscopic studies of the mechanism for hydrogen-induced exfoliation of InP

Morral, Anna Fontcuberta i; Zahler, James M.; Griggs, M. J.; Atwater, Harry A.; Chabal, Yves J.

doi:10.1103/physrevb.72.085219

Cited by 28 publications

(15 citation statements)

References 26 publications

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“…This shoulder encompasses the reported values of 1978 cm −1 for the Ge͑111͒ surface mono-hydride. 9 Thus, these data provide evidence of the presence of ͑100͒ and ͑111͒ internal surfaces at 501°C.…”

Section: Temperature Dependencementioning

confidence: 52%

“…In the same sample and following exfoliation at 399°C, there is a broad tail toward 1950 cm −1 that is consistent with the presence of Ge͑111͒ surface monohydride modes. 9 The mechanism described above is similar to the case of silicon, but there are some differences. In both cases there is a formation and transformation of hydrogenated vacancy species into extended internal surfaces.…”

Section: Discussionmentioning

confidence: 95%

“…[2][3][4][5][6] The mechanism of H-induced exfoliation has been extensively studied in the case of silicon, 7,8 and, more recently, in the case of InP. 9 The early work of Weldon et al provided important conclusions: ͑i͒ implantation induced defects serve to trap H within the Si substrate. ͑ii͒ A broad distribution of vacancy hydrogen defect structures is the main reservoir for hydrogen that contribute to the exfoliation process.…”

Section: Introductionmentioning

confidence: 99%

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Role of hydrogen in hydrogen-induced layer exfoliation of germanium

et al. 2007

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The role of hydrogen in the exfoliation of Ge is studied using cross-sectional transmission electron microscopy, atomic force microscopy, and multiple-internal transmission mode Fourier-transform infrared absorption spectroscopy and compared with the mechanism in silicon. A qualitative model for the physical and chemical action of hydrogen in the exfoliation of these materials is presented, in which H-implantation creates damage states that store hydrogen and create nucleation sites for the formation of micro-cracks. These micro-cracks are chemically stabilized by hydrogen passivation, and upon annealing serve as collection points for molecular hydrogen. Upon further heating, the molecular hydrogen trapped in these cracks exerts pressure on the internal surfaces causing the cracks to extend and coalesce. When this process occurs in the presence of a handle substrate that provides rigidity to the thin film, the coalescence of these cracks leads to cooperative thin film exfoliation. In addition to clarifying the mechanism of H-induced exfoliation of single-crystal thin Ge films, the vibrational study helps to identify the states of hydrogen in heavily damaged Ge. Such information has practical importance for the optimization of H-induced layer transfer as a technological tool for materials integration with these materials systems.

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Section: Temperature Dependencementioning

confidence: 52%

Section: Discussionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

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Role of hydrogen in hydrogen-induced layer exfoliation of germanium

et al. 2007

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“…However, to exfoliate an implanted InP layer using the ion-cut method, it is generally necessary to implant hydrogen ions at a high dosage of several times 10 16 /cm 2 into the semiconductor donor. 5 Due to such high concentrations, the transferred layers suffer from implantation-induced damage, which cannot be easily remedied even through high-temperature thermal annealing beyond 600°C, at which point InP decomposes through the preferential evaporation of phosphorus. 3,6 Additional processing complications required for annealing above 600°C are the use of a capping layer or high phosphorus overpressure.…”

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confidence: 99%

InP Layer Transfer with Masked Implantation

Chen¹,

Bandaru

Tang

et al. 2009

Electrochem. Solid-State Lett.

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InP layer transfer with masked implantation was investigated to eliminate ion-implantation induced damage involved in the ion-cut process. InP donor wafers were selectively implanted with hydrogen through a mask at a dose of 8.5 ϫ 10 16 ions/cm 2 at 160 keV. The layers which were subsequently mechanically exfoliated were characterized by large pyramidal protrusions on the surface, associated with the unimplanted regions. This undesirable morphology was bypassed through the inclusion of a selective etch-stop layer. The resulting structures possessed flat surfaces suitable for further bonding. This process enables the transfer of finished devices, unaffected by ion-implantation, onto a variety of desirable substrates.

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“…8-10 A few works have also reported on this phenomenon in some conventional compound semiconductors. [11][12][13] Techniques such as vibrational spectroscopies, [14][15][16][17][18][19] transmission electron microscopy, 10,20 Rutherford backscattering spectrometry in the channeling mode, [21][22][23] x-ray diffraction, 24 and positron annihilation spectroscopy 22,25 improved greatly our understanding of the microscopic mechanisms of the ion-cut process ͑particularly in Si͒. These studies have demonstrated the critical role of H-vacancy ͑H-V͒ complexes and damage-generated stress in the formation of nanoscopic platelets and voids immediately after implantation.…”

Section: Introductionmentioning

confidence: 98%

Experimental elucidation of vacancy complexes associated with hydrogen ion-induced splitting of bulk GaN

et al. 2010

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We present a detailed study of the thermal evolution of H ion-induced vacancy related complexes and voids in bulk GaN implanted under ion-cut conditions. By using transmission electron microscopy, we found that the damage band in as-implanted GaN is decorated with a high density of nanobubbles of ϳ1 -2 nm in diameter. Variable energy Doppler broadening spectroscopy showed that this band contains vacancy clusters and voids. In addition to vacancy clusters, the presence of V Ga , V Ga -H 2 , and V Ga V N complexes was evidenced by pulsed low-energy positron lifetime spectroscopy. Subtle changes upon annealing in these vacancy complexes were also investigated. As a general trend, a growth in open-volume defects is detected in parallel to an increase in both size and density of nanobubbles. The observed vacancy complexes appear to be stable during annealing. However, for temperatures above 450°C, unusually large lifetimes were measured. These lifetimes are attributed to the formation of positronium in GaN. Since the formation of positronium is not possible in a dense semiconductor, our finding demonstrates the presence of sufficiently large open-volume defects in this temperature range. Based on the Tao-Eldrup model, the average lattice opening during thermal annealing was quantified. We found that a void diameter of 0.4 nm is induced by annealing at 600°C. The role of these complexes in the subsurface microcracking is discussed.

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Spectroscopic studies of the mechanism for hydrogen-induced exfoliation of InP

Cited by 28 publications

References 26 publications

Role of hydrogen in hydrogen-induced layer exfoliation of germanium

Role of hydrogen in hydrogen-induced layer exfoliation of germanium

InP Layer Transfer with Masked Implantation

Experimental elucidation of vacancy complexes associated with hydrogen ion-induced splitting of bulk GaN

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