On the mechanical strength of monocrystalline, multicrystalline and quasi‐monocrystalline silicon wafers: a four‐line bending test study

Barredo, J.; Parra, Vicente; Guerrero, Ismael; Fraile, Alberto; Hermanns, Ludger M.

doi:10.1002/pip.2372

Cited by 15 publications

(10 citation statements)

References 16 publications

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“…Previous research on wafer thinning has focused on two aspects: (i) improving existing equipment and techniques for processing, 12,13,18,19 and (ii) studying the mechanics of crack propagation to avoid fracturing. 18−21 While these efforts have led to improvements, the typical method for processing silicon wafers has remained relatively constant for the past six decades.…”

Section: ■ Introductionmentioning

confidence: 99%

Polycyclic Aromatic Hydrocarbons as Sublimable Adhesives

et al. 2017

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Polycyclic aromatic hydrocarbons (PAHs) are used as adhesives that can be removed on-demand by sublimation without application of solvent or mechanical force. These adhesives are polycrystalline solids that enable bonding of glass, metal, and plastic with lap shear forces ranging from 5 to 50 N cm −2 . Systematic examination of factors governing bonding suggests that favorable chemical interactions between bonded surfaces and PAHs, and structural features at the surface of the substrate influence both the lap shear force and the mechanism of failure. Utilizing sublimable PAHs enables sequential bonding and release of substrates, as well as control of actuation of electronic systems through mechanical work.

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Section: ■ Introductionmentioning

confidence: 99%

Polycyclic Aromatic Hydrocarbons as Sublimable Adhesives

et al. 2017

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“…It was reported that quasi‐mono silicon has higher averaged residual stress than multi‐crystalline silicon, and the strength of the former is weaker than the latter especially when appearance of locally high density defects . To our surprise, the statistical fracture strengths of multi‐crystalline silicon wafers are comparable with or even higher than those of CZ silicon wafers by Weibull distribution. The influence of GBs on the mechanical properties and the weak point in multi‐crystalline silicon wafer are not well understood yet.…”

Section: Introductionmentioning

confidence: 57%

“…The stress fields around GBs are critical in terms of the mechanical stability of the wafer, as they can act as sources for crack formation if additional force is applied . It was reported that quasi‐mono silicon has higher averaged residual stress than multi‐crystalline silicon, and the strength of the former is weaker than the latter especially when appearance of locally high density defects . To our surprise, the statistical fracture strengths of multi‐crystalline silicon wafers are comparable with or even higher than those of CZ silicon wafers by Weibull distribution.…”

Section: Introductionmentioning

confidence: 68%

Effect of Small‐Angle Grain Boundary on the Mechanical Properties in Direct Silicon Bonded Wafer

Wang

Cui

et al. 2018

Physica Status Solidi (a)

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The mechanical properties of small-angle grain boundary (GB) in direct silicon bonded wafer are investigated by dislocation motion using the Vickers micro-indentation combined with nano-indentation technique. The dislocation motion is thoroughly hampered at the GB, due to the large strain field (comprehensive stress as high as %339 MPa), which is demonstrated by the micro-Raman spectroscopy measurement. Nanoindentation tests directly on GB show that Young's modulus and hardness are almost identical to those in the grain. The results indicate that electrically active small-angle GB with high stress should not be the weak point of mechanical strength in multi-crystalline silicon.

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“…Therefore, an increase in the macroscopic breakage yield during the industrial handling can be expected. It has been verified that there were direct effects of such a high density of defects (Figure 9(a)) in the fracture tension limits of the wafers, as determined by a systematic four-line bending test (FLBT) analysis [10]. By FLBT fitted to the corresponding Weibull distribution analysis, a batch of 50 highly dislocated mono-like wafers exhibited up to ca.…”

Section: Towards the Seed Recyclingmentioning

confidence: 86%

About the origin of low wafer performance and crystal defect generation on seed-cast growth of industrial mono-like silicon ingots

Guerrero

Parra

Carballo

et al. 2012

Prog. Photovolt: Res. Appl.

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The era of the seed-cast grown monocrystalline-based silicon ingots is coming. Mono-like, pseudomono or quasimono wafers are product labels that can be nowadays found in the market, as a critical innovation for the photovoltaic industry. They integrate some of the most favorable features of the conventional silicon substrates for solar cells, so far, such as the high solar cell efficiency offered by the monocrystalline Czochralski-Si (Cz-Si) wafers and the lower cost, high productivity and full square-shape that characterize the well-known multicrystalline casting growth method. Nevertheless, this innovative crystal growth approach still faces a number of mass scale problems that need to be resolved, in order to gain a deep, 100% reliable and worldwide market: (i) extended defects formation during the growth process; (ii) optimization of the seed recycling; and (iii) parts of the ingots giving low solar cells performance, which directly affect the production costs and yield of this approach. Therefore, this paper presents a series of casting crystal growth experiments and characterization studies from ingots, wafers and cells manufactured in an industrial approach, showing the main sources of crystal defect formation, impurity enrichment and potential consequences at solar cell level. The previously mentioned technological drawbacks are directly addressed, proposing industrial actions to pave the way of this new wafer technology to high efficiency solar cells.

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On the mechanical strength of monocrystalline, multicrystalline and quasi‐monocrystalline silicon wafers: a four‐line bending test study

Cited by 15 publications

References 16 publications

Polycyclic Aromatic Hydrocarbons as Sublimable Adhesives

Polycyclic Aromatic Hydrocarbons as Sublimable Adhesives

Effect of Small‐Angle Grain Boundary on the Mechanical Properties in Direct Silicon Bonded Wafer

About the origin of low wafer performance and crystal defect generation on seed-cast growth of industrial mono-like silicon ingots

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