Crystal Damage and Surface Morphology in Industrial Diamond Wire Slicing of 300 mm Monocrystalline Silicon Wafers for Microelectronic Devices
At a Glance
Section titled âAt a Glanceâ| Metadata | Details |
|---|---|
| Publication Date | 2024-12-18 |
| Journal | Advanced Materials Technologies |
| Authors | Stephan Oberhans, Wolfgang HeiĂ, G. J. Pietsch |
| Institutions | Friedrich-Alexander-Universität Erlangen-Nßrnberg |
| Citations | 2 |
Abstract
Section titled âAbstractâAbstract In the semiconductor industry, thin wafers are cut from a monocrystalline silicon. The most important process step is cutting the monocrystal into a multitude of thin substrate slices, which determines the properties of the resulting wafers. Some time ago, the transition from traditional slurryâwireâslicing (SâMWS) to diamondâwireâslicing (DâMWS), which is more costâeffective and resourceâefficient, took place. Unlike in the photovoltaic industry and also in the production of smaller wafer diameters of up to 200 mm, it is not possible to create a seamless transition with todayâs standard wafer diameters of 300 mm due to the waviness that occurs on the wafer surface immediately after the cutting process. This situation considerably limits the achievable component generation (design rule), as the strict requirements of the chip manufacturers cannot be fulfilled. Therefore, a comprehensive understanding of the process is required. A detailed comparison of the surface structure, surface topography, and fracture strength is carried out based on the three relevant crystal orientations Silicon(100), Silicon(110), and Silicon(111). In addition, some wire segments are examined. All microscopic examinations carry out on both the primary and secondary chipping faces do not provide any correlation between the microscopic surface condition and the macroscopic waviness.