Abstract: Methods and apparatus are presented to measure the photoluminescence of incoming wafers and extract parameters such as minority carrier life time, diffusion length, and defect density that may be used to predict final solar cell efficiency. In some examples, illumination light is supplied to a side of an as-cut silicon wafer and the induced luminescence measured from the same side and the opposite side of the wafer is used to determine an indication of the minority carrier lifetime. In another example, the luminescence induced by two instances of illumination light of different wavelength is used to determine an indication of the minority carrier lifetime. In another example, the spatial distribution of luminescence intensity over an area surrounding a focused illumination spot is used to determine an indication of the minority carrier lifetime. Other apparatus useful to passivate the surface of a wafer for inspection are also presented.

Abstract: Methods and apparatus are presented to measure the photoluminescence of incoming wafers and extract parameters such as minority carrier life time, diffusion length, and defect density that may be used to predict final solar cell efficiency. In some examples, illumination light is supplied to a side of an as-cut silicon wafer and the induced luminescence measured from the same side and the opposite side of the wafer is used to determine an indication of the minority carrier lifetime. In another example, the luminescence induced by two instances of illumination light of different wavelength is used to determine an indication of the minority carrier lifetime. In another example, the spatial distribution of luminescence intensity over an area surrounding a focused illumination spot is used to determine an indication of the minority carrier lifetime. Other apparatus useful to passivate the surface of a wafer for inspection are also presented.