Solar photovoltaic (PV) energy will shortly be in great demand, since it is inexhaustible and cleaner than any conventional energy resources. The global PV production was over 2.6 GW in 2006 alone, out of which, the majority was the silicon wafer-based solar cells. Because the fast growing PV market is mainly based on crystalline silicon, the lack of silicon raw materials in recent years is becoming a critical issue. The exponential growth of the solar cell industry has driven up the price of silicon several times and the shortage of silicon has been a serious issue since 2003. So far, most of solar grade silicon (SoG-Si) is from the Siemens process, which is energy intensive and high cost. Therefore, cheaper routes for producing SoG-Si are being developed in the PV industries, but the progress in slow. The price of raw silicon has increased almost ten times for the past five years. Therefore, seeking a feasible and low-cost route for producing SoG-Si is important for the PV industry. On the other hand, because there is about 40% kerf silicon loss during slicing processing, the recycle of the silicon from the cutting slurry could save the raw material used significantly. However, the attempt has not yet been succeeded so far. In this thesis, we developed a novel approach to recover SoG-Si from the Si/SiC mixture obtained from the cutting slurry waste. Herein a detailed discussion of the processes involved in the whole recycle research is reported. The average resistivity and minority carrier lifetime of the grown crystals from recycled silicon were found to be about 0.7 Ω-cm and 1.02 μs, respectively, which were close to the original sawing silicon ingots. Solar cells using multi-crystalline wafers of recovered silicon were fabricated and the best energy conversion efficiency (12.6%) was comparable to the ones from the high-purity silicon (13.2%). The yield of recycle process is about 20% and the cost (32 $/kg) is much lower than the right now price of solar grade silicon. Multi-crystalline silicon (mc-Si) grown by the directional solidification method has attracted world wide attention as a solar cell material because of its low production cost and high throughput. However, the efficiency of mc-Si solar cells is usually lower than single-crystalline silicon solar cells because of the presence of variety of defects such as randomly oriented grain boundaries, dislocations, inclusions and oxides, in large concentration. These defects act as recombination center for light generated electrons and holes and therefore are harmful for the solar cell performance. Recently, grain boundaries have been shown to have different characteristics under different orientations. For example, the Σ3 boundary is a well-known inactive boundary as it does not act as recombination center. Therefore, in order to improve the efficiency of mc-Si based solar cells, efforts have been directed towards growth of mc-Si with highly oriented grains. In fact, controlling the cooling speed during initial stage of solidification induces dendrite growth along the crucible bottom wall which is responsible for growth of large grains with Σ3 grain boundary. In this thesis, we report a novel method to control the grain orientation by using cooling spots at the bottom of the crucible. The cooling spots induce locally larger radial thermal gradients to enhance dendritic growth, but not limited to the size of the crucible. Studies have been carried out for laboratory scale, and some preliminary results have been obtained from an industrial scale experiment. The minority carrier lifetime measurements and electron back scattering pattern analysis in the grown crystals have been carried out to assess the effect of using cooling spot.