KF/hydrotalcite [14], sulfated zirc

KF/hydrotalcite [14], sulfated zirconia [15], MgO, CaO, PbO, PbO2, Pb3O4, Tl2O3, and ZnO [16], heteropoly acids [17], MgO loaded with KOH [18], etc. Though all the catalysts mentioned above showed a comparative biodiesel yield,sulfated zirconia was found to be the best one. It was reported that 98.6% of yield was obtained with sulfated zirconia while the lowest yield of 85% was obtained with KF/ hydrotalcite. It has been observed that the activities exhibited by the heterogeneous catalysts are very high but their synthesis routes are very lengthy and time consuming. Therefore, there is a need to search for an ideal heterogeneous catalyst which is low cost,
ecofriendly in nature and exhibits high catalytic activity

during
transesterification.
To address these issues, catalyst research for the production of biodiesel is focused towards green catalyst. Such novel catalyst could be prepared either from biomass or from waste generated in the households. Recently waste shells of egg, oyster and shrimp were used for biodiesel production via transesterification. Nakatani et al. [19] reported a high biodiesel yield of 73.8% when the transesterifica- tion was catalyzed by combusted oyster shells and it could be reused for biodiesel production. In another experiment the viability of waste chicken egg shells as solid catalyst was investigated by Wei et al. [20] for transesterification. The researchers not only obtained a high biodiesel yield but they also emphasized that the catalyst prepared was environmentally benign and could be reused.
In this work, we have carried out transesterification using the waste shells of Turbonilla striatula as catalyst. It is easily available in Chirang district of Assam, India and is widely distributed in swamp areas, rivers and agricultural fields. Meat remaining inside the shell is used as one of the food items by some groups of people in that locality. After taking out the meat, the shells have no practical use and are thrown out as waste materials. The activated waste shells are mainly composed of CaO and can be used as heterogeneous catalyst, consequently adding value to the waste generated. In addition, the synthesis route reported here has benefits over existing technologies because this method of preparing catalyst is simple, inexpensive, environmentally benign as well as a good catalyst for biodiesel production. Moreover the utilization of such catalysts for the production of biodiesel also provides an alternative for sustainable development to economically weaker nations. Therefore, the shells of T. striatula may present a good option as a renewable catalyst for biodiesel production. In this study, along with the physical and chemical characterizations of the catalyst, biodiesel components were also analyzed. The effect of various reaction conditions on the biodiesel yields was also investigated.