Carbon emission is the biggest problem all over the world. The actualizing of low carbon emission in the bread kitchen and dessert shop segment permits the difference in its mechanical procedure through the improvement of an eco-proficient framework. This study was to line up bread and cake with fully completely different wheat quality, baking time, and temperature through low carbon emission. The prepared samples were chemically analyzed for wet content, ash content, compound content, and organoleptic. Among the four processed cake products based on each parameter tested organoleptically, cupcake products were the most preferable one. Bread products made with substitution of 50% have been received by consumer panelists. The results of this study were also in line with the research conducted by which resulted in a substitution of spinach flour substitution of up to 60% still acceptable by panelists. Sponge cake from flour can still be received by panelists with 50% substitution. 12% of moisture will help 5 days’ self-life without chemical preservatives. The oven is the largest of the three consumers and typically accounts for between 35% and 45% of the total site carbon emissions. The dark cake pan, which holds in more heat than light-colored baking pans and bakes our cake batter faster. Considering that the most significant dark non-stick pan was suggested for baking low carbon emission, it will be reducing the baking temperature by 25° F. Good practice opportunities can be delivered for various plant/equipment utility serving could deliver on average a 10% saving in total CO2 emissions for the sector. This would speak to a CO2 decrease of 57 000 ton CO2 / year over the world.
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 S. Aralas, M. Mohamed, M. Fadzelly and Bakar, “An antioxidant property of selected salak (Salacca zalacca) varieties in Sabah Malaysia”, Nutrition & Food Science, Vol. 39 (3), Pp. 243-250, 2009.
 T. Budiyanti, S. Hadiati, R. Prihatini and Sobir, “Genetic Diversity of Indonesian Snake Fruits as Food Diversification Resources”, International Journal on Advanced Science Engineering Information Technology, Vol. 5 (3), Pp 41–44, 2015.
 P. Stephan, K. Annette and H. Stefanie, “Assessing the environmental impacts of freshwater consumption in LCA”, International Journal of Environmental Science and Technology, Vol. 43 (11), Pp 4098-4104, 2009.
 AA. Aziah, WL. Min and R. Bhat, “Nutritional and sensory quality evaluation of sponge cake prepared by incorporation of high dietary fiber containing mango (Mangifera indica var Chokanan) pulp and peel flours”, Int J Food Sci Nutr Vol. 62 (6), Pp 559–567, 2011.
 K. Antonios, S. Laurence and A. Adisa, “Economic sustainability of food supply chains: life cycle costs and value added in the confectionary and frozen desserts sectors”, Science of the Total Environment, Vol. 670, Pp 902-914, 2019.
 T. Ismail, S. Akhtar, M. Riaz and Ismail, “An effect of pomegranate peel supplementation on nutritional, organoleptic and stability properties of cookies”, International Journal of Food Sciences and Nutrition, Vol. 65 (6), Pp 661–666, 2014.
 SS. Sarabjit, and MA. Juan, “Functionality of emulsifiers in sponge cake production”, Journal of the Science of Food and Agriculture, Vol. 83 (14), 2003.
 YM. Sakin, EF. Kaymak, and C. Ilicali, “Modeling of simultaneous heat and mass transfer during convective oven ring cake baking”, Journal of Food Engineering, 111 (2), Pp 289–298, 2012.
 AFC. Passini, P. Chagas, and JO. Demarco, “Cleaner production options for a small bakery”, Scientific Electronic Library Online, Vol. 26 (3), Pp 3613-3619, 2019.
 R. Rahim, and AAR. Abdul, “Carbon dioxide emission reduction through cleaner production strategies in a recycled plastic resins producing plant”, Journal of Cleaner Production, Vol. 141 (10), Pp 1067-1073, 2017.