Biogas can play the pivotal role in the production of carbon-neutral fuels of high quality as well as providing feedstocks for various industries. This is a unique property of biogas compared with other REs, which makes biogas a prime alternative to the use of fossil fuels. The performance of biogas-based systems for heat and power generation has already been proved in many situations on commercial as well as domestic scales.

In addition, biogas wastes can also yield liquid fuels, such as cellulosic ethanol, which can be used to replace petroleum-based fuels. Cellulosic ethanol can be produced from grasses, wood chips, and agricultural residues by biochemical route using heat, pressure, chemicals, and enzymes unlocking the sugars in cellulosic biogas. Algal biogas is also emerging as a good source of energy, because it can serve as a natural source of oil, which conventional refineries can transform into jet fuel or diesel fuel. Biogas energy systems have the potential to address many environmental issues, especially global warming and GHG emissions, and foster sustainable development among poor communities. Biogas fuel sources are readily available in the rural and urban areas of all countries. Biogas-based industries can provide appreciable employment opportunities and promote biogas regrowth through sustainable land management practices. The negative aspects of traditional biogas utilization in developing countries can be mitigated by the promotion of modern waste-to-energy technologies that provide solid, liquid, and gaseous fuels as well as electricity for house appliances, commercial buildings, and different types of industries. Biogas wastes can be transformed into clean and efficient energy by biochemical as well as thermochemical technologies. Fig. 1.1 shows the types of biogases, which include different forms of biogas such as virgin wood, energy crops, agricultural waste, and waste from other materials. Virgin wood is also classified into tree surgery residues, forestry residues, and fuel wood, as shown in Fig. 1.2. Figs. 1.3–1.5 also show the types of energy crops, agricultural wastes, and other wastes, respectively.

Rather than thermochemical technologies, the most common technique for producing both heat and electrical energies from biogas wastes is direct combustion. In direct combustion, the thermal efficiencies as high as 80%–90% can be achieved by advanced gasification technology with greatly reduced atmospheric emissions. Combined heat and power (CHP) systems, ranging from small-scale technology to large grid-connected facilities, provide significantly higher efficiencies than systems that only generate electricity. Biochemical processes, like anaerobic digestion and sanitary landfills, can also produce clean energy in the form of biogas and producer gas, which can be converted into power and heat using a gas engine. A biogas system also uses plant or animal material for energy generation, for heat production, or in various industrial processes as the raw material for a range of products. It can be purposely grown energy crops, wood or forest residues, waste from food crops (wheat straw and bagasse), horticulture (yard waste), food processing (corn cobs), animal farming (manure, rich in nitrogen and phosphorus), or human waste from sewage plants. Burning plant-derived biogas releases CO₂, but it has still been classified as an RE source in the European Union and United Nation legal frameworks, because photosynthesis cycles the CO₂ back into new crops. In some cases, this recycling of CO₂ from plants to the atmosphere and back into plants can even be CO₂ negative, as a relatively large portion of the...