Biogeochemical cycles are important natural processes for our planet, and without them, life on Earth would not be possible. For resources like oxygen, water, nitrogen, phosphorus, and other nutrients to be available and usable by living beings, transformation processes are required. On Earth, different natural cyclical systems develop where nothing is wasted, following the law of conservation of matter and energy. Energy is neither created nor destroyed, only transformed. Therefore, all energy, through physical-chemical and microbiological processes, is transformed into elements indispensable for life. Let's analyze a tree: its leaves, when they fall naturally, reach the ground and, through microbiological processes, decompose into nutrients that enrich the soil, allowing the tree's roots to use them for growth. This allows for the production of foliage and the generation of fruit. There, resources are naturally recirculated in such a way that nothing is wasted. One of the most important cycles is the water cycle. Water covers 70% of the Earth's surface. As a fundamental element for life, it goes through several states of transformation. Throughout its passage through the biosphere and atmosphere , its gaseous presence in the atmosphere allows for the formation of clouds. It precipitates into the biosphere as rain, hail, or fog, enabling the formation of seas, rivers, lakes, and aquifers, among others. Upon reaching the ground, it is captured by different sources of life, either through direct ingestion or absorption processes through roots. Water integrates into the cycle through evaporation processes caused by the sun or evapotranspiration through plants, reintegrating into the atmosphere to continue the cycle. Humans play an important role in two aspects: first, they capture water for their survival, but additionally, they take the water they will use in production processes and the transformation of raw materials. Second, it refers to its availability and quality, considering that it is limited and in constant circulation. Therefore, it is essential that the use of this resource be rational and efficient, and that after being used for different purposes, it can be treated, managed, and recirculated in production systems, guaranteeing its availability and reducing pollution from discharges, which in turn... This will result in benefits associated with reduced operating expenses, and another essential cycle for life is the carbon cycle, on which all living beings on the planet depend. This cycle is essential for the generation of oxygen, and thanks to it, plant growth is possible, guaranteeing the availability of food. There are two forms of carbon: in its inorganic form, present in non-living matter such as rocks and in the Earth's mantle, and in its organic form, present in all living beings. We are composed of molecules that contain carbon. This element is available in a gaseous state in the soil, water, and air as carbon dioxide (CO2). Through photosynthesis, plants and other photosynthetic microorganisms absorb and transform the CO2 present in the atmosphere, fixing carbon as food and releasing oxygen (O2) into the atmosphere. Subsequently, the carbon is reintegrated into the environment through natural processes of respiration or decomposition of living beings and organic matter to begin the cycle again. The second way of releasing CO2 into the atmosphere is through processes such as the burning of fossil fuels, forest fires, intensive grazing, industrial, transportation, and domestic activities. Among other things, however, if the capacity that plants can assimilate is reduced, or if the absorption capacity of the system is decreased as a result of deforestation, an excess of CO2 is generated in the atmosphere, producing alterations in the climate. In common, all natural cycles represent the circularity of the flows of matter and energy where these are incorporated again and again into the system without generating waste. This principle is what the circular economy seeks to implement. Yes