Anaerobic digestion

Anaerobic digestion is a natural process where tiny living things called microorganisms break down biodegradable material without using oxygen. This process helps manage waste and make fuels. People use it in factories and at home.

During anaerobic digestion, the material changes into a gas called biogas, which is rich in methane. This biogas can be used to make renewable energy. What is left after the process, called digestate, can be treated and sometimes reused in helpful ways.

Anaerobic digester system in Germany

Anaerobic digestion happens naturally in places like soil, lakes, and oceanic basin sediments. It is how marsh gas methane was first discovered by Alessandro Volta in 1776. The process has four main stages: hydrolysis, acidogenesis, acetogenesis, and methanogenesis.

This process is important because it helps reduce waste and creates energy. It is used to treat sewage sludge and can use special plants like maize to make more energy. The biogas produced can be used as fuel or turned into a clean gas called biomethane. The digestate made during this process is rich in nutrients and can be used as fertilizer.

Process

Main article: Anaerobic respiration

Anaerobic Digestion Process Flow: All process flows are dependent on the balance of between proteins, carbs and fats.

Many tiny living things called microorganisms help break down natural materials without needing oxygen. They change these materials into useful gases by using other things instead of oxygen.

These tiny helpers can turn things like food waste into a gas called biogas, which can be used for energy. The process happens in special containers where no oxygen can get in. The microorganisms work together in steps to change the materials into gases like methane and carbon dioxide.

It often takes time for these microorganisms to grow strong enough to work well, so people add materials that already have these helpful tiny creatures to start the process faster.

Feedstocks

Anaerobic lagoon and generators at the Cal Poly Dairy, United States

Almost any organic material can be used in anaerobic digestion. Some materials work better than others. The easier a material is to break down, the more gas it can make. Common materials used include food scraps, grass clippings, paper, and animal waste. However, woody materials like wood chips don't break down well because of a tough substance called lignin.

Anaerobic digesters can also use crops grown just for this purpose, like corn or grass, to make extra energy. These special plants are often used in places called biogas plants. Mixing different materials together, like manure and food waste, can help make even more gas. The time it takes for the material to break down depends on how complex it is—simple sugars break down quickly, while tougher materials take longer.

Applications

Using anaerobic digestion can help reduce greenhouse gas emissions in several important ways. It can replace fossil fuels, use less energy to treat waste, and prevent methane from landfills. This process also offers an alternative to chemical fertilizers and reduces the need for travel and electricity.

Schematic of an anaerobic digester as part of a sanitation system. It produces a digested slurry (digestate) that can be used as a fertilizer, and biogas that can be used for energy.

Anaerobic digestion is useful for treating organic waste from factories, wastewater, and sewage. It helps lower the amount of waste that ends up in landfills or is burned. In many developed countries, rules about waste disposal have encouraged more use of this process to cut waste and create helpful byproducts. This method can also clean up sludge polluted with certain chemicals, helping remove some harmful substances.

In places with less industry, small anaerobic digestion systems can provide affordable energy for cooking and lighting. Countries like China and India have supported such projects for years. The gas from this process can replace fossil fuel energy, which helps lower greenhouse gas emissions. Large operations work well for making power, while smaller farms can also gain benefits. Some places even use the gas to make electricity or heat buildings. The leftover material can act as a natural fertilizer for crops, improving soil health without chemical fertilizers. Small-scale systems can even make gas for cooking from kitchen and other organic waste.

Products

The three main results of anaerobic digestion are biogas, digestate, and water.

Biogas

Biogas holder with lightning protection rods and backup gas flare

Main article: Biogas

Biogas is made mostly of methane and carbon dioxide. It also has a little bit of hydrogen, water vapor, and a tiny amount of hydrogen sulfide. This gas is kept in a special bubble above the digester or in a container nearby. The methane in biogas can be burned to make heat and electricity. This electricity can warm the digesters or heat buildings. Any extra electricity can be sold or added to the local electricity grid. Biogas is a clean energy source because the carbon dioxide it produces comes from plants and animals.

Digestate

Biogas carrying pipes

Main article: digestate

Digestate is what’s left after microbes break down materials. It includes bits of the original material that the microbes couldn’t use and the remains of the microbes. There are two types of digestate: a solid, fibrous material that can be used like compost or to make building products, and a liquid rich in plant nutrients that can be used as fertilizer. Sometimes, this liquid needs extra treatment to make sure it’s safe for plants.

Wastewater

The water that comes out of anaerobic digestion systems often has high levels of certain chemicals. These chemicals can harm water plants and animals if released directly into rivers or lakes. Because of this, the water usually needs extra cleaning before it can be safely released. This cleaning might involve letting air mix with the water or using special filters to remove harmful substances.

**Typical composition of biogas**
Compound	Formula	%
Methane	CH ₄	50–75
Carbon dioxide	CO ₂	25–50
Nitrogen	N ₂	0–10
Hydrogen	H ₂	0–1
Hydrogen sulfide	H ₂S	0–3
Oxygen	O ₂	0–0
Source: www.kolumbus.fi, 2007

History

People have been interested in the gases made when organic matter breaks down naturally since the 1600s. Early scientists noticed that moving mud from lakes and streams could release flammable gas. Later, they learned that this gas was methane.

The first tanks built to trap these gases were made in the 1800s. By the early 1900s, designs started to look like the systems we use today. Interest in these gas-making systems grew during times when there was less oil available. Today, many farms and wastewater treatment places use these systems to turn waste into useful energy.

Main article: Imhoff tank