This dark material: the black alchemy that can arrest carbon emissions

Not only does biochar trap carbon when it is created, it is heating homes in Sweden and feeding cows in Lincolnshire

Biochar is a form of charcoal produced when organic matter is heated at high temperatures with little or no oxygen. Photograph: Alamy

It traps carbon in the ground for centuries, boosts plant growth, provides a sustainable heat source and could even reduce methane emissions from cows. Biochar may not be a silver bullet to combating the climate emergency, but it certainly ticks a lot of boxes.

A form of charcoal created via a special chemical process, biochar is not much to look at, resembling the aftermath of a particularly good barbecue. But it is already heating homes in Stockholm, feeding cows in Lincolnshire, and nourishing trees near Loch Ness.

“When you look at the range of benefits it has, it is quite phenomenal,” says Marc Redmile-Gordon, senior scientist for soil and climate change at the Royal Horticultural Society (RHS). While stressing that biochar is only part of the solution, he adds: “If we stop burning fossil fuels tomorrow, we’ll still have a lot of carbon dioxide removal to be doing, and this is one of the most effective ways we can achieve that.”

Following biochar’s recognition in the IPCC 2018 report, earlier this year Redmile-Gordon launched the society’s first trials to see how the material could improve plant growth. He estimates planting 10-20kg of biochar in your garden could offset the carbon from a five-mile return commute in a car for a month.

Biochar is a form of charcoal produced when organic matter – for example wood, leaves or dead plants – is heated at high temperatures with little or no oxygen in a process called pyrolysis. The normal burning or decomposition of these materials would release large amounts of methane and carbon dioxide into the atmosphere. Instead, creating biochar traps this carbon in solid form for centuries; it becomes a carbon sink that can be buried underground.

This is nothing new – in Stockholm they have already developed technology to trap the heat generated in the process and put it to use, so now the focus is on what benefits biochar can bring once it is in the ground. Although results vary depending on the type of biochar and soil used, Redmile-Gordon says this stuff can “alleviate some of the stresses that come from climate change”.

Biochar is full of xylem vessels and capillaries – channels that “can carry nutrients, air, water and house the biology that make for a healthy soil ecosystem”, he says. This means that in waterlogged clay soil it can reduce and redistribute water content, whereas in sandy soil affected by drought it can increase water-hold potential.

While scientific research has established the benefits of biochar in theory, deploying it in a way that makes a real difference is a challenge. One of its most obvious uses is in tree planting, which is poised to become a major activity in the UK over the coming years. The Conservatives have pledged to plant 30m trees a year, the Liberal Democrats have promised 60m a year, while Labour’s manifesto pledges an ambitious tree-planting programme.

“They bandy around these big numbers, but will they actually talk about the survival rates?” asks James MacPhail, commercial director of Carbon Gold, which sells biochar products for use in soil everywhere, from people’s back gardens to Ascot racecourse.

Up to 80% of trees planted along the HS2 rail route died after last summer’s drought. For MacPhail, this suggests not enough is being done to ensure tree growth: “If you plant 1m trees, great, but if 800,000 die, was it really worth it? If you can just do one thing to guarantee the survival of a tree going in the ground then maybe trees can save the planet.”

Research suggests biochar could be just the thing. Dr Saran Sohi leads the UK Biochar Research Centre in Edinburgh which is injecting biochar made from forestry residue such as bark around tree roots as part of a tree-planting project near Loch Ness. “It really does seem to offer some quite marked benefits in terms of tree health, early stage growth and nutrient management,” says Sohi. “Turning this particular part of the tree into biochar allows the nutrients to be returned to the forest sites in the process of replanting.”

Other projects are making strides in integrating biochar into farming, too. Richard Copley is part of the Innovative Farmers network, and received funding to trial feeding biochar to some of his cows this year. As both a farmer and a tree surgeon, Copley was keen to use the waste from his tree felling in a useful way, and he noticed the positive effects of biochar on his animals immediately.

Biochar is alkaline, so it balances the highly acidic diet of cows. Evidence suggests it is beneficial for microbial activity – like putting a probiotic into your stomach, according to Copley. Trials elsewhere have suggested biochar could reduce methane emissions, something Copley hopes can be explored later, as well as trialling the material on other animals such as chicken and sheep.

Meanwhile, Donna Udall, a researcher from Coventry University, is exploring whether manure from the biochar-fed cows is more effective as a fertiliser than biochar by itself. In some instances biochar can reduce crop yield by absorbing the nutrients needed by the plants – biochar as part of manure could be the solution.

While academics and researchers are optimistic about the benefits of biochar, they are not blind to the risks either. “If we’re wrong, and we spread hundreds of thousands of tonnes of charcoal over the UK, we can’t get it back out of the ground. We’ve got to be right. The stakes are really high,” says Udall.

Sohi adds: “This makes the government a bit anxious, which is why I think starting slowly and getting comfortable with the technology first is probably a good idea.”

Not only that, but there are also practical problems with trying to acquire the vast amounts of biochar needed to make a real impact. Udall says: “In order to scale up the technology, you’d have to plant woods everywhere, and obviously you can understand the impact that would have on the land that we need to grow crops.”

Only when farmers, food producers and other industries start putting their biomass waste through a pyrolysis process as standard would there be enough biochar to roll it out on a wide scale, says Udall. But eventually biochar could be made from green waste in urban areas – everything right down to the banana skin lying on your desk, she adds.

The key is working out how the source material affects the resulting biochar after pyrolysis, something which still needs substantial investigation. But with some estimates suggesting biochar could offset 1bn tonnes of carbon a year, it’s easy to see why people are getting excited about it. SOURCE

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From dumpster to diesel: How a pilot project in Whitby is turning plastic waste into fuel

Backers claim project can convert 5 tonnes of waste into 4,000 litres of fuel per day


A pilot project in Whitby, Ont., turns non-recyclable plastics into usable fuel, rather than having the waste sit in a landfill. (Talia Ricci/CBC)

A pilot project in Whitby, Ont., is using technology to give plastic waste a second life by turning it into diesel fuel and gasoline.

The technology, dubbed the Phoenix, can convert single-use items like plastic bags and Styrofoam — items that would otherwise end up in landfill.

John O’Bireck, president of energy investment company Sparta Group, says he sees plastic “as a resource, not a scourge.”

He says the fuel produced by Phoenix is already being used in his company’s fleet of trucks that transport industrial waste.

“Five tonnes of plastic can be converted into about 4,000 litres. And 4,000 litres can drive our whole fleet of 10 vehicles back and forth every day running 16 hours a day.”

O’Bireck says Phoenix uses a process involving pyrolysis — using heat to bring about decomposition — to upcycle plastics that can’t go into the recycling stream.

John O’Bireck, of Sparta Group, says fuel produced by Phoenix is already being used in his company’s fleet of trucks that transport industrial waste. (Talia Ricci/CBC)

“If you take plastic as it stands, it’s going to go in the ground and it’s going to sit there for a thousand years. By adding this technology, we are converting it so that we give it one more chance to go back out.”

The process shreds the plastic into smaller pieces and feeds it into a “cooker.” O’Bireck claims it’s not being burned; the material is in an airtight vessel and being heated in the absence of oxygen.

“There’s actually two gases formed: condensable and non-condensable gas. We’re distilling it down to take it from its gas to a liquid.”

O’Bireck says the goal is to expand to municipalities and bigger companies. MORE