Embrace what may be the most important green technology ever. It could save us all

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Eleanor Shakespeare/The Guardian

Thu 24 Nov 2022 14.41 GMTLast modified on Thu 24 Nov 2022 19.23 GMT

So what do we do now? After 27 summits and no effective action, it seems that the real purpose was to keep us talking. If governments were serious about preventing climate breakdown, there would have been no Cops 2-27. The major issues would have been resolved at Cop1, as the ozone depletion crisis was at a single summit in Montreal.

Nothing can now be achieved without mass protest, whose aim, like that of protest movements before us, is to reach the critical mass that triggers a social tipping point. But, as every protester knows, this is only part of the challenge. We also need to translate our demands into action, which requires political, economic, cultural and technological change. All are necessary, none are sufficient. Only together can they amount to the change we need to see.

Let’s focus for a moment on technology. Specifically, what might be the most important environmental technology ever developed: precision fermentation.

Precision fermentation is a refined form of brewing, a means of multiplying microbes to create specific products. It has been used for many years to produce drugs and food additives. But now, in several labs and a few factories, scientists are developing what could be a new generation of staple foods.

Replace animal farms with micro-organism tanks, say campaigners

 

The developments I find most interesting use no agricultural feedstocks. The microbes they breed feed on hydrogen or methanol – which can be made with renewable electricity – combined with water, carbon dioxide and a very small amount of fertiliser. They produce a flour that contains roughly 60% protein, a much higher concentration than any major crop can achieve (soy beans contain 37%, chick peas, 20%). When they are bred to produce specific proteins and fats, they can create much better replacements than plant products for meat, fish, milk and eggs. And they have the potential to do two astonishing things.

The first is to shrink to a remarkable degree the footprint of food production. One paper estimates that precision fermentation using methanol needs 1,700 times less land than the most efficient agricultural means of producing protein: soy grown in the US. This suggests it might use, respectively, 138,000 and 157,000 times less land than the least efficient means: beef and lamb production. Depending on the electricity source and recycling rates, it can also enable radical reductions in water use and greenhouse gas emissions. Because the process is contained, it avoids the spillover of waste and chemicals into the wider world caused by farming.

‘One paper estimates that precision fermentation using methanol needs 1,700 times less land than the most efficient agricultural means of producing protein: soy grown in the US.’ Photograph: Creative Touch Imaging Ltd/NurPhoto/REX/Shutterstock

If livestock production is replaced by this technology, it creates what could be the last major opportunity to prevent Earth systems collapse, namely ecological restoration on a massive scale. By rewilding the vast tracts now occupied by livestock (by far the greatest of all human land uses) or by the crops used to feed them – as well as the seas being trawled or gill-netted to destruction – and restoring forests, wetlands, savannahs, natural grasslands, mangroves, reefs and sea floors, we could both stop the sixth great extinction and draw down much of the carbon we have released into the atmosphere.

The second astonishing possibility is breaking the extreme dependency of many nations on food shipped from distant places. Nations in the Middle East, north Africa, the Horn of Africa and Central America do not possess sufficient fertile land or water to grow enough food of their own. In other places, especially parts of sub-Saharan Africa, a combination of soil degradation, population growth and dietary change cancels out any gains in yield. But all the nations most vulnerable to food insecurity are rich in something else: sunlight. This is the feedstock required to sustain food production based on hydrogen and methanol.

Precision fermentation is at the top of its price curve, and has great potential for steep reductions. Farming multicellular organisms (plants and animals) is at the bottom of its price curve: it has pushed these creatures to their limits, and sometimes beyond. If production is distributed (which I believe is essential), every town could have an autonomous microbial brewery, making cheap protein-rich foods tailored to local markets. This technology could, in many nations, deliver food security more effectively than farming can.

There are four main objections. The first is “Yuck, bacteria!” Well, tough, you eat them with every meal. In fact, we deliberately introduce live ones into some of our foods, such as cheese and yoghurt. And take a look at the intensive animal factories that produce most of the meat and eggs we eat and the slaughterhouses that serve them, both of which the new technology could make redundant.

The second objection is that these flours could be used to make ultra-processed foods. Yes, like wheat flour, they could. But they can also be used to radically reduce the processing involved in making substitutes for animal products, especially if the microbes are gene-edited to produce specific proteins.

This brings us to the third objection. There are major problems with certain genetically modified crops such as Roundup Ready maize, whose main purpose was to enlarge the market for a proprietary herbicide, and the dominance of the company that produced it. But GM microbes have been used uncontroversially in precision fermentation since the 1970s to produce insulin, the rennet substitute chymosin and vitamins. There is a real and terrifying genetic contamination crisis in the food industry, but it arises from business as usual: the spread of antibiotic resistance genes from livestock slurry tanks, into the soil and thence into the food chain and the living world. GM microbes paradoxically offer our best hope of stopping genetic contamination.

The fourth objection has more weight: the potential for these new technologies to be captured by a few corporations. The risk is real and we should engage with it now, demanding a new food economy that’s radically different from the existing one, in which extreme consolidation has already taken place. But this is not an argument against the technology itself, any more than the dangerous concentration in the global grain trade (90% of it in the hands of four corporations) is an argument against trading grain, without which billions would starve.

The real sticking point, I believe, is neophobia. I know people who won’t own a microwave oven, as they believe it will damage their health (it doesn’t), but who do own a woodburning stove, which does. We defend the old and revile the new. Much of the time, it should be the other way around.

I’ve given my support to a new campaign, called Reboot Food, to make the case for the new technologies that could help pull us out of our disastrous spiral. We hope to ferment a revolution.

  • George Monbiot is a Guardian columnist

 

Yesterday I cam across an article referring to a publication in Nature Communications in which an Australian research group published a new method for direct transformation of CO2 into carbon.

The technology is still in a research phase, but if workable on bigger scale it has high promises for a sustainable future. Solving two issues in one go: reduction of CO2 in the atmosphere and reduction of the chopping of wood for transformation into various kinds of carbon. I can imagine a wide range of applications ranging from drawing charcoal to active carbon, from BBQ charcoal to building block for carbon rich fuel.

If you feel the same and have interest in further exploring business opportunities for this process, please leave your reaction hereunder, or contact me directly.

This is the article:

Liquid metal catalyst solidifies CO2 for safe storage

27th February 2019 9:24 am

In what is claimed to be a world first, researchers have used a liquid metal catalyst to turn CO2 back into solid coal, an advance with implications for carbon capture and storage.

Schematic showing how liquid metal is used as a catalyst for converting carbon dioxide into solid coal (Pic: RMIT University)

Published in Nature Communications, the research led by RMIT University in Melbourne, Australia is claimed to offer an alternative direction for safely and permanently removing the greenhouse gas from the atmosphere.

Technologies for carbon capture and storage (CCS) involve compressing CO2 into a liquid form, transporting it to a suitable site and injecting it underground but implementation has been hampered by engineering challenges, economic viability and environmental concerns about possible leaks from the storage sites.

RMIT researcher Dr Torben Daeneke said converting CO2 into a solid could be a more sustainable approach.

“While we can’t literally turn back time, turning carbon dioxide back into coal and burying it back in the ground is a bit like rewinding the emissions clock,” said Daeneke, an Australian Research Council DECRA Fellow.

“To date, CO2 has only been converted into a solid at extremely high temperatures, making it industrially unviable.

“By using liquid metals as a catalyst, we’ve shown it’s possible to turn the gas back into carbon at room temperature, in a process that’s efficient and scalable.

“While more research needs to be done, it’s a crucial first step to delivering solid storage of carbon.”

Lead author, Dr Dorna Esrafilzadeh, a Vice-Chancellor’s Research Fellow in RMIT’s School of Engineering, developed the electrochemical technique to capture and convert atmospheric CO2 to storable solid carbon.

To convert CO2, the researchers designed a liquid metal catalyst with specific surface properties that made it extremely efficient at conducting electricity while chemically activating the surface.

According to RMIT, the carbon dioxide is dissolved in a beaker filled with an electrolyte liquid and a small amount of the liquid metal, which is then charged with an electrical current.

The CO2 slowly converts into solid flakes of carbon, which are naturally detached from the liquid metal surface, allowing the continuous production of carbonaceous solid.

“A side benefit of the process is that the carbon can hold electrical charge, becoming a supercapacitor, so it could potentially be used as a component in future vehicles,” Esrafilzadeh said. “The process also produces synthetic fuel as a by-product, which could also have industrial applications.”

The research was conducted at RMIT’s MicroNano Research Facility and the RMIT Microscopy and Microanalysis Facility. The collaboration involved researchers from Germany (University of Munster), China (Nanjing University of Aeronautics and Astronautics), the US (North Carolina State University) and Australia (UNSW, University of Wollongong, Monash University, QUT).