The three million diesel-engined buses circulating in the world, account for nearly half of all nitrogen oxides (NOx) and more than two-thirds of all particulate matter (PM) emissions from US transportation sources.
In 2018, there were about 425,000 electric buses in service in the world’s cities. Almost all—99 % of them—were in China. Arguably the first commercial li-ion electric bus was developed by Mr Lu Guanqiu at the Wanxiang Electric Vehicle Company (WXEV).
The company traces its origins to the creation of a repair shop for agricultural machinery in 1969 in the people’s commune Ningwei. In 1979, a factory for agricultural machinery was created.
Then in 2000, WXEV bought a li-ion battery company and three years later they were running a prototype li-ion bus on Route Y9 around West Lake, Hangzhou City.
By 2009, a fleet of these had clocked up 350,000 mi. (560,000 km) on this route and WXEV had delivered buses to major cities in China, including Shanghai, Hangzhou, Guangzhou, Zhengzhou, Nanchang, etc.
They also supplied 100% electric buses to the 16th Asian Games, held in Guangzhou in 2010 while at the Shanghai Expo 2010, Wanxiang deployed 160 buses, each with 65 seats and 300 batteries, on two 8.6 mi (14km) long lines, each capable of a range of 50 mi. (80km). The additional batteries were charged in a hall and changed by robots in 6 minutes.
There will be 1.5 million electric buses in use worldwide by 2030, according to the International Energy Agency Europe.
Every five weeks, 9,500 brand new electric buses take to the roads in China: that is the equivalent of the entire London bus fleet. A number of cities in the Europe’s Nordic region such as Oslo, Trondheim and Gothenburg also have electric buses in operation. Only 1.6% of all city buses in Europe are electric. In the US, it is only about 0.5%.
Alongside the biggest manufacturer, BYD (75,000 units), other electric bus manufactures include
The vast majority of large buildings in the world are still made with energy intensive, inorganic single-use concrete and steel.
Buildings incorporating algae and other nature-sourced materials.
In 2012, one of the world’s largest engineering/development/construction companies, Arup, teamed up with Splitterwerk Architects of Graz, Austria, Colt, and Strategic Science Consult to design and build a five-storey 15-apartment residential building in Hamburg, covered by panels filled with algae, a fast-growing form of biomass.
The panels are on the two south-facing sides to help provide internal shading, and the micro-algae growing in the glass louvers provide a clean source of renewable energy.
Called Solar Leaf, the building pumps water, nutrients, and compressed CO₂ between 129 “bioreactors.” These bioreactors have four glass layers. The two inner panes have a 6 gall (24-li) capacity cavity for circulating the growing medium.
Either side of these panes, insulating argon-filled cavities help to minimise heat loss. The front glass panel consists of white anti-reflective glass, while the glass on the back can integrate decorative glass treatments.
Compressed air is introduced to the bottom of each bioreactor at intervals. The gas emerges as large air bubbles and generates an upstream water flow and turbulence to stimulate the algae to take in CO₂ and light. At the same time, a mixture of water, air and small plastic scrubbers washes the inner surfaces of the panels.
SolarLeaf integrates all servicing pipes for the inflow and outflow of the culture medium and the air into the frames of its elements.
When the sun shines, the algae multiply as a result of photosynthesis. The system collects the residue, then converts it to biogas, which is burned in a boiler. Together with a heat recovery system and solar panels on the roof, the building is completely energy independent.
The system can be operated all year round. The efficiency of the conversion of light to biomass is currently 10% and light to heat is 38%. For comparison, PV systems have an efficiency of 12-15% and solar thermal systems 60-65%.
The flat photo-bioreactors are highly efficient for algal growth and need minimal maintenance. The building, also called BIK, completed in 2013, was part of Hamburg’s International Building Exhibition. (arup.com)
In 2015, Guglielmo Carra of Arup Berlin working with Kasper Jørgensen of GXN Innovation in Copenhagen, developed BioBuild, the first self-supporting façade panel made out of bio-composite materials.
Developed as part of the €7.7 million EU-funded BioBuild program, the design reduces the embodied energy of facade systems by 50% compared to traditional systems with no extra cost in construction.
The 13 ft x 7.5 ft (4m x 2.3 m) panel is made from natural flax fabric and bio-derived resin from agricultural processing of corn, sugar cane and other crops.
Intended primarily for commercial offices, the glazing unit features a parametrically-derived faceted design, and comes prefabricated ready for installation. The panel is also designed to be easy to disassemble, making it simple to recycle at the end of its life.
The panel won the JEC Award 2015 for the best composites innovation in the construction field. (gxn.3xn.com)
In 2017, Arup published a report entitled “The Urban Bio-Loop: Growing, Making and Regenerating” in which it demonstrates that a different paradigm for materials in construction is possible. The report highlights the following organic matter products already available: peanut, rice, banana and potato.
What you can do: Tell local architects and builders about the Arup Bio-Loop
Plastic waste in the ocean is breaking down into irretrievable microplastic.
A ship to study how this is happening, picking up the waste and taking it back to port.
In 1979 Mary T. Crowley founded Ocean Voyages, an international yacht chartering business that offers a full range of services, including educational sailing program., sailing vessels, expedition ships, motor yachts and scuba and snorkeling program all over the world.
She also started the Ocean Voyages Institute at the same time, a nonprofit organization with a mission of preserving the maritime arts and sciences, the ocean environment and island culture.
In 2008, Crowley founded Project Kaisei, bringing together a team of innovators, scientists, environmentalists, ocean lovers, sailors, and sports enthusiasts with a common purpose: to study the North Pacific Gyre and the marine debris that has collected in this oceanic region, to determine how to capture the debris and to study the possible retrieval and processing techniques that could potentially be employed to detoxify and recycle these materials into diesel fuel.
Their first research expedition in the summer of 2009, on board a 140ft (43m) sailing brigantine S/V Kaisei, was critical to understanding the logistics that would be needed to launch future clean-up operations and testing existing technologies that had never been utilized under oceanic conditions.
From 2011, sometimes twice a year, Mary Crowley and volunteers from the Ocean Voyages Institute have voyaged out on S/V Kaisei from Hawaii to clean up trash floating in the ocean.
During June 2019, the brigantine’s crane pulled out 40 tons (36 metric tons) of abandoned fishing nets as part of an effort to rid the waters of the nets that entangle whales, turtles and fish and damage coral reefs.
The cargo ship returned to Honolulu, where 2 tons (1.8 tonnes) of plastic trash were separated from the haul of fishing nets and donated to local artists to transform into artwork to educate people about ocean plastic pollution.
The rest of the refuse was turned over to a zero emissions energy plant to incinerate it and turn it into energy,
What you can do: Pick up plastic waste near you, keep our Planet Tidy!
Bottles thrown away can end up in landfills or in Nature.
In 2017, DB Breweries in New Zealand built a machine which pulverizes glass bottles then turns them into fine-grain substitute building sand in just 5 seconds.
Two thirds of the world’s beaches are retreating as people across the world use non-renewable beach sand for construction, roading and other uses. There were even some beaches in New Zealand where they were taking the sand off one beach and putting it on another beach, which seemed crazy to DB.
All a drinker needs to do is deposit his or her bottle in the machine, a laser triggers a wheel of small steel hammers spinning at 2,800 rpm to crush it into 7 oz. (200 gm.) of sand in only five seconds. After extracting the plastic labels and silica with two vacuum systems, the sand is then processed through a screener which sorts it into a fine grades between 1.1 – 0.4mm particle sizes.
In several months, a fleet of these machines recycled 100 tons of sand, which is the equivalent of 500,000 DB Export Bottles. Until recently about 11,000 ton (10,000 tonnes)of glass at Visy Recycling in Auckland could not be recycled, so, rather than have it diverted to landfill, it now goes into the industrial beer bottle sand machine.
The resulting sand substitute was then given to their construction and retail partners to use in place of beach sand. Finding partners for the program was a critical step in achieving scale for the project.
The brewer has finalized a two-year deal to supply Solution 54 in a 1-a-day series of 366 creative, hopeful ideas to clean up, repair, protect our planet: the company now delivers DB Export Beer Bottle Sand to #DryMix to make a super easy eco concrete Solution 54 in a 1-a-day series of 366 creative, hopeful ideas to clean up, repair, protect our planet: the company now delivers DB Export Beer Bottle Sand to #DryMix to make a super easy eco concrete , leading to a new brand of eco-concrete, sold to consumers through the country’s biggest home improvement chain.
Beer Bottle sand is now used by Downer in road-making projects, commercial and residential construction, and even golf bunkers and resurfacing projects, and Drymix, which has created a ‘‘super easy eco concrete’’, available through Mitre10.
In 2018, DB Export’s beer bottle sand was combined with recycled ink toner cartridges to make an aggregate for resurfacing the 430,000 ft² (40,000m²) Queenstown Airport apron, the first project of its kind. Requests for machines arrived from as far away as Dubai, with scoping to supply 500 machines currently underway. DB’s trucks carry the slogan “Drink DB Export. Save Our Beaches.” (db.co.nz)
From May 1999, Norsk Resirk launched a deposit return scheme for plastic bottles and aluminum beverage cans which has led to 97% of all plastic drinks bottles in Norway being recycled, 92% to such a high standard that they are turned back into drinks bottles.
Norway’s model is based on a loan scheme, which means when a consumer buys a plastic bottle, they are charged a small additional fee equivalent to about 13 to 30 US cents.
The scheme is open to all consumers who can either take a bottle or can to a reverse vending machine which returns the money after scanning the verifiable barcode of the deposited bottle, or they can return it to various small shops and gas stations for cash or store credit.
These shop owners also receive a small fee for each bottle they recycle, and some argue it has even increased their business.
Three processing plants were opened to receive the bottles, one in Fetsund outside Oslo to handle approximately 80% of what is collected in Norway.
First step in the process is sorting out the aluminum and steel cans. Next step is sorting out clear and light blue bottles. Then follow the colored bottles. Some of the material has been recycled more than 50 times.
The company is now called Infinitum. All the materials are then structured into ballots and sent further for recycling: metals go to the company Norsk Hydro in Holmestrand, Norway; PET bottles are sent to Cleanaway AB in Sweden.
Nevertheless, even in Norway, there is still room for improvement. During the year, Infinitum estimates that 150,000 bottles will not be returned, and if they had, it would have saved enough energy to power 5,600 households for the year.
The same system is now being used in neighbouring Sweden, Denmark, and Germany and a number of US and Canadian states.
There are ten states in the United States with container deposit legislation, popularly called “bottle bills” after the Oregon Bottle Bill (established since 1971), the first such legislation that was passed. Container deposit legislation (CDL) also known as a Container Deposit Scheme (CDS) was first implemented in South Australia in 1977 and has since been extended all over that continent.
The manufacturing of a board game is not environmentally friendly and it may only concentrate on abstract concepts such as “Sorry” or “Snakes and Ladders”.
Board games that involve players in cleaning, repairing and protecting our Planet.
In 1996, following the success of his first board game Bioviva, Jean-Thierry Winstel of Montpellier, France decided to create a range of question-and-answer-themed educational games for family and children that would raise awareness of respect for nature in an eco-design approach.
They must be exclusively made in France, so reducing CO₂ emissions related to their shipment and linked to an eco-design approach i.e. paper, cardboard and FSC-labelled wood and plant-based inks, respectful of people and the environment.
This approach, unique in the publishing sector, allowed Bioviva to constantly improve its production methods and to reduce its ecological footprint ever more. The games are offered at attractive prices, in order to make them accessible to the greatest number.
One popular product is a board game called “Nature Challenges” where children Tomorrow’s the incredible diversity of animals and try to protect them on 5 continents. Added to their board and card games, Bioviva launched “Nature Challenges” books.
Bioviva has produced more than 2.5 million copies of “Nature Challenges”, translated into various languages and sold in 13 countries.
In February 2018, on the occasion of the 10th anniversary of the Nature Challenges card game Bioviva announced the launch of the Défis Nature club, a 12-page promotional magazine including gifts (cards, posters) and contests.
Alongside Bioviva, other games encourage players to focus on our Planet. “Earthopoly” is inspired by the “Monopoly” board which since 1935 has been translated into 47 languages, played in 114 countries and has sold more than 275 million copies.
To play Earthopoly, a player chooses their token (an object from nature) and starts at “Go Green.” Players increase their property value by collecting Carbon Credits and trading them in for Clean Air. But try to avoid getting sent to the Dump!
Like Bioviva’s “Nature Challenges”, not only is Earthopoly a game about the earth it is entirely eco-friendly itself as the game pieces are either made by nature or completely recyclable, the ink is vegetable oil-based, with the game box made from 100 % recycled Chip board.
All the paper is recyclable and is made with 10 % recycled pulp that comes from a mill that purchases pulp that is monitored by a responsible third party forest management group. Green Power was purchased for the electricity used to manufacture the paper for the box (renewable energy in the form of wind, hydro, and biogas).
While TDC Games produces “The Green Game” for 2 to 6 players, with its coasters growing actual wildflowers, Global Horizons Ltd. produces “Envirochallenge – The Ultimate Challenge for the last Endangered Species MAN.”
“Ethica”, based on the principles behind the collaborative ethical investment group Reseau Financement Alternatif, lets up to 27 players assume the role of an investment banker or venture capitalist and see how well their green intentions stand up in the world of international finance.
“Wildlife Web”, inspired by Pokémon card games, created by Montana-based author and educator Thomas J. Elpel, is a dynamic ecology strategy game that engages players to experience what life is such as for a red-tailed hawk or yellow-bellied marmot foraging for food, raising young and defending against predators. It gets players’ animals to cooperate or compete with one another.
What you can do: Acquire and play Planet-oriented board games at home.
Using and adapting a camera system designed to monitor pedestrians and cars, the team is planning to mount the AI bird watcher on top of a solar panel. In this way they plan to gather data to help help ornithologists unravel the mystery of why our feathered friends are dying in droves at solar farms.
Solution 50 in a 1-a-day series of 366 creative, hopeful ideas to clean up, repair, protect our planet:
Billions of birds are killed annually following collision with the large panes of glass used in modern buildings.
Bird protection glass with an ultraviolet-reflective coating. Birds can see the coating, but it is virtually invisible to humans.
In the late 1990s Dr. Alfred Meyerhuber, a German attorney with a personal interest in birds and science read an article in a magazine about orb weaver spiders and their use of stabilimenta. Orb weaver spiders, common worldwide, build their distinctive webs using strands of silk with UV reflective properties.
Meyerhuber was good friends with Hans-Joachim Arnold, the owner of Arnold Glas, a manufacturer of insulated glass products headquartered in Remshalden, Germany. As a young business owner, Arnold was motivated by technical and environmental challenges and looked for ways to set Arnold Glas apart from its competition.
When Meyerhuber brought the orb weaver spider’s strategy to his attention, Arnold was intrigued. Despite initial resistance by the board of directors, he convinced the company to undertake the necessary research and put his company to work developing a product that would have the same UV-reflecting qualities as spider silk.
Arnold Glas’s Head of Research and Development, Christian Irmscher, led the technical product development of ORNiLUX. The coating was developed together with technicians at Arnold Glas’s sister company, Arcon, located in Feuchtwangen, Germany, which specializes in thin low-e and solar coatings for architectural glass.
The companies tested many different coating types and patterns. The researchers found that a patterned coating (versus a solid coating) made the contrast of the glazing more intense: the coated parts reflected UV light while the interlayer sandwiched between two layers of glass absorbed the UV light. The two functions together enhanced the reflective effect.
Although the specific pattern of a spider’s web inspired the solution, Irmscher and his team had to design a unique pattern for the window coating in order to make the application process practical.
After patenting the transparent UV coating in 2001, Arnold Glas introduced ORNiLUX SB1 Bird Protection Glass, its first commercial product using the technology, in 2006. The vertical lines of UV-reflective coating used in this product were sometimes perceptible but very subtle and not visually distracting.
Three years later, the company introduced an improved second-generation product, ORNiLUX Mikado. The name refers to the crisscrossed UV pattern of the design and comes from the German name for the game of pick-up sticks.
The new pattern and improved coating of Mikado is nearly invisible to the human eye. Independent pre-market testing by the Max Planck Institute for Ornithology in Radolfzell, Germany, demonstrated that ORNiLUX windows are highly effective at protecting against bird strikes.
The first project in the USA to use ORNiLUX was at the Center for Global Conservation at the Bronx Zoo and was completed in 2009. The architects specified ORNiLUX SB1 for the entire building, but in the end it was used in only a corner conference room that had the biggest risk of bird strikes.
An ongoing monitoring program has noted a dramatic difference between the portions of the building with and without the bird-safe glass.
A year later, Munich’s Hellebrunn Zoo used ORNiLUX Mikado in the design for a new outdoor polar bear exhibit. Due to the zoo’s location near the Isarauen Nature Reserve, which harbours many wild kingfishers, bird collisions were a significant concern.
The zoo had other outdoor glass enclosures with a history of bird strikes, and previous attempts to use hawk silhouettes and bamboo plantings to protect the birds had failed.
ORNiLUX Mikado was used for the polar bear enclosure and pelican house. Zoo officials were pleased to find a solution that did not block visitors’ views of the animals and noted in the first months after it was installed that no birds had collided with the glass.
At the American Institute of Architects Expo in June 2019, Arnold Glas debuted new oversize production capabilities for its bird-safety glass, ORNILUX. It is now offered in a maximum size of 126 x 472 in (320 x 1200 cm).
What you can do: Tell local architects and builders about Ornilux.
Solution 49 in a 1-a-day series of 366 creative, hopeful ideas to clean up, repair, protect our planet:
The conventional composting of biowaste is slow.
The Rocket high-speed composting machine.
In the early 1990s, John Webb of Macclesfield, Cheshire, England, wanting to speed up the composting process on his smallholding, developed a machine that could treat his garden waste and horse manure and turn it into highly nutritious compost in just 14 days.
Working closely with DEFRA (The Department for Environment, Food and Rural Affairs) after the 2001 foot and mouth crisis, Webb and his son Simon continued to develop the machine to ensure it was fully compliant with the Animal By-Products Regulations to safely treat other organic wastes, including food waste.
They founded Tidy Planet to build and commercialise a machine they called the Rocket.
It comprises a continual flow system with waste being mixed with dry woodchip for compost production. The capacity of the electrically-powered Rocket range of machines goes from 154 gallons (700 liters) up to 3.9 tons (3.5 tonnes) per day.
Tidy Planet expanded its globally-acclaimed range of Rocket composters, with the creation of the B1400, a machine specially-commissioned for its French distributor: Alexandre Guilluy and Fabien Kenzo of Les Alchimistes needed equipment that would process up to two tonnes of a mix of food and shredded wood wastes every day – in line with the site’s waste processing threshold.
Les Alchimistes have a fleet of trailer bicycles and small vans which go around Paris collecting food waste from supermarkets, restaurants, and hotels across the French capital.
This is assembled at Lil’O known locally as L’Île-Saint-Denis an island in the River Seine, 6 mi (10km) north of The Eiffel Tower where it is turned into compost, to be sold to urban agriculture and gardening.
Due to the project’s resounding success, Les Alchimistes has received support from the French Government and EU funding to set up similar food waste collection centres in Lyon, Toulouse, Toulon, and Marseille, each of them using Tidy Planet’s B1400 Rocket. Les Détritivores based at the Ecosytème Darwin in Bordeaux are carrying out a similar operation.
In China, another solution dealing with food waste is to feed it to cockroaches (Blattodea) which then become either feed for livestock or for curing oral and peptic ulcers, skin wounds and even stomach cancer. At one farm, run by Li Yanrong in the Zhangqiu District, over 1 billion cockroaches are consuming some 55 tons (50 tonnes) of kitchen waste every day.
Elsewhere in Sichuan, a company called Gooddoctor is rearing 6 billion cockroaches, while Shandong Qiaobin Agricultural Technology Co., in Jinan plans to set up three more such plants, aiming to process a third of the kitchen waste produced by Jinan, home to about seven million people.
What you can do: Tell local authorities about advances of Rocket composters in large towns.
Biodegradable solutions have faltered in the past, largely due to the creation of microplastics, lack of compatibility with recycling systems, and confusion from consumers around the recycling of packaging.
A formula that breaks down plastic items to a sludge for easier and more complete biodegradation.
Polymateria Ltd, led by Niall Dunne and currently based at Imperial College London’s I-HUB, has come up with a solution designed to trigger a chemical conversion which attacks the structure of commonly used plastics.
As developed by Graham Chapman, Christopher Wallis and Gavin Hill, Polymateria’s biotransformation technology (or additive) converts the hydrocarbon backbone of a plastic product which has escaped a recycling facility, into an oligomeric material in two ways:
It breaks up / cuts the links in the polymer chain to produce smaller wax-like oligomeric and discrete chemical compounds, i.e. reduces the molecular weight.
Then it chemically transforms the super-hydrophobic hydrocarbon polymer backbone into a hydrophilic bacteria and fungi material capable of interaction with the natural environment, fully biodegrade within two years, leaving behind no microplastics.
In October 2019, Polymateria announced a partnership with Clariant, one of the world’s leading specialty chemical companies.
The ambition of the partnership is to bring Biotransformation technology to market in South East Asia, the main global source of “fugitive” plastic, which is plastic that escapes into the natural environment.
In July 2020, Polymateria received £18.9 m (£15 million) in funding from impact investing platform Planet First Partners (PFP) to fund the roll-out its ‘biotransformation’ technology. Sportswear group Puma will be using Polymateria’s additive in the production of 160 million plastic bags it uses each year which will be on sale in Southeast Asia in 2021.
Oil spills spread toxins throughout marine and shore ecosystems, killing and causing genetic defects in flora and fauna.
Bioremediation – the use of microorganisms, plants, or microbial or plant enzymes to detoxify pollutants into non-toxic substances.
Since the iconic 1969 oil well blowout in Santa Barbara, California, there have been at least 44 oil spills, each over 10,000 barrels (420,000 gallons), affecting U.S. waters. On March 24, 1989, the oil tanker Exxon Valdez hit Prince William Sound’s Bligh Reef in Alaska, spilling 40.9 million litres (11 million gallons) of crude oil over 1,000 miles (km of shoreline.
It is thought to be one of the worst man made environmental disasters ever. But three years later the worst oil spill in history, the Gulf War oil spill spewed an estimated 8 million barrels of oil into the Persian Gulf after Iraqi forces opened valves of oil wells and pipelines as they retreated from Kuwait in 1991.
The oil slick reached a maximum size of 101 miles by 42 miles and was five inches thick. is a process used to treat contaminated media, including water, soil and subsurface material, by altering environmental conditions to stimulate growth of microorganisms and degrade the target pollutants.
The bioremediation breakthrough came in 1972 when George M Robinson, assistant county petroleum engineer for Santa Maria, California successfully used microbes to clean out the fuel tanks on the RMS Queen Mary, the start of implementing bioremediation towards contamination sites.
This was improved by Ananda Chakrabarty, an Indian American microbiologist, who carried out performed bacterial genetics to mate the pollutant-eating bacteria into a single “super-bug” Alcanivorax borkumensis, that would eat multiple components of oil.
Following the Exxon Valdez spill, cleanup by physical methods such as skimming the water and spraying the rocky shore with detergents was used first, and the result dispersed about two-thirds of the oil. Then the genetically engineered bacteria and other bacterial strains were added to consume the remaining oil.
Because bioremediation became a prototype in the almost never-ending oil spill cleanup sites since, it has involved many interactions within scientific researchers all over the world.
Provided that proper nutrients are present, an oil spill that was estimated to be cleaned by natural conditions in 5-10 years could be cleaned in 2-5 years with the use of bioremediation.
Daniel J. Kevles, “Ananda Chakrabarty Wins a Patent: Biotechnology, law, and Society, 1972-1980”, Historical Studies in the Physical and Biological Sciences, Vol. 25, No. 1 (1994), pp. 111-135
Carbon capture should be turned to something useful.
Markus D. Herrema, founder of NewLight Technologies of Huntington Beach, California has found a way to use a specially developed micro-organism-based biocatalyst (similar to an enzyme) to turn waste gas captured from air into a bioplastic called AirCarbon, a naturally-occurring biopolymer that can match the performance of oil-based plastics and out-compete on price.
The biocatalyst pulls carbon out of methane or carbon dioxide from farms, water treatment plants, landfills, or energy facilities, then combines it with hydrogen and oxygen to synthesize a biopolymer material.
AirCarbon can be used in extrusion, blown film, cast film, thermoforming, and injection molding applications to make products, including phone cases and furniture.
Herrema, who graduated magna cum laude High Honors from Princeton University with a Bachelor of Arts degree in Politics and Political Theory, with additional work in Physics, Mathematics, and Chemistry, founded NewLight in 2003.
He was assisted by Kenton Kimmel in the design, scale-up, and optimization of the company’s gas-to-plastic technology, including the engineering, construction, commissioning, and optimization of the Company’s production lines, as well as the detailed engineering of Newlight’s commercial production facility.
Since commercial scale-up in 2013, Newlight has developed commercialization relationships with Dell, Sprint, Virgin, KI, HP, and The Body Shop. In 2015, Newlight executed a 19 billion pound off-take agreement with Vinmar International as well as 10 billion pounds in licensed production.
The following year, Paques Holdings in Balk, the Netherlands entered into a 15-year technology license agreement that would allow Paques to manufacture, process, and sell bioplastics based on Newlight’s proprietary GHG to AirCarbon™ conversion technology, at a rate of up to 1.4 million tons (1.3 million tonnes) per year.
In recognition of Newlight’s technological and commercialization achievements, Newlight was awarded “Innovation of the Year” by “Popular Science” in 2014, “Technology Pioneer” by the World Economic Forum in 2015, “Technology Excellence Award” by “PC Magazine” in 2014, “Company of the Year” by CleanTech OC in 2014, “Biomaterial of the Year” by the Nova-Institute in 2013, and an R&D 100 Award as “one of the 100 most significant innovations of the year” in 2013.
Much bioplastic uses sugar cane and molasses. But some reason that with a burgeoning global population, such vast plantations should be precision-farmed to provide food and that other sources should be used.
In 2008 a team lead by John A. Bissell and Makoto N. Masuno started up Micromidas (now Origin Materials) in West Sacramento, California to develop 95% plant-based polyethylene terephthalate (PET) plastic, made from waste biomass feedstocks, such as old corrugated cardboard (OCC), sawdust, and wood chips, that do not divert resources or land from food production for human or animal consumption.
Since non-food (“gen-2”) plant-based feedstocks do not compete with food production, Origin’s proprietary chemistry turned C-6 cellulose into four isolated building-block chemicals in one chemo-catalytic step, with almost zero carbon loss.
In March 2017 Origin joined with Danone and Nestlé Waters to form the NaturALL Bottle Alliance. The consortium released a report claiming that they had successfully produced samples of 80% bio-based PET at pilot-scale.
In September 2018 beverage firm PepsiCo joined the NaturALL Bottle Alliance. Once construction is complete, the partners expect to produce 95% bio-based PET and subsequently achieve full commercial-scale.(originmaterials.com)
Another firm using tree cellulose is VPZ (Verpackung Zentrum) in Graz, Austria. Since the late 1990s the family enterprise of Helmut and Susanne Reininger has specialised in biogenic packaging made from alginsulate foam, biopolymers made from agricultural waste materials and net packaging made from cellulose natural fibres.
Packnatur®, their tear-resistant and wet-proof tubular netting first appeared on supermarket shelves in December 2012, when REWE first used it for their Ja! Natürlich products, such as organic fruit and vegetables.
The packaging has also been used by HOFER (the Austrian ALDI) for their “Zurück zum Ursprung” (Back to the Roots) and “Natur aktiv” ranges since June 2013. Since November 2017, the Packnatur cellulose netbag has been on the shelves of the Swiss Coop supermarket chain.
The main raw material is FSC-certified beech wood, which is a by-product of forest thinning in central Europe, and which is converted to cellulose fibres by Lenzing AG, using a CO₂-neutral process in line with the strictest environmental standards. In addition, the bags feature a wooden drawstring stopper, which is also made from beech wood and turned in a local workshop. (vpz.at)
VPZ have also developed organic labels in association with IM Polymer GmbH, Lenzing Plastics GmbH & Co. KG and the Vegetable Growers Association, Marchfeldgemüse.
They have avoided the use of the thermal paper, due to the controversy around bisphenol A. and have even thought about the print on the labels. The Packnatur® organic wineglass labels are printed for EAN-Code and batch identification using thermal transfer (carbon ribbon) printing.
Boats built of glass-fibre reinforced plastic are very expensive to recycle and usually end up as carcasses in some muddy estuary.
Over in Friesland and Omrin, in August 2019, 10XL of Dordrecht teamed up with Frisian waste management company Morssinkhof in the creation of a 3D printed sloop made out of recycled polypropylene.
The 20ft (6m) boat was printed by a robotic arm with six axes, taking around 24 hours to create. It belongs to the municipality of Súdwest-Fryslân. Now that the company has more or less perfected the design, they are planning to open a ship building factory in Friesland.
Two months later, the University of Maine’s Advanced Structures and Composites Center used the world’s largest prototype polymer 3D printer to create the 25 ft (7.6 m), 5,000 lb (2,268 kg) ship, dubbed 3Dirigo. At the end of the event, the team tested the seaworthiness of its boat in UMaine’s Alfond W2 Ocean Engineering Laboratory, which features a multidirectional wave basin and a high-performance wind machine.
If pushed to its limits, the 3D printer can create objects up to 100 ft. long, 22 ft. wide, and 10 ft. high.(30m x 6.7m x 3 m) (composites.umaine.edu)
Bioplastics News, July 9, 2018 ; “Frisian companies helping create 3D printed boat from recycled plastic,” The Northern Times, August 12, 2019.
Vehicles made in steel and aluminum which are costly to extract, must be taken to a scrapyard for an energy-expensive process involving crushing, then shipping off to a recycling center where they are shredded and separated into small pieces, which are then sorted into various metals.
In the early 1940s, Henry Ford experimented with making plastic parts for automobiles. These experiments resulted in what was described as a “plastic car made from soybeans.
Based on the work of Afro-American scientist/botanist George Washington Carver, the “Soybean Car” was unveiled by Henry Ford on August 13, 1941 at Dearborn Days, an annual community festival. The exact ingredients of the plastic panels are unknown because no record of the formula exists today.
On the other hand, the Trabant automobile of which several million were made between the late 1950s and about 1990, had most of its body panels made from phenol-formaldehyde reinforced with cotton. The average life span of these cars was more than 30 years.
Sixty years later, in 2001, Deborah Mielewski, the Senior Technical Leader of Materials Sustainability at Ford Motor Company’s Research and Innovation Center in Dearborn, Michigan, initiated the biomaterials program.
Her team was the first to demonstrate soy-based foam that met all the requirements for automotive seating, enabling Ford to include the product first on the 2008 Mustang, then in every Ford North American-built vehicle.
Ford Research’s next step was to look at the agave fruit. The blue agave cactus Agave tequilana has spiked leaves and a round, fleshy core (the piña) and grows in the hot and arid regions of Mexico and the Southwestern United States.
The leaves are chopped off and the core is cooked and crushed to create juice, which is fermented and distilled to make tequila.
Jose Cuervo make the best-selling tequila in the world. As of 2012, Jose Cuervo sells 3.5 million cases of tequila in the US annually, and a fifth of the world’s tequila by volume.
Ford teamed up with Jose Cuervo to make bioplastics from agave fibre waste that otherwise must be burned or sent to the landfill, for use in vehicle interior and exterior components such as wiring harnesses, storage bins and HVAC units. This could make cars lighter and improve fuel economy.
Mielewski at Ford has also teamed up with McDonald’s to incorporate coffee chaff — coffee bean skin that comes off during the roasting process — into the plastic headlamp housing used in some cars.
The coffee version is more sustainable because it is lighter and does not use the talc which, as a mineral, is not renewable. Coffee chaff, on the other hand, is widely available. McDonald’s also achieved its goal of sourcing all of its US coffee sustainably, one year ahead of schedule, and is also working with competitors to develop more environmentally friendly coffee cups. (corporate.ford.com)
At the Gdańsk University of Technology in Wroclaw County Selena, a research group led by Wojciech Komala, is turning to plants that are not used in the human food chain as a potential source of eco-friendly plastics.
One environmental benefit of 3D printing is the ability to print items anywhere, even in a store or at home. This theoretically could significantly reduce the need to transport items and therefore lower the emissions associated with that transportation. Unlike subtractive manufacturing, 3D printing uses only the material it needs when layer by layer is added so reducing waste, while it is also capable of reusing plastic waste.
Using 3D printing, automobile dashboards and other interior components could soon be made from Tytan which has been protected by patents in Poland, Germany, France and Great Britain.
A research team led by Professor Hiroyuki Yano at Kyoto University is working on nanocellulose, a wood pulp material for automobile door panels, fenders and car hoods, a material as strong as steel, but 80% lighter. The team chemically treats wood pulp, which consists of millions of cellulose nanofibres (CNFs), and disperses these CNFs into plastic. (rish.kyoto-u.ac.jp)
Researchers at Oak Ridge National Laboratory (ORNL) in Tennessee have spent a lot of time working with unique 3D printing materials, such as polyester, lignin and nanocellulose. In 2019, a new research collaboration between ORNL and the University of Maine’s Advanced Structures and Composites Center aims to increase efforts to use nanocellulose as 3D printing materials.
Together, the team will work with the forest products industry to create new bio-based 3D printing materials that can be used to make products for building components including automobiles.
One of their partners is American Process Inc. with its nanocellulose product BioPlus, made at the company’s plant in Thomaston, Georgia. ORNL have already used their “Big Area Additive Manufacturing” (BAAM) a large fused deposition modeling (FDM) 3D-printer, in collaboration with Cincinnati Incorporated to print the full-sized, National Harbor Strati electric car in conjunction with Local Motors in Phoenix, Knoxville, and National Harbor.
The car took just 44 hours to print during the 2014 International Manufacturing Technology Show in Chicago, Illinois. The printing was followed by three days of milling and assembling.
After the car was printed, the mechanical and electrical parts such as battery, motors, and suspension were manually assembled, with the completed car first test-driven on September 13, 2014.
Local Motors also located to Tempe, Arizona where they teamed up with IBM’s Watson IoT’s AutoLAB to release the self-driving Olli shuttle bus. Local Motors has also set up localized micro-factories in Phoenix, Las Vegas, National Harbor, and Berlin, which design and manufacture automobiles in the regions they serve.
This plan has helped the company achieve a small-batch, on-demand business model, so they can keep a small footprint while working on big ideas such as the Olli bus, that have the potential to redefine existing industries. (ornl.gov)
In 2014, Mitsubishi Chemical Corporation announced the development of a new grade of high-performance, high-transparency bio-based engineering plastic called DURABIO™, for use in touch panels on automobiles, using plant-derived isosorbide as its raw material. (m-chemical.co.jp)
Netherlands: In 2018, Eindhoven University of Technology researchers created the first car made completely out of bioplastics.
The Bioplastic car was named Noah and weighs 794 pounds (360 kg) without batteries, approximately half the weight of a regular car. The batteries weigh 132 lb (60 kg). The chassis is made from sugars, the body is made from polylactic acid (PLA) and the car is weather-proof. (tue.nl)
Morgen Filament; Axel Barrett, “First Car Made Completely From Bioplastics”
Plants have been transforming sunlight into things that we can use for fuel for 1.6 billion years. However, with a few exceptions, they are still only about 1% efficient.
In 2009, Daniel D. Nocera, the Henry Dreyfus Professor of Energy at the Massachusetts Institute of Technology (MIT) founded a startup called Sun Catalytix to develop a prototype design for a system to convert sunlight into storable hydrogen which could be used to produce electricity.
During the next two years, Nocera developed what he called the “artificial leaf,” a silicon strip coated with catalysts on each side. When placed in water and exposed to sunlight, the leaf splits the H2O to release oxygen on one side and hydrogen on the other.
In August 2014, Lockheed Martin purchased the assets of Sun Catalytix, and now Sun Catalytix technology is being commercialized under the venture, Lockheed Martin GridStar Flow.
Soon after, Nocera was appointed Patterson Rockwood Professor of Energy in the Department of Chemistry and Chemical Biology at Harvard University, teaming up with Pamela Silver of Harvard Medical School to create the “Bionic Leaf”.
This merged the artificial leaf with genetically engineered bacteria Ralstonia eutropha that feed on the hydrogen and convert CO₂ in the air into alcohol fuels or chemicals.
The first model that used the nickel-molybdenum-zinc alloy created a reactive oxygen species that destroyed the bacteria’s DNA.
Abnormally high voltages were used to prevent the microbes from dying, but they also resulted in reduced efficiency. An improved model removed the nickel-molybdenum-zinc alloy catalyst and allowed the team to reduce the voltage.
The new catalyst improved the efficiency of producing alcohol fuels by nearly 10%. The Bionic Leaf operates at solar-to-biomass and solar-to-liquid fuels efficiencies that greatly exceed the highest solar-to-biomass efficiencies of natural photosynthesis.
With this system, Xanthobacter bacteria which pull nitrogen from the air and use the bioplastic, which is basically stored hydrogen, to drive the fixation cycle to make a bacteria-laden yellowish liquid that can be sprayed onto fields.
But the real proof is in the radishes. In greenhouse experiments at the Arnold Arboretum, radishes grown with this X. autotrophicus fertilizer ended up more than double the size of control radishes grown without added fertilizer.
The researchers have used their approach to grow five crop cycles. The vegetables receiving the bionic-leaf-derived fertilizer weigh 150% more than the control crops. In 2018, Nocera founded a second company called Kula Bio, to focus on the development of renewable and distributed crop organic fertilization and land restoration.
When mass-produced, these tiny solar “carbon-negative” fuel factories could be inexpensive enough for everyday people to use to power their vehicles and run their lights and appliances.
Farmers with a small on-site array of bionic leaves could create enough fertilizer for their own needs instead of buying container-loads of synthetic fertilizer produced at sprawling CO₂-spewing factories and shipped for thousands of miles.
Sargassum algae accumulates on beaches and releases poisonous gases such as hydrogen sulphide and ammonia when it decomposes.
Turn the algae into shoes, office supplies, packaging, slabs, glasses frames, mugs and more.
Since 2011, the Caribbean islands, Guadeloupe, Martinique, Saint-Martin, Saint-Barthélemy, the Dominican Republic, Barbados, and Trinidad and Tobago have faced larger and more frequent invasions of Sargassum algae and the problems associated with it.
One method of cleaning is by spade and barrow onshore. Another is by raking boats offshore. Barrages of shallow nets floated by long buoys can be used to ward off algae drifts, depending on wave height and current. Several companies have found solutions to convert Sargassum into compostable biomaterial.
Having worked in plastics manufacturing for 15 years where he specialised in the development of biomaterials, in 2010, Rémy Lucas of Saint Malo (Ille-et-Vilaine), France founded Algopack to commercialise his formula for sourcing Sargassum powder to produce a biomaterial from which office supplies, packaging, slabs, glasses frames, mugs, caddies chips etc. are made.
This included finding a system to capture Sargassum, stabilize it and make sure it does not rot during shipping from the Caribbean.
With two other Breton companies, Olmix (Morbihan) and Codif (Saint-Malo), Algopack founded an acceleration company called BioAlg. Its objective is to create a worldwide chain and to structure the collection of Sargassum, on an industrial scale. In 2015, the company was bought by Lyreco, the European leader in the distribution of office supplies and personal protective equipment. Based in Valenciennes, the group employs 2,500 people in France.
In Quintana Roo, a Mexican state on the Yucatán Peninsula, after five years of research and development, Jorge Castro Ramos of Guanajuato founded Renovare to make clothing-grade textile fibers and environmentally friendly footprint objects using recycled plastic and sargassum.
Traditionally, Sargassum was used as a natural fertilizer or a herbicide to improve the harvest of products like corn, squash, chili and beans.
Recently, this fertilizer process has been commercialised by SUEZ, through its subsidiary SITA Verde. Supported by ADEME, in Guadeloupe, SUEZ has introduced Sargassum from the territory of the riverbank deposits of the Riviera du Levant in its recovery processes.
A half a billion tonnes of used coffee grounds are dumped into general waste and sent to landfill where they emit the greenhouse gas methane.
Turn those grounds into useful things like logs that can be burned in domestic wood burners and multi-fuel stoves.
The world population drinks over 2.25 billion cups of coffee every day. With an estimated average of 11 grams of fresh ground coffee going into each cup, that adds up to an estimated 500,000 tonnes of old coffee grounds.
While low volumes of spent coffee grounds are good for fertilising domestic gardens, until the past few years, spent coffee grounds have been largely overlooked as a valid, sustainable resource on an industrial scale.
Founded in 2012, Bio-Bean Ltd. in Huntingdon, UK has developed a solution to collect thousands of tons of spent coffee grounds from businesses at every scale, from leading coffee chains and large transport hubs to office buildings, instant coffee manufacturers, restaurants and small independent cafés. It then converts them into sustainable biomass pellets.
In 2016 Bio-Bean launched their first consumer retail product, Coffee Logs, and are now poised to launch their first natural flavouring ingredient into the food and beverage industry.
Single-use plastic cups, once thrown away, can take over a century to biodegrade.
Making eating utensils out of foods.
To biomimic fruit as a replacement, Jun Aizaki of Williamsburg, Brooklyn, founder of the firm Crème, initially tested rice paper, but then settled on the gourd, a fast-growing plant of the family Cucurbitaceae, which for centuries has been used as receptacles including pots, pans and bowls, and gourds, still used to this day in Asia and South America.
For water vessels, they are still preferred over earthenware jars because they are lighter and they cool the water by evaporation. In Chinese culture, gourds were grown to hold alcohol.
In Japan watermelons are grown in little boxes so that they become square. It looks quirky and weird, but it makes them easy to stack and transport. The idea is giving nature a little bit of a nudge to form it into shapes that would be more functional.
The Crème team created 3D-printed molds in several shapes to experiment with, while Aizaki planted gourds in the backyard of his home in Brooklyn so they would grow into the shape of a cup.
After three summers of growing gourds, the team settled on two main shapes: a stackable cup that has geometric facets and a flask style with a smaller opening, which go by the name of HyO-Cup.
The finished cups are translucent, unique objects that are 100% organic and biodegradable. But it takes a month for the plant to fruit, two to three weeks for the fruit to develop, and then once it is finally grown large enough, it takes another two to three months of sitting in the sun for the gourd to dry enough that it can be used to drink out of.
Aizaki is determined to find a way of making the production process more efficient and thus more scalable.
When in 2019, Crème opened their natural timber, white-painted brick and gingham fabric RedFarm eatery in West Village, New York, following with a second eatery in Covent Garden, London, Hyo-Cups were one of the features. (cremedesign.com)
In Mexico, Scott Munguia’s Biofase Company has been making single-use cutlery and straws out of bioplastics made from discarded avocado pits. This is largely due to a phenomenon called “bonus of biogenic carbon”, which explains that the avocado tree, when growing, absorbs CO₂ of the atmosphere to form its tissues. This phenomenon does not occur in the production of any plastic derived of oil.
It takes 240 days for Biofase’s avocado seed-based bioplastic items to biodegrade in natural conditions, whether they are simply buried underground or placed in a compost pile.
The avocado pits Biofase uses are byproducts of a company called Simplot’s Avocado Farms, which are located in Mexico, keeping the manufacturing process domestic. 80% of the items Biofase produces are exported to other countries (the U.S., Canada, Costa Rica, Colombia, and Perú. Biofase also supplies straws to a few major restaurant chains, including P. F. Chang’s and Chili’s.
There is too much plastic in the world that takes too long to break down.
A compostable plastic that dissolves instantly in hot water and breaks down over a period of months on land or at sea.
In Indonesia, Kevin Kumala has taken a local and cheap root vegetable called the Cassava and combined its starch with vegetable oil and organic resins to make a compostable plastic.
The inventor claims it leaves no trace of toxic residue, which he demonstrates by drinking the dissolved plastic.
In 2014 Kumala founded Avani Eco, further innovating a material made from corn soy and sunflower seeds with which he has made ponchos. The strength of Avani Eco’s bioplastic is comparable to that of petrochemical-based plastic.
Javier Gomez Fernandez, assistant professor and a team at the Singapore University of Technology and Design (SUTD), researching into biodegradable building options investigated a fungus-like class of eukaryotes known as oomycetes.
Their structures combine cellulose with the second-most abundant polymer on the planet: chitin, an artificial polymer made from chitin, a fibrous substance which is extracted from shells of crustaceans such as shrimps.
Chitin is biodegradable polymer that is antimicrobial, antibacterial, and biocompatible.
Inspired by this newly studied species of oomycetes, a team at Singapore Univeristy of Technology and Design mixed small amounts of chitin with cellulose in an industrial dough mixer to create an organic, biodegradable composite they call Fungus-Like Additive Material (FLAM).
FLAM can be 3D-printed or cast, as well as manufactured using common woodworking techniques (e.g. sawing, drilling, polishing…) and also combinations of them. (www.epd.sutd.edu.sg
Researchers at Harvard University’s Wyss Institute have developed a material called Shrilk, an artificial insect cuticle made from chitin (a polysaccharide) and fibroin (a protein from silk).
Simply mixed together, the materials have mechanical properties that reflect the average of each material and are two times stronger than the stronger component. Shrilk could one day be used to suture wounds, and serve as scaffolding for tissue regeneration. (www.wyss.harvard.edu
Although shrimp shells are part of the waste problem in Egypt, in collaboration with the Nile University in Egypt, bioengineers at the University of Nottingham engineered chitin into biodegradable shopping bags, as well as new food packaging material to extend product shelf life.
Other materials are being developed. Scientists from the Centre for Sustainable Chemical Technologies at the University of Bath have developed a renewable plastic from a chemical called pinene found in pine needles.
In the Netherlands, Jalila Essaïdi and her team have found a way to turn manure into a bioplastic they called Mestic, which derives from the Dutch word for manure (‘mest’).
Essaïdi was approached by the agricultural sector of the Dutch province Noord-Brabant to help find a way to deal with the surplus of the manure. An annual report in 2016 showed that a total of 190,600 tons (172,900 tonnes) of phosphate was produced in the Netherlands, of which 99.7 million kg. originates from cow manure. www.jalilaessaidi.com
Humans produce almost 20,000 plastic bottles every second, according to a report by The Guardian, while a study by Oceana.org finds that as many as 34 billion plastic bottles per year end up in the ocean.
Biodegradable plastics made of corn and other plants.
In 1989, Pat Gruber working for commodity grain processor Cargill Inc., set out to turn corn into plastic. Gruber ascertained that if he fermented corn sugar with the right lactic bacteria and distilled it, this might be a route to a commercially viable biodegradable plastic.
By 1994, Gruber had progressed to a test factory to learn how to adjust the process to change the performance of the polymer for different applications.
That was enough to persuade Dow Chemical Co. to collaborate as a partner.
In December 1997, two years and one month after Cargill Dow was officially established, work began on building a US$3 million plant in Blair, Nebraska to produce NatureWorks PLA (poly lactic acid) polymer.
The plant was up and running by early 2002, with the capacity to produce an annual 154,000 tons (140,000 tonnes) of NatureWorks PLA made from 40,000 bushels of locally grown corn per day.
Gruber’s polymer was soon being used for making items such as bottles. In 2002, a manufacturing facility in Blair, Nebraska began operations.
It is the world’s first and largest PLA facility and it supplies NatureWorks’ Ingeo biopolymer. The Blair facility increased its Ingeo nameplate capacity and in 2013 NatureWorks sold 1 billion lb (454,000 kg) of Ingeo. www.natureworksllc.com
In 2009 Coca-Cola invested millions of dollars in creating its PlantBottle™, which uses PET plastic that is combined with up to 30 % of plant-based material made from sugar cane juice and/or molasses.
The company sought verification from third-parties such as Imperial College, London, where a biologist performed a life-cycle analysis of the bottle and reported that the packaging reduced the CO₂ impact by 12% to 19%.
A Michigan State University professor also confirmed PlantBottle’s green benefits. Coca-Cola has since distributed more than 15 billion of the breakthrough bottles in 25 countries, including parts of the U.S., Canada, Japan, Brazil, Mexico, Norway, Sweden Denmark and Chile. This saved 347,000 tons (315,000 tonnes) of CO₂ between 2009 and 2015.
In 2011, Coca-Cola took the first step in this collaborative innovation approach by licensing PlantBottle technology to H.J. Heinz for use in its ketchup bottles.
More than 200 million 20 oz (500 gm) packages, which feature “talking labels” asking “Guess what my bottle is made of?” reached store shelves and foodservice counters in the U.S. and Canada.
The next generation of plant-based PET packaging – or PlantBottle 2.0 – began in December 2011, when Coca-Cola invested in three leading biotech companies, Virent, Gevo and Avantium, to speed the commercialization of a PET plastic bottle made entirely from plants.
That year the company did launch a 100% plant-based bottle using a different drop-in plastic. It introduced a single-use bottle made from 100% bio-based high-density polyethylene for its Odwalla juice. The material was sourced from Brazil-based chemicals and plastics company Braskem.
In June 2012, Coca-Cola also teamed up with Ford, Heinz, Nike and Procter & Gamble to form the Plant PET Technology Collaborative.
Together, these brands have been working together to pursue a 100% renewable polyester plastic solution made entirely from plants for use in everything from clothing and footwear, to automotive fabric and packaging.
Coke is partnering with The World Wildlife Fund (WWF) to create guiding principles for sourcing agricultural feedstocks used in PlantBottle packaging.
In 2015, at the Expo Milano World’s Fair, Coca-Cola showcased the world’s first demonstration-scale PET plastic bottle made entirely from plant-based materials. The bottles used BioFormPX paraxylene produced by Coca-Cola partner Virent.
By 2018 PlantBottle technology had been used in more than 60 billion packages worldwide, although Coca-Cola was accused of “greenwashing” by a Danish local environmental group called Forests of the World who claimed that the company’s marketing of PlantBottle was exaggerated and misleading.
In July 2019 the Company committed to reducing the carbon footprint of “the drink in your hand” by 25% by 2020, compared to 2010 levels.
This includes the first-ever goal targeting for the entire Coca-Cola end-to-end value chain, cutting CO₂ across its manufacturing processes, packaging formats, delivery fleet, refrigeration equipment and ingredient sourcing.
Coca-Cola has calculated that this will directly and indirectly prevent the release of 220 million tons (20 million tonnes) of CO₂ into the atmosphere.
During the past 150 years billions of tons of chemical fertilizers have been added to the planet’s soil, many of them harmful.
A ‘charcoal’ made from biomass like wood, manure and leaves, and produces a soil enhancer that holds carbon and makes soil more fertile, reduces agricultural waste and more: Biochar.
Pre-Columbian Amazonians are believed to have used biochar to enhance soil productivity. They seem to have produced it by smouldering agricultural waste in pits or trenches. European settlers called it terra preta de Indio.
Following observations and experiments during 2006, a research team working in French Guiana hypothesized that the Amazonian earthworm Pontoscolex corethrurus was the main agent of fine powdering and incorporation of charcoal debris in the mineral soil to produce tropical soil fertility.
As high yield biochar can be produced through torrefaction or slow pyrolysis, unlike the conventional burning of wood or plant matter, the carbon stored up through photosynthesis is not released back into the atmosphere which has a significant effect on reducing AGW (Anthropogenic Global Warming) through the reduction of GHG (Greenhouse Gases).
Livestock manure, along with waste-feed residues and bedding materials, is a potential source of biochar.
Pro-Natura International has developed a continuous process of pyrolysis of vegetable waste (agricultural residues, renewable wild-grown biomass) transforming them into green charcoal.
This domestic fuel performs the same as
charcoal made from wood, at half the cost. It represents a freeing up from the constraints of scarcity, distance and cost of available fuels in Africa.
The first pilot program operated at Pro-Natura’s plant in Ross Bethio, Senegal.
Research worldwide into biochar has seriously increased over the past decade, and in India specifically, the number of studies on biochar has gone up in the past five years.
A lab at the University of Zurich is working on understanding how biochar can be effectively used and have conducted field trials in Germany, Spain, Italy, Norway, Nepal, North America, Indonesia, Madagascar, Zambia, and importantly in India where, for over 12 years, Zurich has been collaborating with GKVK College of Agriculture and the Indian Institute of Science (IISc) in Bengaluru.
On a farm near Manjimup in south-west Australia, since 2012 dung beetles have been working with cowpats to develop biochar which is then added to the cattle’s feed and reduces their methane emissions and also enriches the soil.
Find out more about some of the prominent companies currently functional in the global biochar market which is expected to reach around US$ 3.82 billion by 2025:
Because of their short lifespan as packaging, petroleum-based polypropylene (PP) and polyethylene (PE) thermoplastics end up in landfills as waste and take around 20-30 years to completely decompose.
Polypropylene made from sugar cane.
In October 2008, at the BioJapan conference in Yokohama, Braskem of Brazil announced that after five years’ research they had succeeded in producing the first green polypropylene sample made using 100% sugar cane as a feedstock resource, which was verified in accordance with ASTM D6866.
They had used fermentative ethanol production, followed by chemical conversion into ethene, dimerization and metathesis.
The following year, Braskem entered into partnership with Novozymes as well as with Brazil’s UNICAMP college and LNBio laboratory. With access to the country’s large sugarcane crops – reaching 30 million ac (12,2 million ha) in 2015 – Braskem became the leading manufacturer of non fully biodegradable bio-polymers in the world.
In 2019, after considerable R&D, Neste of Finland, the world’s largest producer of renewable diesel from waste and residues, and LyondellBasell of Rotterdam, Netherlands, one of the largest plastics, chemicals and refining companies in the world, announced the first parallel production of bio-based polypropylene and bio-based low-density polyethylene on a commercial scale.
The joint project used Neste’s renewable hydrocarbons derived from sustainable bio-based raw materials, such as waste and residue oils.
The project successfully produced several thousand tons of bio-based plastics which are approved for the production of food packaging and being marketed under the names Circulen and Circulen Plus, the new family of LyondellBasell circular economy product brands.
Neste is now working with Jokey, a leading international manufacturer of rigid plastic packaging on rigid food storage and other bins.
LyondellBasell also sold some of the renewable products produced in the trial to customers like the Melitta Group’s Cofresco, and for use in popular household wraps made by Toppits and Albal.
Cofresco plans to use the Circulen Plus bio-based polyethylene to create sustainable food packaging materials. Other uses include textiles, bottles, Rubik’s cube stickers, and even polymer banknotes.
One of Neste’s first clients was home furniture company IKEA initially for plastic storage boxes. As capacities improve, more products will follow. IKEA is working to change all of the plastic used in IKEA products to plastic based on recycled and/or renewable materials by 2030.
In June 2019, during the G20 Ministerial Meeting on Energy Transitions and Global Environment for Sustainable Growth in Karuizawa in Nagano, Japanese materials company Mitsui Chemicals introduced a new cost-effective production concept for bio-PPs – bio-propylene and bio-polyethylene.
This involves the fermentation of various biomass types, mainly non-edible plants, to produce isopropanol (IPA), which is then dehydrated to obtain propylene in a first-of-its-kind IPA method.
During the next few years, bioPP breaking down more readily in sunlight is expected to generate huge profits in terms of revenue but also contribute to planet protection.
The high levels of CO₂ in cities need to be reduced, captured and stored.
Living architecture like an algae curtain that can absorb as much carbon dioxide as 20 large trees.
Dr Marco Poletto and Claudia Pasquero of EcoLogicStudio in East London collaborated with University College London, UK and the University of Innsbruck to create a digitally designed and custom-made bioplastic flat photobioreactor that uses daylight to feed living micro-algal cultures and releases faint bio-luminescent shades at night.
Unfiltered city air enters the curtain from the bottom, and as it travels up through the liquid in the tubes, the micro-algae within capture the carbon dioxide molecules. This process of photosynthesis also produces oxygen, which is released from the top of the unit.
One curtain’s ability is equivalent to a mature tree. The main material of the hardware is ETFE, a hi-tech polymer with exceptional transparency, durability, fire retardant properties and recyclability. Another beneficial by-product of the process is biomass, which the algae grow from the sequestered carbon, and which can be burnt for energy or turned into bioplastic material, such as that used to make the curtain.
EcoLogicStudio’s first large-scale design for the Milan EXPO 2015, was an interactive pavilion containing living microalgal cultures that oxygenated air and provided shade from the sun.
In 2018 an installation of bio-curtains, composed of 53 x 22 ft (16.2 x 7 m) modules and dubbed “Photo.Synth.Etica”, was installed at the Customs and Revenue House in Dublin, during the Irish capital’s Climate Innovation Summit, created in collaboration with climate-KIC, EU’s most prominent climate innovation initiative.
Another installation was set up outside the House of Nobility Palace in Helsinki as part of that city’s Fashion Week. Here they absorbed approximately 2 lb (1 kg) of CO₂ per day, equivalent to that of 20 large trees.
In 2020, London will see its first Photo.Synth.Etica on display, as part of an exhibition at The Building Centre in June. Bio-curtains would have to be adopted on a very large scale to start making any meaningful effect.
Pakistan has lost large swaths of forest to decades of felling, which makes it vulnerable to deadly flooding and landslides.
In 2014, Muhammad Tehmasip and a team from the Government of Khyber Pakhtunkhwa launched Plant for Pakistan (Plant4Pakistan) and set about planting of 1 billon trees over five years. The Billion Tree Tsunami, as it is now known, reached its goal in August 2017.
On September 3, 2018, after becoming Prime Minister of Pakistan, Imran Khan launched a 5-year, country-wide 10 billion tree plantation drive from Makhniyal, KPK to combat the effects of AGW. This is part of the even greater initiative launched by the IUCN to restore 370 million ac (150 million ha) of degraded and deforested land worldwide by 2020, and 865 million ac (350 million ha) by 2030.
Bicycles are the most energy efficient form of transportation in the world, but the manufacturing of metal frames and components is energy and carbon intensive.
The Muzzicycle. A bicycle made of recycled plastic to replace at least some of the 2 billion in the world that are made of steel and aluminium.
In 1998, Juan Muzzi, a Uruguayan artist and mechanical engineer living in Sao Paulo, Brazil began research into PET and nylon materials including plastic bottles, shampoo containers, car dashboards and kitchen trash cans as a source of raw material, to make a plastic bicycle. It would not rust, be sturdier, more flexible and cheaper.
By 2008, Muzzi had found a way to integrate his molded frames with wheels, mudguards, pedals and seats, but it took four further years of testing to market the product to secure the seal of quality from INMETRO (Brazil’s National Institute of Metrology, Standardization and Industrial Quality).
By then a plant had been built which could take in 17,000 tons (15,400 tonnes) of recycled plastic every year using it to produce 10,000 Muzzicycles per month in every colour of the rainbow.
With 200 plastic bottles going into each frame, the process uses far less energy than is required for making traditional metal frames, saving well over 5 tons (4.5 tonnes) of CO₂ emissions, although a steel bicycle frame will lasdt a lifetime.
In 2020, Do Bem, manufacturer of fruit juice made a promise to remove from the environment 100% of the amount of long-life cartons that it produces per year, approximately 44 million.
This has included the donation of 20 Muzzicycles to four ngos in Rio de Janeiro: “Champion Hug”, “Maré Development Network”, “Irmãos Kennedy Community Center” and “Yes, I am from the Middle”.
Additionally, while working with Teto and Ecolar, the polyaluminium used to line Do Bem’s fruit juice cartons would be recycled into glasses, tiles and floors – the last two items will be used in the construction of sustainable housing organizations.
The production of a tile, for example, takes 500 boxes. Each house has 20 square meters and is made with 63 sheets and 16 recycled tiles, which requires about 40,000 cartons
In 2012 after discovering the Muzzicycle, Juan Carlos Seguro of Medellin, Colombia set up Eco Muévete Seguro making and marketing his bikes as Re-ciclas, or Re-cycles. Seguro then partnered with a local recycling firm, Kaptar, which operates a network of bottle collecting machines that link to smartphone applications.
Bottle collectors, by depositing bottles in the machine, earn points that can be spent on benefits such as subway tokens and movie passes. Kaptar’s machines take in 2,000 polyethylene terephthalate (PET) bottles every day.
Now there is a waiting list of at least 2,500 people to buy a recycled frame bike that is custom made in Sao Paulo. Juan Muzzi is now planning to manufacture recycled child’s bikes and plastic wheelchairs.
44% in bakeries, delicatessens and supermarkets. When it is deemed stale and can’t be sold it is simply thrown away.
Turn uneaten, ready-to-be-thrown-into-the-dumpster bread into ‘can-I-please-have-a-pint’ craft beer.
Tristam Stuart, the founder of Feedback based in London, England campaigns against food waste.
In December 2009, he launched a food waste campaign by organising “Feeding the 5000” in London’s Trafalgar Square in which 5,000 people were served free curry, smoothies and fresh groceries from cast off vegetables and other food that otherwise would have been wasted.
Tristam heard about a brewery in Belgium which uses discarded bread to make craft ale. There is nothing new about this process. Kvass (from rye bread) although typically not strongly alcoholic has been around in Russia, Ukraine etc. for at least 5 centuries.
After refining the recipe with Hackney Brewery in London, Stuart then contracted with Hambleton Ales in North Yorkshire to produce it in quantities.
In 2016, Tristam began selling Toast Ale at London restaurants, online and through a growing number of distributors. Using roughly one slice per ½ UK pint (284 ml) bottle, his team of three recycled 3.6 tons (3.3 tonnes) of bread in the first 15 months.
The beer is made when surplus bread is sliced and mashed to make breadcrumbs, then toasted and brewed with malted barley, hops and yeast to make a quality pale ale with a distinctive taste of caramel notes that balance the bitter hops, giving a malty taste similar to amber ales.
All profits go straight to Feedback. Toast Ale subsequently expanded nationally in the UK, and internationally to the USA, South Africa, Brazil, Iceland and Sweden.
It also open-sources a recipe for homebrewers. The company has received global press coverage and won 11 industry awards, while Tristam Stuart was named at the World Economic Forum in Davos as one of 30 leaders to inspire ambition and mobilise action to reduce food loss and waste globally. Cans of Toast Ale bear the slogan “Here’s to Change” and describes the contents as among other terms “tropical” and “zesty”, “planet-saving. ” (toastale.com)
Beaches all over the world are littered with plastics and other garbage and detritus from local sources and from washing up on the shore from sources thousands of miles away.
Efficient beach cleaners that can gather this material and transport it to properly regulated waste and recycling facilities.
In the early 1960s, Harold S. Barber of Naugatuck, Connecticut explored the idea of building a raking prototype to clean beaches of unwanted seaweed, cigarettes, glass, shells, coral, stones, rocks, sticks, and man-made debris including plastic from wet and dry sand with ease. He named the unit the SURF RAKE Model 500.
Mr. Barber’s novel invention quickly proved to be the most effective tool for the emerging beach cleaning industry in the United States. Since then, Barber has sold more beach cleaners around the world than any other brand, being used on six continents and in over 90 countries.
The tractor-towed 600HD, weighing almost 4,000 lb (1,800 kg.) can clean up to 9 ac (3.1 has) an hour, and with a 7 ft (2 m) wide cleaning path. In the 1990s, Rockland of Bedford, Pennsylvania, developed their Beach King featuring a 2.2 cubic yard hopper to take more debris. (h.barber.com)
Over in Europe, Unicorn of Torredembarra, Spain, manufacture a range of six beach cleaners from the Musketeer, a medium-sized, self-drive sifting-type machine with a vibrating mesh for surface cleaning of small areas for cleaning small beaches to the Magnum with its large capacity rear hopper that can unload at a height of 8 ft (2.50 m) and its operating width of 7.5ft (2.30 m.)
Metaljonica in the Teramo Area of Italy make EcoBeach, a macchina puliscispiaggia, powered by an 8.4 hp Honda GX270 unleaded petrol engine.
Until now, tractors towing beach cleaners have been diesel or gasoline-engined, but with the latest developments of the battery-electric tractor, they may soon become cleaner and silent.
Totally electrically driven, the Solarino developed by DronyX in 2013 a remote-controlled beach-cleaning machine, developed in Montemesola in the province of Taranto, Apulia, south eastern Italy by three mechatronics engineers – Alessandro Deodati, Emiliano Petrachi and Giuseppe Vendramin.
The Solarino includes a removable rake that scoops and discards debris. It can also be used to tow up to 2,200 lb (1039 kg) when the rake system is not attached. The Solarino is powered by 3 full isolated gel batteries and also by solar energy. The wide matched tread helps to optimize the traction system performance both on wet and dry sandy terrains. (www.dronyx.com)
In December 2019, a team led by Young-Hye Na at IBM Research Center in Almaden in San José, California, USA announced the development of a new battery built from minerals and compounds found in seawater (magnesium, potassium, boron, strontium, fluoride etc.).
It uses a cobalt and nickel-free cathode material, as well as a safe liquid electrolyte with a high flash point, thereby reducing flammability, which is widely considered a significant drawback for the use of lithium metal as an anode material.
When optimized for this factor, this new battery design will exceed 10,000 Watt per Litre (W/L), outperforming the most powerful li-ion batteries available. Additionally, tests have shown this battery can be designed for a long cycle-life, making it an option for smart power grid applications and new energy infrastructures where longevity and stability are key.
Moving forward, the team has also implemented an AI technique called semantic enrichment to further improve battery performance by identifying safer and higher performance materials.
Using machine learning techniques to give human researchers access to insights from millions of data points to inform their hypothesis and next steps, researchers can speed up the pace of innovation in this important field of study. (www.research.ibm.com)
Unlike the majority of electricity-generation technologies, which use mechanical energy to move a magnet through a coil of wire to generate a current, the man-made diamond is able to produce a charge simply by being placed in close proximity to a radioactive source.
The Bristol team have demonstrated a prototype ‘diamond battery’ using Nickel-63 as the radiation source.
They are now working to significantly improve micropower battery efficiency by utilising carbon-14 incorporated within the diamond battery.
One available source of this radioactive version of carbon, is found in decommissioned nuclear reactors where it is generated in graphite blocks used to moderate the reaction in nuclear power plants.
Extracted from waste at the Berkeley power station in Gloucestershire, Carbon-14 was chosen as a source material because it is a pure beta emitter, which is quickly absorbed by any solid material.
Carbon 14 is naturally present in the ecosystem at a background level as it is easily taken up by living matter. This would only make it dangerous to ingest or touch with your naked skin if present in unnaturally large quantities, but safely held within a diamond, no short-range radiation can escape.
Neutron irradiated (Magnox) reactor graphite blocks form the bulk of the existing legacy feedstock. Each block contains machined ‘through-hole’ channels for accommodating fuel rods and gas cooling.
The wall surfaces of these channels contain the bulk of the carbon 14 carbon which can be harvested by robots and converted into gas such as carbon dioxide and into methane. Gas centrifuges will be used to purify C14 methane and there are techniques to efficiently separate light isotopes.
The UK currently holds almost 105,000 tons (95,000 tonnes) of graphite blocks and by extracting carbon-14 from them, their radioactivity decreases, reducing the cost and challenge of safely storing this nuclear waste.
Radioactive material from a nuclear power plant being decommissioned in the U.K. could soon be used to create “ultra-long-lasting” power sources. Using carbon-14 the battery would take 5,730 years to reach 50% power, which is about as long as human civilization has existed.
Making silk with silk worms kills the worms and emits vapours that cause respiratory problems for workers.
Luxurious, environment-friendly silk made from bamboo.
Bamboo silk, a popular fibre because it is breathable like cotton and cool to the touch, is used for luxury towels, bedding and linen.
Sericulture (making silk) is not considered an eco-friendly practice. Living cocoons are collected and kept under the sun, or boiled, or exposed to steam to kill the silkworms and make the cocoons easier to unravel. The boiling of cocoons leads to the formation of vapours that can pollute the environment and also cause
Bamboo can be a very sustainable crop; a fast growing grass, it requires no fertiliser and self-regenerates from its own roots, so it does not need to be replanted.
When compared to cotton cultivation, which requires large amounts of water, pesticides and labour, the advantages are pretty clear.
The first process involves combing out the bamboo fibres and spinning these into thread. This results in a slightly coarse fabric that is usually called “bamboo linen”.
Creating this “linen” is labour intensive and expensive and the result not suitable for the soft, intimate products for which bamboo is most in demand.
The second and much more popular method is the process used to make the silky soft bamboo fabric you find in sheets, underwear and more.
This “bamboo rayon” is produced through a highly intensive chemical process, similar to the process used to turn wood chips into rayon. This is where the sustainability of bamboo gets a little prickly.
The majority of bamboo is grown in China, and there is no information regarding how intensively bamboo is being harvested, or what sort of land clearing might be underway in order to make way for the bamboo.
Also, although bamboo doesn’t require pesticides, there is no guarantee that they are not being used to maximise outputs.
A similar fabric called Lyocell (also known by the brand name TENCEL) uses a closed-loop process to recapture and reuse 99% of the chemical solution.
It was developed beginning in 1972 by a team at the American Enka fibers facility at Enka, Western North Carolina and called Newcell. The fibre was developed further as Tencel in the 1980s by Courtaulds Fibres in Coventry, UK.
Tencel is often made from sustainably farmed oak, birch and eucalyptus trees with respect for the indigenous forest, and the fabric was awarded the “European Award for the Environment” by the European Union.
Bamboo Lyocell is made with pure organic bamboo pulp; it is crushed, washed and spun into yarns. Traditional lyocell is made from wood, but bamboo lyocell is a renewable plant source.
Bamboo lyocell is silky, smooth and very soft. Companies using bamboo Lyocell include Ettitude in Los Angeles for their sustainable bedding brand.
The process of making Lyocell consists of cellulose fibre made from dissolving pulp using dry jet-wet spinning. The amine oxide used to dissolve the cellulose and set the fibre after spinning is recycled. 98% of the amine oxide is typically recovered.
Since there is little waste product, this process is relatively eco-friendly.
In 2000, CVC (Citicorp Venture Capital) sold the Tencel division to Lenzing AG, who combined it with their “Lenzing Lyocell” business but maintained the brand name Tencel.
In 2004 Weyerhaeuser Company introduced a modified kraft pulp fiber that is used to generate Lyocell fibers for textiles and non-woven products. Four years later Lenzing and Weyerhaeuser teamed up to develop lyocell-based nonwoven fabrics.
In 2016, Lenzing’s Tencel Denim Team,Tricia Carey, Hale Ozturk and Michael Kininmo, launched “Carved in Blue”, a blog covering the inner workings and innovations of the denim industry and be part of a community that has a growing environmental consciousness and creativity: stories on sustainability, trends, mills, and brands including social media channels on Instagram, Facebook, Linked In, Twitter and You Tube.
Result: as of 2017, Lenzing’s Tencel brand is perhaps the most widely known lyocell fiber producer throughout the world and is building the world’s biggest Lyocell plant in Thailand.
Dr Richard Blackburn, a sustainable materials expert from Leeds School of Design, believes this extraction method could be extended to other high cellulose plant by-products such as stalks, stems and leaves, to create different types of sustainable fiber.
In August 2020 Tencel, the textile specialty fibre brand under Lenzing, has partnered with India-based textile and garment major Arvind Ltd. to launch a collection of trendy, stylish sustainable workwear shirts and suiting for men.(lenzing.com)