Considering the current political climate and state of affairs (like increasing inequality and a drive to pull out social safety nets for…everyone) in the United States, I thought I’d revisit Ecology of Commerce (revised edition) by Paul Hawken. The scenario playing out right now in our government perfectly embodies his statement that, “You cannot protect a system that is rigid and entrenched without sacrificing the interests of the people it intends to serve.” Our government and the corporate interests it loyally serves is sacrificing away. The gulf between “what might be” and “what is” seems wider than ever. Perhaps that is because we are at the precipice of a new age.
I’ve been experiencing cognitive dissonance between my privileged existence and the realities of an accelerating deterioration of our local ecosystems and climate and communities. As Hawken says, “We have reached a point where the value we add to our economy is now being outweighed by the value we are removing, not only from future generations in terms of diminished resources but from ourselves in terms of unsustainable sprawl, deadening jobs, deteriorating health, and rising crime.” I hear the warning sirens from experts like Bill McKibben (Winning Slowly is the Same as Losing) and see the unreal have to be pulled into the norm. It feels like a downward spiral, with a hope for the future based on something increasingly unattainable. The reality is that way I live, despite my attempts at minimizing impact, is part of the problem. But I’m not sure where to go with that knowledge. To a large degree (as evidenced by my lack of posts on my blog over the last several months), I feel paralyzed.
I can see why Hawken focused his efforts on Project Drawdown, as the solutions he posits in Ecology of Commerce are pie in the sky, while Project Drawdown focuses on making it real. There are concrete (for lack of a better word) steps to take to address climate change. They are right there – 100 of them – researched, served up and ready to be acted upon. One of Hawken’s hopes in Ecology of Commerce is that small businesses will pick up the charge should a “revitalization and revisioning of incentives…liberate the imagination, courage and commitment that reside within individuals who truly want to make a difference – ‘ecopreneurs’ dedicated to restoring the world around them for the world that comes after them.”
My worry, similar to experts like McKibben and Hawken, is that it just can’t happen fast enough. That the massive brakes needed to stop this freight train traveling at full speed with cars full of oil and coal as far as the eye can see just don’t exist and will never exist. Perhaps it’s just not possible to slow it down.
Of course, there is another option – destroy the tracks and derail the train.
While the US government seems to lack any ability to “revision” anything other than how to consolidate power and defend the status quo for the indefensible, it’s the small efforts by individuals, non-profits and small businesses – and many of them – that perhaps are my greatest hope. This hope actually emerges from biomimicry research I started in my graduate program and plan to pick back up in 2018 – research focused on how invasive species disrupt systems quickly.
In researching invasive species, I’ve learned that invasive species aren’t considered invasive until seemingly all of a sudden they have widespread economic and environmental impact (“impact”, of course, being largely defined through the lens of human enterprise). At that point, you might say the ecosystem goes off the rails – ecosystem interconnections and resource flows are changed, sometimes irreparably so. In some cases, the eventual result is a state shift to an alternative stable state, never to shift back.
But at the point of perceived sudden widespread impact it’s not that they came out of nowhere, it’s that their small, dispersed populations went undetected or seemed insignificant (to us) AND the ecosystems in which they got established had their weaknesses. Our current systems, while being shored up by governments and increasingly walled off from the masses by corporations driven by perverse economic incentives, have clear weaknesses. The increasing number of efforts around the world to establish a different kind of system based on different criteria with different goals perhaps will eventually emerge at a large overlapping scale and shift us into a new age, the “alternative stable state” Paul Hawken and others have been talking about for decades.
This shift will derail that freight train relatively suddenly, and as with the real thing, it probably won’t be pretty. I don’t know what will emerge on the other side, but it does give me hope that the groundswell of efforts around the world, while seemingly insignificant at the moment, do actually have the potential for widespread, fast impact. When that will happen is anyone’s guess. But I hope together we can lay the groundwork to make sure that what emerges on the other side is restorative and generous. As Hawken writes, “Industrialism is over, in fact; the question remains how we will organize the economy that follows.” So let’s get on with it. Let’s change our story.
Think “flame retardant” and your next thought would not likely be “cellular respiration” and “food”. Yet it turns out a process occurring all the time in our cells (in you right now!) has invaluable lessons that have the potential to radically shift the flame retardant industry through not only new technology, but a completely radical supply chain based on raw materials from food. Yes, that’s right, food. I’ll discuss the hows and whys in Part 3 of my #SystemReset series, and demonstrate the potential paradigm shift this solution represents.
As I mentioned in Parts 1 and 2 of my #SystemReset series, using a biomimicry systems approach (including the innovation methodology and Life’s Principles) to rethink the approach to solving for the core function of a product allows innovators to quickly find existing working whole-system solutions in nature as starting points to create viable alternative human product category system solutions. These alternatives introduce radical disruption at a systems level – both affecting the product category ecosystem and beyond but also redefining (for the better) the environmental, social and economic impact of that product category – while still delivering a viable solution that addresses the core functional needs of the product category.
Nobody’s dream of the future includes their house burning down. But the fact is there are gadgets and appliances and lights throughout our homes that have the potential to catch fire, and enough accidents occur that fire is a top five leading cause of accidental death worldwide. What burns? Homes, cars, airplanes, communications equipment…you name it. The response of course is to incorporate into or douse materials with flame retardants to slow the spread of fire to enable people to escape in time. Flame retardants can be found in mattresses, couches, carpet padding, curtains, flooring, composite materials, packaging, insulating materials, glues, fabric finishes and surface coatings, plastics (oh, so many plastics) and electronic components (think computers and TVs, including cords). Great news, right? Yes and no. While they can present a clear benefit in reducing the severity of a fire and increasing the time for escape from fire in our homes and places of work, some of the major classes of conventional flame retardants can pose significant human and environmental health risks.
Your mind might now be full of questions: So how is nature’s approach different from conventional flame retardants? And why do we even care? What alternatives are already out there and how is a biomimetic solution different? If a new group flame retardants shifts the flame retardant industry, what are the potential range of impacts? Let me tackle them one by one, and as always, leave a comment below to share thoughts, ask questions and continue the discussion!
The Dominant Design in Flame Retardants
The flame retardant industry is complex. The market is dominated by three major manufacturers of flame retardants – Israel Chemicals, Chemtura and Albemarle. The largest portion of the market demand comes from the construction industry and related building materials and interior finishes. Additional demand and anticipated growing markets include construction products, electrical and electronic products, wire and cable, motor vehicles, textiles, aircraft and aerospace (check out this report I drew this information from for more info on the industry). Flame retardants are used in an incredible variety of materials from foams to plastics, wood, fabrics, paper, insulation, paints, etc. Certain families of flame retardants are typically used on some types of materials and not others, depending on the material and flame retardant properties. This is no small industry, and the variety of applications is overwhelming.
Depending on the type of flame retardant and material being protected, flame retardants can make up anywhere from less than 1% to 30% of the content of a material. For example, cellulose insulation is about 20% flame retardant by weight, plastic television and computer cases are often 10–20%, and polyurethane foam cushioning can be up to 30%. One of the challenges in creating a flame retardant is developing one that can be added to a host material without altering the properties of the host material. Because of this challenge, flame retardants are often added without chemical bonding to the host material. In addition, as some flame retardants contain volatile organic compounds, the chemicals off-gas during decomposition and evaporation (e.g., while they are sitting in your home, car and office). These challenges result in the potential for the flame retardant particles to migrate out of the host material and/or release gases into the environment.
If you’re like me, this all makes you wonder, how often and to what degree do you come into contact with flame retardants everyday? And, more importantly, what is your risk?
What are the risks?
People are primarily exposed to flame retardants in two ways – breathing it in (inhalation) or inadvertently eating it (ingestion). The flame retardants migrate out of the materials in our homes and collect in dust, which we breathe in and put in our mouths without knowing. Young children who are often on and/or close to the floor are particularly at risk of ingesting or breathing in dust containing flame retardants and are consistently found to have the highest levels of flame retardants in their systems, particularly in the Unites States. In a 2014 study of 40 child care centers in California, researchers discovered 100 percent of the centers contained both PBDE and non-PBDE flame retardant compounds, including tris(2,3-dibromopropyl)-phosphate, which was named as a presumed carcinogen in 1970 and banned in children’s sleepwear in 1977 (but not banned for other uses – facilities with foam furniture “significantly higher levels of PBDEs compared to those without foam products”).
Both halogenated and organophosphorus flame retardants pose high risks to human health and the environment. Called persistent organic pollutants (POPs), many conventional flame retardant products can be bioaccumulative meaning they are extremely slow to break down and thus persist in human tissues and the environment for years. When in the environment and exposed to ultraviolet (UV) light from the sun, some flame retardants can break down into different dioxin-like compounds that are even more toxic than the original chemical. Flame retardants are ubiquitous throughout human populations and the environment: they have been found in the tissues of people around the world, in children in California at levels 10-100 times higher than European and Mexican averages, and found in flora and fauna from the developed world to the Himalayan and Arctic regions.
These flame retardants not only contribute to development of cancer but are also linked to endocrine disruption, diabetes and hyperthyroidism; developmental problems for children such as decreased birth weight; neurological defects such as antisocial behavior, memory loss and lower IQ; undescended testicles; infertility in adults and DNA mutation (for information, check out these articles from the New York Times and Washington Post). (Anecdotally, it also makes me think about all the dogs I’ve known – you know, the ones with their noses sniffing and licking the floors of our houses – very few have died of anything other than cancer.)
When combusted, flame retardants can also degrade into even more highly toxic compounds such as dioxins, furans and formaldehyde. Primarily, it is the toxic smoke released by fires that kills or causes harm by attacking the respiratory systems of humans, posing the most significant risks to firefighters who breathe in the toxic smoke. A 2010 study in the UK revealed that at the same time that the increased use of synthetic polymers since 1955 was accompanied by an increase in fire deaths and injuries (peaking around 1980 at double the number of deaths and declining back to 1955 levels in the 2000s), the ratio of deaths from smoke and toxic gas inhalation increased by a factor of 20. As summarized in Chapter 4 of the book Polymer Green Flame Retardants (2014), the conclusions drawn from the study were that the increase of deaths from inhalation of smoke and toxic gases occurred “at least in part by the higher fire toxicity of certain polymers, and particularly those containing gas phase flame retardants.”
The broad impact of flame retardants on human health due to the pervasiveness of fire retardants in homes is unknown, particularly in the United States where measurement of the amount of flame retardants in a typical United States home is measured in ounces and pounds. Despite the known toxicity of these chemicals, due to the structure of our political and regulatory system these flame retardants are placed onto the market without a thorough study of associated health risks. Several of the halogenated flame retardants (e.g., PBDEs, polybrominated biphenyls (PBBs), and Tris-dibromopropyl phosphate) have been banned in the US and Europe, although they’ve been replaced by similar but unstudied organohalogen compounds. In the case of PBDEs, it “took nearly 40 years of exposure to PBDEs to accumulate sufficient evidence for action to be taken” (Chapter 4, Polymer Green Flame Retardants (2014)). The question then remains, why should we wait for other flame retardants to be banned – why not replace them with safer alternatives?
Much information can be found on the internet regarding more information on health risks associated with flame retardants and preventative measures that can be taken in the home, car and workplace. A good resource is the Green Science Policy Institute, which conducts scientific research and focuses on reducing the use of flame retardants. They provide easy-to-understand information on their website. In addition, two books I referenced in this section and found useful (although highly technical) were Polymer Green Flame Retardants edited by Constantine D. Papaspyrides & Pantelis Kiliaris (2014), and Fire Toxicity edited by A. A. Stec and T. R. Hull (2010). Wikipedia also has a summary and list of major studies regarding the health risks of flame retardants.
Another good thing to know – California passed Technical Bulletin (TB) 117-2013 which went into effect January 1, 2014. TB 117-2013 states that manufacturers may transition from the open flame test process adopted and mandated in 1975 to the new methods for smolder resistance of cover fabrics, barrier materials, resilient filling materials, and decking materials for use in upholstered furniture. This means when you buy new furniture, you can find a tag on it that states whether or not the manufacturer used flame retardants to achieve compliance with flammability regulations.
The search for alternatives
Because of the known health risks of the aforementioned flame retardants, some in the flame retardant industry have been researching and moving towards more benign alternatives in recent years. In fact, according to an industry report, “Halogenated retardants, represented by bromine- and chlorine-based products, are being phased out across the globe due to their perceived environmental and human health risks, creating an opportunity for suppliers of alternative flame retardants to replace them.” Now is the time for market disruption.
As mentioned above, alumina trihydrate now makes up almost 40 percent of the US market demand, and this report also indicates that “non-halogenated phosphorus compounds and other types with more environmentally friendly profiles will benefit from industry efforts to forestall increased regulatory scrutiny.” (note, that quote was written pre- the 2016 U.S. presidential election). While more eco-friendly flame retardants can be less toxic in their use and during combustion than those mentioned above, many still have human and environmental health and safety impacts.
For example, alumina trihydrate is produced during aluminum production. Aluminum is found in bauxite ore which is found throughout the world in tropical and semitropical zones. Bauxite ore is largely mined in open cast mines (strip mines). This type of mining consists of clearing vegetation then stripping and storing the top layer of native soil, mining the top few meters of bauxite ore, replacing the native soil in the (now depressed) land and replanting vegetation (the last two steps are best practice but not always completed). Approximately 40-50 square kilometers of new land are cleared each year for bauxite mining.
Alumina is then refined from bauxite ore in a process known as the Bayer process. The Bayer process includes heating the ore in a solution of caustic soda, water and other chemicals depending on the ore, and precipitating out the aluminum from the rest of the ore. The crystallized alumina are chemically bonded to water, so the crystals are then heated to 2000 degrees F to separate the water from the alumina. The byproduct of the process is bauxite tailings. For every ton of alumina produced, approximately 1 to 1.5 tonnes of bauxite tailings are generated, or approximately 150 million tonnes in 2015.
While alumina trihydrate is found to be relatively benign as a flame retardant with respect to human health during use and combustion, the production of alumina trihydrate is less than benign. While the aluminium industry for many years has been trying to address environmental challenges throughout the industry, the reality is that production of new aluminum requires open cast mining which destroys habitat, creates dust and erosion, disrupts hydrology, and can have social justice issues; and processing which requires large amounts of water and energy, produces bauxite tailings which can pollute water and land, and generates significant greenhouse gas emissions. In addition, if looking up the supply chain, the use of caustic soda presents its own problems – the process to produce caustic soda is energy intensive and can use significant amounts of mercury (depending on the process used), and necessarily generates equal amounts of chlorine, the majority of which is used to manufacture organic and inorganic compounds.
Therefore, while the industry and potentially health experts may be satisfied with the use of alumina trihydrate as a flame retardant, the negative environmental impacts associated with the product’s life cycle render the flame retardant as far from benign. The same might be true for other “eco-friendly” flame retardants such as one based on resorcinol bis(diphenyl phosphate). Many eco-friendly flame retardants are not yet on the market and need ongoing research to find scalable production and application methods, such as those made from dopamine, milk proteins or other bio-based materials.
Significant research is going into more eco-friendly flame retardant alternatives. But considering the significant health risks associated with conventional flame retardants, we need alternatives in the market sooner rather than later. And those alternatives that are not only eco-friendly in use but also in raw material production and manufacture could significantly shift the industry for the better.
Note – some efforts to find non-toxic flame retardants include research on using natural flame retardants sources from plants or animals. For example, one research effort discovered that milk proteins (caseins, found in whey, a byproduct of cheese manufacturing), when applied to certain fabrics, are effective flame retardants and do not produce toxic off-gassing during combustion. (A commercial application of this type of product, however, is not yet available). While this research uses natural chemicals and could possibly have potentially similar effect on the entire supply chain for the flame retardants it could possibly replace, this example is not biomimicry. However, all approaches that provide this type of paradigm-shifting research are valuable in the overall effort to shift away from flame retardants that are harmful to humans and/or the environment.
How would nature fight fire?
Nature deals with fire all the time, so many plants and animals have developed defenses to protect themselves against fire. What the function of fighting fire comes down to is avoiding combustion – by either sacrificing some part of their structures, deflecting, or slowing down and/or cooling a fire. One place you probably wouldn’t even think to look for knowledge about thwarting combustion is within each cell of our bodies. Cells need to convert nutrients into biochemical energy in a process known as metabolism – it’s how we grow. During metabolism, energy in the form of heat is generated basically rendering it a combustion reaction, and yet we don’t spontaneously combust! (Or at least melt into a puddle of goo.) Why is that?
It turns out that metabolic chemical reactions occur in separate steps in our cells, and while some steps generate heat (exothermic reactions), other steps absorb energy (endothermic reactions). During a key stage in the process – the citric acid or Krebs cycle – energy is generated through the oxidation of (or binding of oxygen to) acetates which is then captured as chemical energy in a molecule (adenosine triphosphate or ATP) and stored for later use as an energy source for other metabolic processes.
There are three main processes of the Krebs cycle that are applicable to the properties necessary for stopping fire. During the initial generation of energy in the Krebs cycle, carbon dioxide is released when acetate molecules are oxidized – thus taking away oxygen (fuel) and producing carbon dioxide (which does not burn). In addition, the process of capturing chemical energy in the formation of ATP is endothermic, meaning it absorbs energy, which results in cooling. Another relevant aspect of the Krebs cycle is that during the formation of ATP, water is formed which also has a cooling effect. Thus both functions of cooling and extinguishing are present in the Krebs cycle.
The “Flame Retardants from Food” solution
The Kreb’s cycle was an exciting revelation for innovation scientists and engineers working on an eco-friendly flame retardant at Trulstech, Inc. They had before them a proven, working example of a process in which oxygen and energy (e.g., heat) were consumed – just the steps that are necessary for putting out fires. So they asked, if this chemical process is happening all the time in our bodies, can we not only emulate the citric acid cycle chemical processes, but also develop the solution emulating the life-friendly chemistry so that the flame retardant is non-toxic and biodegradable? The answer is a big fat exciting YES!
Trulstech developed Molecular Heat Eater (MHE)®, a non-toxic, environmentally friendly and biodegradable flame retardant containing only food grade chemicals (in approved concentrations). Based on innovation technology emulating the Krebs cycle transfer of energy processes, MHE® both cools and extinguishes flames to stop the spread of fire in polymer, plastic and fiber materials. The MHE® technology solves key challenges posed by traditional flame retardants.
MHE® functions in multiple ways to slow or extinguish a fire. MHE® is specifically formulated according to the material physics of each host material (polymers, plastics, fibers) and its transfer of energy; specifically, MHE® is formulated according to what chemicals are released from the host material and at what temperatures this chemical breakdown occurs. The MHE® technology uses weak acids in combination with strong alkalis to create acidic complex salts. Additional carbon compounds are also added. When exposed to high heat, the salts are oxidized (meaning oxygen binds to the salts), effectively taking away the fire’s fuel (oxygen); carbon dioxide and water are released from the reaction. Carbon dioxide is a non-flammable gas and water has a cooling effect. In addition, MHE® is designed to bind to the host material at the specific temperature at which the host material starts to break down; this chemical binding is an endothermic or cooling reaction which absorbs energy, thus also lowering the temperature. For all materials, MHE® causes an intumescent or charring reaction in which the material swells as a result of the release of carbon dioxide and heat exposure, increasing in volume and decreasing in density. The char (carbon) is a poor conductor of heat thus retarding heat transfer to the unexposed material. The result is that the retardant can break the chain reaction, pyrolysis, which is a precondition for starting fire. The strategy of binding MHE® to the host material significantly reduces migration of the flame retardant into the environment.
MHE® is produced in biodegradable micro-sized particles that are applied in the form of a liquid, gel or powder. Trusltech does not produce powder below 2 microns in size because they do not want to make nanoparticles with potential health issues. The size range of 2 to 10 microns reduces the weight load because it increases the surface area of the flame retardant, thus speeding up the chemical reactions during exposure to heat (so less retardant is required). MHE® currently can be applied to most types of materials such as polyester, polyamide, PVC, polyurethane, bitumen, rubber, polyolefines, latex, cellulose-based materials, PVAc, PVA and lacquer. MHE®-treated materials have met flammability standards in markets around the globe.
True to the solution found in nature, life-friendly chemistry is used to produce MHE®. MHE® is manufactured using food grade chemicals in quantities acceptable to applicable regulatory entities and manufactured from raw materials such as grape pomace and citrus fruits. In the quantities used, these chemicals are harmless to humans, completely biodegradable in the environment, and do not break down into harmful substances when exposed to fire. In addition, because the raw materials are plant-based, the raw material life-cycle is carbon neutral. Food grade chemicals are also widely available in all markets, challenging the chemical industry’s grip on pricing and barriers to market entry. In this way, MHE® solves the risks to human health and the environment posed by other flame retardants on the market, and provides a completely alternative supply chain solution that is better for our environment. MHE® is currently on the market under the name Apyrum sold by Deflamo in Europe and the former Republics of the Soviet Union.
Impact on the flame retardant product category ecosystem
As noted above, raw materials for MHE® are sourced from food products, the products are harmless when used in approved quantities during raw material sourcing, production, manufacture, use and disposal – the MHE® alternative literally provides a different approach or indirect impact on pretty much the entire product category ecosystem and associated goods and services.
Raw materials are sourced from food, even waste products of food that can be sourced local to the production facility – a far cry from the supply chain needed for producing the raw materials for flame retardants with mineral, organic and inorganic compounds. Industries affected by this shift would include the aluminum mining industry, chlorine producers (who also happen to produce caustic soda), petrochemical manufacturers and their supply chains…you get the picture. The supply chain for this type of flame retardant has the potential to shift value from the conventional supply chain players to local farmers, adding value to local communities.
Worker safety is improved and exposure to toxic chemicals is reduced at all stages of production. As MHE® is mixed into the host material at the chemical manufacturer plant, material manufacturers have lower costs because they no longer require the equipment to mix the flame retardant and material on site, store toxic flame retardant and catalyst chemicals, maintain associated complex environmental regulatory compliance or pay the high cost for disposal of toxic chemicals.
Of course consumers benefit greatly by this type of flame retardant due to decreased health risks – reduced long-term exposure to toxic chemicals and even more toxic gases in the case of exposure to smoke from a fire. In complementary goods and services, the health industry would be impacted in the long run as costs associated with care for the significant health impacts associated with conventional flame retardants would be non-existent. Flame retardants in this family of chemicals that are combusted in a fire remain non-toxic when they turn to into a gas phase, and health impacts associated with smoke inhalation go down. In addition, if a product never catches fire, the flame retardant will eventually biodegrade, leaving no negative impact on the environment.
Not surprisingly, Trulstech has had limited success in gaining the interest of well-established, vertically integrated flame retardant manufacturers. With a racially disruptive technology, Trulstech is searching for different leverage points to disrupt the market. It can’t happen soon enough!
With an estimated 2.8 million metric tons of flame retardant produced annually by 2018, and with halogenated products being phased out due to their human and environmental risks, there is an opportunity for disruption as alternative flame retardants fill the void. Adoption of flame retardants like MHE® thus has the potential to radically shift the flame industry landscape with completely new science that enables effective resistance to combustion at a competitive cost without causing harm to humans or the environment. Talk about a complete #SystemReset!
I would love to see the life-cycle comparison of MHE® with conventional flame retardants, including alumina trihydrate, to understand the full economic and environmental impact at an industry scale of this paradigm shift if taken to scale. Check out this example of LCAs on flame retardants – the last few slides referencing the UK study I understand to include an LCA of MHE – would love to see it! But while this is fantastic, I want to try to grasp the full impact of shifting the entire industry. What would this world look like? Can we paint a clear picture? Any takers?? Let’s put real numbers to this #SystemReset.