The Long Story of Plastic
Understanding the ancient history of plastic is essential to putting it back to good use today.
What is plastic exactly? Where does it come from? And, where is it going? In order to use plastic wisely and make safe decisions about its future, knowing its full, science-based history is essential– what we call the ‘long story of plastic’.
More and more we’re learning that the story of plastic doesn’t end when we throw it away. According to scientists, an increasing amount of plastic is being manufactured, thrown away and reaching the biosphere, where it harms creatures large and small.
However, its just as important to understand that the story of plastic doesn’t begin in a factory. Instead, plastic finds its origins millions of years ago on an ancient, barren Earth we would barely recognize. In fact, the carbon molecules of our modern plastic played a key role in making our common home the thriving and diverse biosphere that we know today.
As you will see, we have much to learn from the way that our once barren planet has slow and steady compacted carbon, stored it, and cultivated ever-richer ecological cycles. From this long-view vantage point, we will see that plastic isn’t the problem. Rather, it’s our starting point to follow the Earth’s ancient example in our modern lives…
Once upon a time….
About 3.2 billion years ago, multicellular organisms figured out how to turn the light of the sun into life-force energy. Using photosynthesis organisms transformed sunlight by sucking in carbon dioxide and making sugars from the carbon to store energy. It was a big breakthrough. Plants grew bigger and spread across the planet. Slow and steady they began to remove the carbon in the early Earth air.
Two hundred million years ago, when the dinosaurs roamed the Earth, plants had gotten really good at transforming carbon. Immense forests covered the continents, and massive blooms of algae filled low lying seas. As plants and creatures died they would fall to the ground or to the bottom of the sea. As time passed, all this carbon-rich organic matter was covered with sediment.
With all this carbon out of the air, the Earth’s atmosphere calmed and cooled down. A combination of pressure and time transformed the buried biomass into densely packed carbon storage deposits.
Life-cycles on the planet continued to become richer and more diverse. Thanks to a combination of plants, climate and geography, one particular primate emerged two million years ago. It manged to do pretty well for itself!
Then, on a cold, dark Ice Age night, these early humans figured out fire. By lighting some sticks they had ignited the process of recombining wood’s carbon molecules with the air’s oxygen in a reaction that warmed and lit their cave.
Despite the pesky smoke, humans got better and better at burning organic stuff. A few thousand years later, humans discovered the earth’s ancient carbon storage deposits. By unearthing and burning black rocks (i.e. coal), they could get even more heat and light than by burning wood (but lots more pesky smoke).
Humans became better and better at extracting compacted carbon and turning it into energy. They discovered other types too– like petroleum and natural gas. Humans gave the stuff a name: “fossil fuels”.
As modern countries flourished their economies began to rely more on more on the easy energy gained from burning fossil fuels. Factories could be built and powered and all sorts of new products made. As more products were consumed, more factories needed to be made. As more factories needed to be powered, more and more fossil fuels were extracted and refined. Petroleum and capital flowed while economies grew.
However, organic compacted carbon deposits were never ideal for being ‘fossil fuels’. In the process of refining petroleum, there was a left over residue (5-15% depending on the crude being used) that just couldn’t be turned into fuels. This left over ‘naphtha’ began to accumulate as it had no where to go.
It was soon realized, that naphtha could be used for making stuff. With a little chemistry it could be turn into polymers, and with a little more chemistry, polymers could be turned into all sorts of new materials with an endless variety of properties. Plastics were born.
Soon humans were solving all sorts of their problems by making all sorts of amazing things from plastic. No longer did elephants need to be killed for their ivory to make billiard balls. No longer did you need expensive silver plates to take a photograph. No longer did food need to go bad in a few days. Plastics had arrived.
But what About the Smoke?
Ever since the first human bond fire, the burning of compacted carbon had been releasing that pesky smoke– mainly CO2. As the easy energy of fossil fuels enabled more and more economy, more and more capital encouraged more and more extraction and industry and carbon decompaction– the reduction in carbon density of the original deposits.
All the hard work that the earth had been doing for the last few million years, was being undone faster and faster by the humans. While burning some logs created a little smoke and some CO2, the Earth’s plants and oceans could manage to suck it back down. However, as the humans began powering their economies with fossil fuels alot more CO2 was being released– more than the earth could manage.
And since the capital in the economies was based on this burning, it created a self-perpetuating loop. The more fuels were burned, the more were extracted, and the more were burned. With so much carbon out of storage and in the air, it began to disrupt the harmony of the earth’s ecological cycles.
As humans extracted and refined more and more raw fossil fuels, there was always that little bit that couldn’t be processed. This lead to more and more cheap and abundant plastic. And as petro-capital economies grew, so too did the use and application of plastic to cover and package products.
Soon plastic was everywhere!
As plastic was bought, used and thrown away, the dynamic of carbon decompaction continued. With surfaces areas often thousands of times expanded from the orginal compacted carbon, the plastics were easily degraded by the elements. Soon microplastics could be found everywhere in the ocean, earth and air.
The more petro-capital economies grew, the more industry produced, the more it burned the more plastic was made. This made cheap plastic so abundant that it began to spill out into the biosphere. Humans tried their best to their plastic by putting it back into Industry. But the petro-economy already had so much cheap new plastic, that there was no-profit in recycling the old, and it was easier to burn it, dump it or send it somewhere else.
Soon humans came to see that industrial recycling wasn’t working. It became clear that dumpling, burning and exporting created more problems than they solved. In order for the petro-capital economy to continue growing, industry tried harder to convince itself and humans there was a solution just around the corner.
Yet, after turning many corner, there was still no solution. Meanwhile, there as so much burning, dumping, so much Co2 and so much plastic, that everyone knew that there was a problem with an economy and lifestyle that had to be powered by ‘fossil fuels’.
It became clear to the humans in these petro-capital economies that that they had much to learn from the planet’s way of relentlessly enriching the biosphere. Looking at indigenous peoples who had lived for centuries in ecological harmony with their surroundings, it was clear that they had much to learn from them also…
Learning from the Earth
Over the last few billion years we can learn much from the way the Earth transformed from a barren rock to a green, abundant, biodiverse, stable and conscious biosphere. A key part of this process has been the processing of carbon! By looking closely at the Earth’s example we see the way that…
- the Earth used carbon in the short-term as an indefinite building block.
- the Earth compacted and secured carbon into long-term storage out of the biosphere.
- all of the Earth’s procesess subtracted more carbon into storage than they added back to the atmosphere.
- all of the Earth’s processes move towards the increase in consciousness of those organisms involved
- all of the Earth’s processes moved towards the increase in biodiversity
- all of the Earth’s processes benefit the biosphere over the biome, the biome over its ecologies, the whole over the parts.
We can also draw some important conclusions from our modern experience…
- Keeping the carbon that is already under the ground is the easiest way to prevent it from getting into the atmosphere
- There is a direct connection between the running of the petro-capital economy and the decompaction of carbon deposits
Seeing Plastic Anew
In light of the Earth’s ancient history, we can see the modern of history of plastic differently…
- There is a direction connection between the running of the petro-capital economy and the production and dispersal of plastic
- Plastic is the one form of processed fuels that remains densely compacted
- Processing plastic in the petro-capital system perpetuates the decompaction of stored carbon, the release of CO2, and the dispersal of plastic
- Plastics loose in the biosphere quickly degrade into greenhouse gases, micro-plastics and toxins.
Learning from Indigenous Peoples
Many economies throughout human history have thrived in harmony with their surrounding ecologies. The way their looked at the world, what they valued and how they used money (capital) is something that we can learn much from.
The Igorot people have lived in ecological abundance in what is now the Northern Philippines for the last centuries. In their world view they have a virtue for making a place ever greener. Someone who successfully transforming barren land into a field, or a field into a garden, or a garden into a forest is called “Ayyew“. The virtue ranks with Courageous, Honor, and Loyalty in their way of seeing the world. The underlying idea of Ayyew is syncing with cycles into ever greater harmony. it is an idea that can help us make sense of the way the Earth has been working for the last few billion years. In fact, this is probably what inspired the Igorots in the first place.
Plastic is also the one fossil fuel by-product that doesn’t get immediately released into the atmosphere. As a form of concentrated carbon, it is has direct connection to the Earth’s ancient past. Our daily usage of plastic connects us to the petro-capital economy at the root of modern carbon decompaction.
The Earth’s example of short short-term carbon cycling and long-term carbon storage can be applied to our plastic. The GEA has developed the concept and criteria of plastic sequestration as means of regenerative ecological service. Learn more…
References & Recommended Readings
For a more extensive version of this page, with full footnotes, please see the Global Ecobrick Alliance Ecobrick & Brikcoin whitepaper.
We also highly recommend the research bibliography of the Story of Stuff project.
Plastic comes from ancient compacted carbon deposits
Over millions of years the Earth has tucked ancient biomass underground, compacting it and storing its carbon out of the atmosphere.
Plastic is By-Product of Petro-Capital Economy
As petroleum has been refined into the fuels that power our economies, the leftovers chemicals are ideal for producing plastics, resulting in an abundance of cheap plastic being produced.
Ecobricks keep plastic & C02 out of the biosphere. Ecobricks raise ecological consciousness. And more!
Ecobricking is a what we call a regenerative technology. Rather than "sustaining" the status quo, we're careful that everything we do re-greens rather than greys.
Ecobricking puts plastic on a safe and secure millennial road out of industry and out of the biosphere.
“The problem is always the solution”
– Bill Molinson, first principle of permaculture.
“Plastic isn’t a bad or a good thing. Its a reflection of where we, humanity, are now in the development of our collective consciousness. By facing the mirror, we have an opportunity waiting to be seized and transformed.”
– Russell Maier, GEA Co-Founder