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Innovation

Can we live without plastic?

A panel of experts at the National Building Museum talks about the life cycle of plastic; the role of green chemistry in eliminating hazardous materials; and new alternative materials, including... mushrooms?
Written by Melanie D.G. Kaplan, Inactive

WASHINGTON -- Last week I went to a program at the National Building Museum, Life After Plastic, during which panelists discussed the impact of rising oil prices on the cost of plastic building materials; the life cycle of plastic; health and environmental concerns; and new product materials such as soy, corn and mushrooms.

ModeratorLance Hosey, president and CEO of GreenBlue (a nonprofit focused on sustainable design and production in business and industry) started off the discussion by telling us that we produce some 300 billion pounds of plastic a year, in highly toxic and dangerous petro-chemical plants. Less than 5 percent of plastic is recycled, he said; other than the small amount of plastic that has been incinerated, every piece of plastic ever made still exists today.

Later he told us, “We spend so much time agonizing over making better [water] bottles—how is it sourced, how is it made--instead of asking: Why are we shipping water from France to begin with? Why are we carrying [them] around to begin with?"

As I listened to the panelists, I sat on a plastic chair, typed on a plastic laptop with a plastic clip in my hair, plastic sunglasses on my head, and a plastic cell phone, a plastic pen and a plastic-filled wallet in my bag. Will plastic ever disappear? Here’s what the experts had to say:

Blaine Brownell
Assistant Professor
University of Minnesota School of Architecture

There are a lot of plastics that come from oil, but… we’re increasingly seeing plastics that come from renewable material. And I think scientists and architects are becoming more aware of what happens after that first life of a product.

One of my favorite [alternative materials] comes from a company called Ecovative Design. MycoBond (used to replace foam) and MycoPly (used to replace balsawood) are made from agricultural waste and mushrooms. They’re very fringe—it’s rudimentary uses now: packaging, shipping. There’s also some companies making things from invasive plants. PIE (Project Import Export, Inc.) uses water hyacinth to make wicker furniture. But it’s interesting to think about the process by which they’re created—the method has changed. You’re calling and ordering a product, and the manufacturer starts growing it instead of manufacturing it.

There’s certainly red flags [about materials] today, versus my first naïve career as an architect, where I’d just grab things off the shelves. There’s increased demand for [sustainable building products], but as architects, it’s not easy. If, for example, it comes from a place where chain of custody is sketchy, it can have the greenest chemistry but not be the green product we’re looking for.

What I teach students: It seems we have to embark on a new era of really creative solutions that are adaptive reuse-focused.

In terms of the technology, we can create plastics from renewable materials. There are a lot of different sugars from which we’re getting bioplastics. Dr. Wool from the University Delaware said the industry is moving like gangbusters toward a time when we move away from polyurethane, and it’ll be more tied with the agriculture tradition.

There’s an interesting issue about durability in the physical environment and the desire for that--like what vinyl siding does so well--versus the fear factor that we don’t want [the plastic around forever]. There’s this strange conflict that emerges. I’m asked about biodegradation, which we want in some cases (we want the water bottle to biodegrade), but what about buildings? We don’t want those to biodegrade. [We need to think about the] time scale to design: So is this a 100-year building or 25-year building? There’s so much emphasis on up –front first use.

Jay Bolus
Vice President of Technical Operations
MBDC

Alternatives to petroleum based plastic: Corn-based, cellulose-based, soy based, sugar based. Polyethylene is one of the greener plastics; it can actually be made from sugar cane.

To me, the building block is not as important as what happens at the end—if we keep throwing things into the landfill or incinerator we’ll never [make progress]. I don’t really feel like the problem is the [materials]; it’s more end of life.

There’s not a one-size-fits-all plastic. Maybe sugar cane makes sense in certain regions of the world, but we’re going to need a whole suite of solutions. In some cases, it might make sense to use sugar cane; or to use petroleum-based plastic; or to switch to steel and aluminum.

Recycling came about as a waste management strategy; it’s not about reusing materials. You can mandate it, but until you start looking at it that way [as a valuable material] I don’t think any of these programs will really work.

Robert Peoples
Director
American Chemical Society’s Green Chemistry Institute

I think plastic is going to be with us for a long time. I’m believer in evolution: We have to evolve, increasing our understanding over time. We’re beginning to understand how these synthetic materials interact with living systems. I think you have to dig very deep to understand all the issues when you talk about materials. There are many kinds of plastic. So the big challenge for us is: Can we develop materials that are benign by design and derived by something other than petroleum?

Green chemistry is all about thinking about end of life considerations before you design the molecule and put it into the environment. If you apply these design principles up front, you would know if it’s not a good molecule.

The goal [in green chemistry] is to reduce or eliminate the hazardous materials or products. It’s a proven systems approach. We have hundreds of regulations in the U.S. that deal with chemicals. If you can apply the principals of green chemistry, you won’t need regulations.

There are zero federally funded green chemistry centers in the U.S. China is a mess environmentally right now, but China gets the fact that green chemistry is [the solution]; there are more than 20 green chemistry centers federally funded by China right now. They understand that they have created a crisis, and they are going to invent their way out of that crisis. The sad thing is that we’re paying for it--it’s our appetite for all of these disposable materials.

Our goal is to always get greener. There are plastics that are greener than others. There’s probably nothing out there that we’d call truly green, but manmade materials, most derived from oil today, will fall across some spectrum of green.

I would say it’s not just transiting from petroleum-based to bio-based. The first thing we have to do is make people aware that alternatives exist, and then we can provide education and information. Then we have the economy of scale, and then we’ll make progress. We are making progress, it’s just slower than some of us would like to see it.

We buy 30 to 50 billion [PET bottles] in the U.S. We recycle about 25. The others get sent to the landfill.

We can’t achieve a sustainable society by the linear expansion of the existing technologies we have. We’ll have to do things differently and pay a little more if we want to make changes, and we can’t be myopic about it. What works as a good solution where they have a lot of sugar cane in Brazil may not work in Sydney or san Francisco.

We must get the economics right. Society has to bear the cost of sustainability. We’ve kind of had a free ride--when you’re done with something you throw it away. But we know there’s no such thing as “away,” because you can’t destroy matter. We’ve been throwing things away not worrying about where “away” is, and “away” is coming back to haunt us.


This post was originally published on Smartplanet.com

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