Tag Archives: are we recycling too much of our trash

Recycle More? Or…Recycle Better?

Guest Blog by Susan Robinson, Senior Public Affairs Director for Waste Management

The other day, two colleagues from the waste and recycling world asked me to help settle a dispute. These two very smart people—one with a Ph.D.—were debating the composition of a plastic microwave tray and how it might be recycled…or not. Should they just toss it in the bin for the recycler to deal with? Municipal guidelines were unclear, but it felt wrong to just throw it in the trash. In the end, they tossed it into the single-stream recycling bin and hoped it would be recycled.

The episode left me wondering. If even we in the waste management world are so confused, what does this mean for the success of recycling in general?

Changing Habits, Changing Waste

Remember newspapers? Once common in American households, newspapers are increasingly a relic, as more and more of us read our news on computers or portable devices. The result? The United States generates a whopping 50 percent less newspaper than we did a decade ago, and 20 percent less paper overall. That’s a huge decrease for a ten-year stretch.

While paper use has declined, the use of plastics has exploded, with new resins and polymers allowing for new possibilities in packaging. Changing demographics—especially the large Baby Boomer and Millennial generations —mean that more consumers are choosing convenient, single-serve packages for meals and snacks.

At the same time, an emphasis on fresh, healthy, and convenient foods is driving a boom in plastic packaging, which can reduce food waste to the tune of preventing 1.7 pounds of food waste for each pound of plastics packaging. However, there is a loss of recyclability on the back end, after those packages have served their use. Today’s recycling materials recovery facilities were built to process approximately 80 percent fiber and 20 percent containers, not the 40/60 or 50/50 mix that we are seeing today. The new mix of inbound material is leading to increased processing costs.

Prevalence of Plastic in Packaging: Saving Grace or Problem Child?

Plastic packaging is both a boon to the environment and a challenge. It’s lightweight, great at protecting and preserving goods, and as a petroleum-based product, in the current global marketplace, it’s cheap. Flexible plastics packaging—also called “pouches”—offer new levels of convenience and freshness, especially in the food industry.

Plastics offer environmental benefits, too. When you look at the entire lifecycle of many types of plastic packaging, they require far fewer raw materials and less energy to manufacture than do other packaging alternatives. Over the years, as the use of plastics has grown in consumer goods and packaging—increasingly crowding out glass, metals, and some paper—society has reaped these benefits. Yet, if there is a downside to plastics, it’s that they have had a dampening effect on recycling quality.

It’s extremely confusing for consumers to understand how to recycle plastics. For starters, there are all the numbers—1 through 7—each with their own, distinct chemical properties, uses, and recyclability. In addition, many manufacturers are including additives to color their packaging, resulting in low-grade plastics that can’t be recycled. So, for every plastic container that can conceivably be recycled—where facilities exist—there are scores that can’t.

So, what do the numbers mean? Here’s a sample consumer plastics recycling guide from Moore Recycling Associates.

Plastic Resin Codes

Is it any wonder that consumers are confused?

As we all know from experience, it can be mighty challenging indeed to determine how and where to properly recycle these materials. Many of us simply toss plastics into the recycling bin—and hope for the best.

Contamination of the Recycling Stream

The mixing of non-recyclable plastics into the recycling stream—called contamination—is a common occurrence. Types of low-grade plastics are not recyclable, while plastic bags are typically only recyclable by returning them to grocery or retail store for recycling (not curbside), so their presence increases contamination and the cost of recycling across the board. In most communities, an inbound ton of waste now has an average of 17 percent contamination, while some loads can contain as much as 50 percent non-recyclable material.

Lightweighting Adds to the Mix

Lightweighting—using lighter material for a product or reducing the weight of the material itself—is becoming a common practice, especially with water bottles made from PET (polyethylene terephthalate). With lightweighting, a typical water bottle now weighs about 37 percent less than it used to. Lightweighting has many benefits, like reducing the amount of plastics used and therefore produced, and helping to lower freight costs during transport of products. But lightweighting challenges the current economics of recycling.

For example, in the current recycling commodities market, recovered PET plastic feedstock is sold by weight, not volume. This means that we need to process 35,000 more bottles than we used to, in order to create one ton of PET feedstock. Using this formula, we would have to process 3.6 billion more water bottles each year to get the same weight of material that we sold a decade ago. Since our costs are currently based on volume and our revenue based on weight, lightweighting drives up our costs and dampens the long-term economic feasibility of recycling and recovery programs.

The Troubled Economics of Recycling

For the past several decades, our primary customer for many types of recyclables has been China, whose booming economy required an almost constant supply of raw materials. However, as China’s economic growth has slowed, they have started to limit the kinds of recyclable feedstock they will accept, shrinking the marketplace and reducing demand for this material.

At the same time, the strong U.S. dollar makes U.S. recyclables more expensive, and therefore less attractive, on the global market. Low oil prices also make virgin materials more attractive than feedstocks derived from recycled content. In other words, the market for plastic feedstocks is shrinking—just as the costs to create those feedstocks are rising (our next blog will talk more about this).

What Is the End Goal?

As a society, we used to think that if recycling is good, then more recycling is better. We made recycling convenient so we could collect more recyclables and achieve our weight-based goals. In the process of pushing for higher recycling weights, however, many have lost sight of the actual goal: to lessen the overall environmental impacts of the waste we produce. If we go back to this larger picture, we see that success doesn’t necessarily mean recycling large percentages of material based on the weight of the waste stream; rather, success means a reduction in greenhouse gas emissions or raw materials extraction. Recycling is one way to achieve this goal, but it is not the ultimate goal. As we all strive to achieve our overall environmental goals, recycling is just one tool in our toolbox.

The popular, newer, non-recyclable plastics test the very goals of recycling. No one wants to put more plastic in a landfill, but when you look at the true environmental impact of different plastic products and uses, the results might surprise you. For example, an EPA lifecycle study looked at different types of coffee packaging to see which consumed the most energy, emitted the most CO2 equivalent gas, and produced the most municipal solid waste. The researchers found that both the traditional recyclable steel can and the large plastic recyclable container performed worse than the non-recyclable flexible plastic pouch. The lightness and flexibility of the plastic meant such savings in transportation and efficiency that it had a smaller environmental footprint overall than did the recyclable materials.

So, Where Do We Go From Here?

Flexible plastics aren’t going anywhere, so consumer education is crucial to preventing contamination at recycling facilities. This is why recyclers and cities are devoting large amounts of resources to help people understand what’s recyclable—and what’s not. We will eventually figure out how to recycle flexible plastics. However, we also need to rethink what our goals really are—and how best to measure them. Is measuring recycling percentages based on weight the best way? Or is it time to find a new way to gauge our success?

At Waste Management, we believe that it is time to change our collective thinking around this critical issue. As the waste stream is increasingly filled with more energy-efficient and lighter weight materials, it’s simply not sustainable to continue to set recycling goals that are unrealistic and fail to capture important environmental benefits like overall emissions reductions.

Perhaps the time has come to shift to a new metric: a “per capita disposal goal” that can better account for the full value of waste reduction. That’s to say, what if the focus weren’t just how much you recycle, but how much greenhouse gas you avoid? Instead of recycling for the sake of reaching a weight target, the goal would be to achieve the best overall result for the environment.

Such a measure, reflecting a lifecycle approach to managing materials, could go a long way toward accurately capturing the full picture of materials use, and send the right signal for truly sustainable materials management practices.

Additional comments by Danny Clark, President ENSO Plastics

This was a very informative blog by Susan Robinson.

The biggest issue that I see in the industry and with talking to sustainability managers and consultants across the board is that many of them have mistakenly fallen into the trap of going with the “flow” or “public think” about how to implement sustainability for the plastic materials used in products and product packaging. The knee jerk thought that we should recycle everything approach is based more on a feel good response and not on any science or data.

Its only after our first decade into the “green movement” that we are realizing the key to developing solutions that make sense is to use science and data to our approach to determining what will minimize our environmental impact.

ENSO Plastics is all about the science and data and LCA studies show that we can reduce our carbon footprint with plastics that are designed to be landfill biodegradable. Over 74% of all municipal solid waste is being disposed of into landfills that are already capturing the converting landfill gas to energy. The LCA studies of converting plastics into landfill gas that is then converted to energy reduces the carbon footprint significantly.

As a society we’ve seem to have been pushed into a direction of demonizing landfills while at the same time promoting the notation that recycling everything must be good for the planet. Some of us are just now realizing that the science and data do not support that environmental folklore approach. Its time we get out of our way and rethink the way we address our plastic waste because what we are doing now does not and will not work in the long-run.

Read the original blog here: http://mediaroom.wm.com/recycle-more-or-recycle-better/

Are we recycling too much of our trash?

Thomas Kinnaman – Professor of Economics, Bucknell University

A recent credible study suggests the amount of waste Americans dispose in landfills each year is over twice what the EPA had been estimating.

Although this news may not surprise the country’s disposal facilities (who already knew the quantity of waste they take in), the study may strike an old nerve for many Americans – that our society generates too much garbage. The answer, we have been repeatedly told, is to recycle our waste. In fact, plans for zero waste or 100% recycling have been hatched in places including Berkeley, California and Indianapolis, Indiana.

But is more recycling always better than less recycling? Is it conceivable that society can recycle too much? What does the research say about the costs and benefits of recycling?

Unfortunately, not much is available. We may sense that more recycling is better than less recycling, but we really do not know. Our recycling habits developed not in the wake of a scientific understanding of these matters but perhaps, as John Tierney describes in his recent New York Times piece, on a leap of faith.

Last year, I coauthored a research study to estimate society’s optimal recycling rate. Results surprised us – society’s best recycling rate is only 10%. And only specific recyclable materials should be included in that 10%. What drives these results?

The literature on recycling

First, dozens of published economic studies from across the globe estimate that landfills depress neighboring property values, although this negative impact appears to diminish for small landfills. Second, a growing number of published life cycle analyses suggest that mining raw materials is damaging to the natural environment, and manufacturing goods with recycled materials rather than their virgin counterparts can be beneficial to the environment. But the magnitude of these benefits varies across materials.

Finally, the economics literature suggests recycling requires more economic resources than simple waste disposal. The value of the extra energy, labor and machinery necessary to prepare materials for recycling can double the value of those resources needed to dispose the material in the landfill.

Our study made the first known attempt to combine these various costs and benefits into one analysis to estimate what recycling rate is best. Our conclusion was that recycling up to 10% appears to reduce social costs, but any recycling over 10% costs the environment and the economy more than it helps. The environment and economy suffer as we transport some recycled materials to destinations as far afield as China.

It’s generally cheaper to send household garbage to a landfill than to recycle because there are lower processing costs.

These provocative results certainly require confirmation from future independent and objective research before broad policy goals can be adjusted. Also, many of the benefit and costs associated with waste disposal and recycling vary across regions of the country and world, and thus optimal recycling rates may also vary. For example, we used municipal cost data from Japan for this study because the United States and most European countries do not keep such data.

But if these results hold for other developed countries, then society should collectively rethink how to approach recycling.

Detailing the costs of waste and recycling

This paper identified several factors that help justify possible reductions in the recycling rate.

First, the environmental damages associated with both modern landfills and incineration plants turn out to be less than traditionally imagined. These facilities certainly depress neighboring property values – on average each ton of waste deposited in a landfill or incinerated is found to reduce property values by about US$4.

But modern disposal facilities in most developed countries are required to abide by strict environmental standards, and air and water pollutants such as methane and carbon generated by these facilities (and the carbon monoxide and consumption from the trucks transporting waste to these facilities) appear less than previously expected. These environmental standards have increased disposal costs (tipping fees) paid by waste generators by as much as $50 per ton, but the remaining external costs have fallen to roughly $5 per ton disposed. Thus, collectively waste disposal facilities generate just $9 per ton in external costs borne by society ($4 from depressed property values plus $5 from remaining air and water pollutants). Economists had once imagined external costs of $67 per ton to as much as $280 per ton.

But because these costs do not appear on the balance sheet of the disposal facility, the assessment of a corrective tax of $9 per ton disposed is necessary for disposal facilities to consider these costs when making decisions. Once this tax is in place, then laws requiring municipalities to recycling can be lifted.

Municipal programs have greatly expanded recycling in the US.

Second, recycling is rather costly to municipal governments. The cost for New York City to process one ton of materials for recycling markets is about $300 more than the cost of simply taking that same material to the landfill, according to the recent New York Times article. In many cases, the travel itinerary for recycled materials, which increasingly includes final destinations in developing countries, exceeds by large margins the distance that garbage is transported.

Third, we found the primary benefits of recycling accrue not from saving landfill space but from generating materials that, when used in production, are less costly to the environmental than mining those materials from the earth. Our study concludes that using an average ton of certain recycled materials in the place of a ton of virgin materials generates environmental spillover benefits of as much as $400 per ton.

By the way, this monetary estimate (and all dollar estimates associated with environmental considerations) is calculated using two processes. First, the life cycle analysis identifies the physical quantity of carbon, sulfur, nitrates and other pollutants associated with the entire life cycle of waste and recycling systems. Second, the economics literature has developed per-dollar estimates of the impact each unit of pollutant costs society. Each ton of carbon, for example, has been estimated to generate $25 of damage to the natural environment.

Targeted recycling

But the substantial environmental benefits outlined above of using recycled materials in production vary substantially across materials. Aluminum and other metals are environmentally costly to mine and prepare for production. Paper, too, is costly to manufacture from raw sources. But glass and plastic appear relatively easy on the environment when manufactured from raw materials.

These differences are vital. Although the optimal overall recycling rate may be only 10%, the composition of that 10% should contain primarily aluminum, other metals and some forms of paper, notably cardboard and other source of fiber. Optimal recycling rates for these materials may be near 100% while optimal rates of recycling plastic and glass might be zero. To encourage this outcome, a substantial subsidy offered only on those materials whose life cycles generate positive environmental benefits should be applied.

In the end, the economy and the environment, speaking in one unified voice, may wish for society to reduce the overall quantity of waste recycled. Perhaps recycling efforts need to surgically focus on only those specific materials that really matter to the economy and the environment. Other materials can be simply disposed of in modern facilities.

Read original article at: https://theconversation.com/are-we-recycling-too-much-of-our-trash-48724