Climate change and the textile industry

15 10 2014

Time sure flies doesn’t it?  I’ve been promising to reiterate the effects the textile industry has on climate change, so I’m re-posting a blog post we published in 2013:

In considering fabric for your sofa, let’s be altruistic and look at the impact textile production has on global climate change. (I only use the term altruistic because many of us don’t equate climate change with our own lives, though there have been several interesting studies of just how the changes will impact us directly,like the one in USA Today that explains that wet regions will be wetter, causing flash flooding; dry regions will get drier, resulting in drought. And … a heat wave that used to occur once every 100 years now happens every five years (1)).

Although most of the current focus on lightening our carbon footprint revolves around transportation and heating issues, the modest little fabric all around you turns out to be from an industry with a gigantic carbon footprint. The textile industry, according to the U.S. Energy Information Administration, is the 5th largest contributor to CO2 emissions in the United States, after primary metals, nonmetallic mineral products, petroleum and chemicals.[2] And the U.S. textile industry is small potatoes when compared with some other countries I could mention.

The textile industry is huge, and it is a huge producer of greenhouse gasses (GHG’s). Today’s textile industry is one of the largest sources of greenhouse gasses  on Earth, due to this huge size.[3] In 2008, annual global textile production was estimated at 60 billion kilograms (KG) of fabric. The estimated energy and water needed to produce that amount of fabric boggles the mind:

  • 1,074 billion kWh of electricity or 132 million metric tons of coal and
  • between 6 – 9 trillion liters of water[4]

Fabrics are the elephant in the room. They’re all around us but no one is thinking about them. We simply overlook fabrics, maybe because they are almost always used as a component in a final product that seems rather innocuous: sheets, blankets, sofas, curtains, and of course clothing. Textiles, including clothing, accounted for about one ton of the 19.8 tons of total CO2 emissions produced by each person in the U.S. in 2006. [5] By contrast, a person in Haiti produced a total of only 0.21 tons of total carbon emissions in 2006.[6]
Your textile choices do make a difference, so it’s vitally important to look beyond thread counts, color and abrasion results.
How do you evaluate the carbon footprint in any fabric? Look at the “embodied energy’ in the fabric – that is, all of the energy used at each step of the process needed to create that fabric. Not an easy thing to do! To estimate the embodied energy in any fabric it’s necessary to add the energy required in two separate fabric production steps:

  1. Find out what the fabric is made from, because the type of fiber tells you a lot about the energy needed to make the fibers used in the yarn. The carbon footprint of various fibers varies a lot, so start with the energy required to produce the fiber.
  2. Next, add the energy used to weave those yarns into fabric. Once any material becomes a “yarn” or “filament”, the amount of energy and conversion process to weave that yarn into a textile is pretty consistent, whether the yarn is wool, cotton, or synthetic.[7)

Let’s look at #1 first: the energy needed to make the fibers and create the yarn. For ease of comparison we’ll divide the fiber types into “natural” (from plants, animals and less commonly, minerals) and “synthetic” (man made):

For natural fibers you must look at field preparation, planting and field operations (mechanized irrigation, weed control, pest control and fertilizers (manure vs. synthetic chemicals)), harvesting and yields. Synthetic fertilizer use is a major component of the high cost of conventional agriculture: making just one ton of nitrogen fertilizer emits nearly 7 tons of CO2 equivalent greenhouse gases.
For synthetics, a crucial fact is that the fibers are made from fossil fuels. Very high amounts of energy are used in extracting the oil from the ground as well as in the production of the polymers.
A study done by the Stockholm Environment Institute on behalf of the BioRegional Development Group concludes that the energy used (and therefore the CO2 emitted) to create 1 ton of spun fiber is much higher for synthetics than for hemp or cotton:

KG of CO2 emissions per ton of spun fiber:
crop cultivation fiber production TOTAL
polyester USA 0 9.52 9.52
cotton, conventional, USA 4.2 1.7 5.9
hemp, conventional 1.9 2.15 4.05
cotton, organic, India 2 1.8 3.8
cotton, organic, USA 0.9 1.45 2.35

 

The table above only gives results for polyester; other synthetics have more of an impact: acrylic is 30% more energy intensive in its production than polyester [8] and nylon is even higher than that.
Not only is the quantity of GHG emissions of concern regarding synthetics, so too are the kinds of gasses produced during production of synthetic fibers. Nylon, for example, creates emissions of N2O, which is 300 times more damaging than CO2 [9] and which, because of its long life (120 years) can reach the upper atmosphere and deplete the layer of stratospheric ozone, which is an important filter of UV radiation. In fact, during the 1990s, N2O emissions from a single nylon plant in the UK were thought to have a global warming impact equivalent to more than 3% of the UK’s entire CO2 emissions.[10] A study done for the New Zealand Merino Wool Association shows how much less total energy is required for the production of natural fibers than synthetics:

 

Embodied Energy used in production of various fibers:
Energy use in MJ per KG of fiber:
flax fibre (MAT) 10
cotton 55
wool 63
Viscose 100
Polypropylene 115
Polyester 125
acrylic 175
Nylon 250
SOURCE: “LCA: New Zealand Merino Wool Total Energy Use”, Barber and Pellow, http://www.tech.plym.ac.uk/sme/mats324/mats324A9%20NFETE.htm

Natural fibers, in addition to having a smaller carbon footprint in the production of the spun fiber, have many additional benefits:

  • being able to be degraded by micro-organisms and composted (improving soil structure); in this way the fixed CO2 in the fiber will be released and the cycle closed. Synthetics do not decompose: in landfills they release heavy metals and other additives into soil and groundwater. Recycling requires costly separation, while incineration produces pollutants – in the case of high density polyethylene, 3 tons of CO2 emissions are produced for ever 1 ton of material burnt.[11] Left in the environment, synthetic fibers contribute, for example, to the estimated 640,000 tons of abandoned fishing nets in the world’s oceans.
  • sequestering carbon. Sequestering carbon is the process through which CO2 from the atmosphere is absorbed by plants through photosynthesis and stored as carbon in biomass (leaves, stems, branches, roots, etc.) and soils. Jute, for example, absorbs 2.4 tons of carbon per ton of dry fiber.[12]

Substituting organic fibers for conventionally grown fibers is not just a little better – but lots better in all respects:

  • uses less energy for production, emits fewer greenhouse gases and supports organic farming (which has myriad environmental, social and health benefits).  A study published by Innovations Agronomiques (2009) found that 43% fewer GHGs are emitted per unit area under organic agriculture than under conventional agriculture.[13] A study done by Dr. David Pimentel of Cornell University found that organic farming systems used just 63% of the energy required by conventional farming systems, largely because of the massive amounts of energy requirements needed to synthesize nitrogen fertilizers. Further it was found in controlled long term trials that organic farming adds between 100-400kg of carbon per hectare to the soil each year, compared to non-organic farming. When this stored carbon is included in the carbon footprint, it reduces the total GHG even further.[14] The key lies in the handling of organic matter (OM): because soil organic matter is primarily carbon, increases in soil OM levels will be directly correlated with carbon sequestration. While conventional farming typically depletes soil OM, organic farming builds it through the use of composted animal manures and cover crops

Taking it one step further beyond the energy inputs we’re looking at, which help to mitigate climate change, organic farming helps to ensure other environmental and social goals:

  • eliminates the use of synthetic fertilizers, pesticides and genetically modified organisims (GMOs) which is an improvement in human health and agrobiodiversity
  • conserves water (making the soil more friable so rainwater is absorbed better – lessening irrigation requirements and erosion)
  • ensures sustained biodiversity
  • and compared to forests, agricultural soils may be a more secure sink for atmospheric carbon, since they are not vulnerable to logging and wildfire.

Organic agriculture is an undervalued and underestimated climate change tool that could be one of the most powerful strategies in the fight against global warming, according to Paul Hepperly, Rodale Institute Research Manager. The Rodale Institute Farming Systems Trial (FST) soil carbon data (which covers 30 years) provides convincing evidence that improved global terrestrial stewardship–specifically including regenerative organic agricultural practices–can be the most effective currently available strategy for mitigating CO2 emissions.

At the fiber level it is clear that synthetics have a much bigger footprint than does any natural fiber, including wool or conventionally produced cotton. So in terms of the carbon footprint at the fiber level, any natural fiber beats any synthetic – at this point in time. Best of all is an organic natural fiber.
And next let’s look at #2, the energy needed to weave those yarns into fabric.
There is no dramatic difference in the amount of energy needed to weave fibers into fabric depending on fiber type.[15] The processing is generally the same whether the fiber is nylon, cotton, hemp, wool or polyester: thermal energy required per meter of cloth is 4,500-5,500 Kcal and electrical energy required per meter of cloth is 0.45-0.55 kwh. [16] This translates into huge quantities of fossil fuels – both to create energy directly needed to power the mills, produce heat and steam, and power air conditioners, as well as indirectly to create the many chemicals used in production. In addition, the textile industry has one of the lowest efficiencies in energy utilization because it is largely antiquated.

#######
(1) http://www.usatoday.com/story/news/nation/2013/02/28/climate-change-remaking-america/1917169/
(2) Source: Energy Information Administration, Form EIA:848, “2002 Manufacturing Energy Consumption Survey,” Form EIA-810, “Monthly Refinery Report” (for 2002) and Documentatioin for Emissions of Greenhouse Gases in the United States 2003 (May 2005). http://www.eia.doe.gov/emeu/aer/txt/ptb1204.html
(3) Dev, Vivek, “Carbon Footprint of Textiles”, April 3, 2009, http://www.domain-b.com/environment/20090403_carbon_footprint.html
(4) Rupp, Jurg, “Ecology and Economy in Textile Finishing”, Textile World, Nov/Dec 2008
(5) Rose, Coral, “CO2 Comes Out of the Closet”, GreenBiz.com, September 24, 2007
(6) U.S. Energy Information Administration, “International Energy Annual 2006”, posted Dec 8, 2008.
(7) Many discussions of energy used to produce fabrics or final products made from fabrics (such as clothing) take the “use” phase of the article into consideration when evaluating the carbon footprint. The argument goes that laundering the blouse (or whatever) adds considerably to the final energy tally for natural fibers, while synthetics don’t need as much water to wash nor as many launderings. We do not take this component into consideration because
. it applies only to clothing; even sheets aren’t washed as often as clothing while upholstery is seldom cleaned.
. is biodegradeable detergent used?
. Is the washing machine used a new low water machine? Is the water treated by a municipal facility?
. Synthetics begin to smell if not treated with antimicrobials, raising the energy score.
Indeed, it’s important to evaluate the sponsors of any published studies, because the studies done which evaluate the energy used to manufacture fabrics are often sponsored by organizations which might have an interest in the outcome. Additionally, the data varies quite a bit so we have adopted the values which seem to be agreed upon by most studies.
(8) Ibid.
(9) “Tesco carbon footprint study confirms organic farming is energy efficient, but excludes key climate benefit of organic farming, soil carbon”, Prism Webcast News, April 30, 2008, http://prismwebcastnews.com/2008/04/30/tesco-carbon-footprint-study-confirms-organic-farming%E2%80%99s-energy-efficiency-but-excludes-key-climate-benefit-of-organic-farming-%E2%80%93-soil-carbon/
(10) Fletcher, Kate, Sustainable Fashion and Textiles, Earthscan, 2008, Page 13
(11) “Why Natural Fibers”, FAO, 2009: http://www.naturalfibres2009.org/en/iynf/sustainable.html
(12) Ibid.
(13) Aubert, C. et al., (2009) Organic farming and climate change: major conclusions of the Clermont-Ferrand seminar (2008) [Agriculture biologique et changement climatique : principales conclusions du colloque de Clermont-Ferrand (2008)]. Carrefours de l’Innovation Agronomique 4. Online at
(14) International Trade Centre UNCTAD/WTO and Research Institute of Organic Agriculture (FiBL); Organic Farming and Climate Change; Geneva: ITC, 2007.
(15) 24th session of the FAO Committee on Commodity Problems IGG on Hard Fibers of the United Nations
(16) “Improving profits with energy-efficiency enhancements”, December 2008, Journal for Asia on Textile and Apparel, http://textile.2456.com/eng/epub/n_details.asp?epubiid=4&id=3296

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Climate change and Newtok

26 08 2014

How does this topic relate to the textile industry?   Well, it just so happens that the textile industry is huge – and a huge producer of greenhouse gasses.  The textile industry, according to the U.S. Energy Information Administration, is the 5th largest contributor to CO2 emissions in the United States, after primary metals, nonmetallic mineral products, petroleum and chemicals.  Your textile choices do make a difference – next week we’ll take a look at why.

Newtok is one example of what the United Nations Intergovernmental Panel on Climate Change warns is part of a growing climate change crisis that will displace 150 million people by 2050.

Climate change is impacting Alaska and Arctic areas disproportionately because shiny ice and snow reflect a high proportion of the sun’s energy into space while the exposed rock and water absorb more and more of the sun’s energy, making it even warmer.   Arctic areas, including Alaska, are warming about twice as fast as the rest of the world. In 2012, Arctic sea ice coverage hit the lowest level ever recorded, and by 2040, it is predicted that summer sea ice could be limited to the northern coasts of Greenland and Canada.[1] But the cities and towns of the east coast of the United States are waking up to their own version of climate change – in the form of storm surges from hurricane Sandy. About half of America’s population lives within 50 miles of a coastline.

This video is an Emmy nominated documentary, Melting Point Greenland – winner of the 2013 National Headliners Award First Prize Environmental:

Today, more than 180 native communities in Alaska are facing flooding and losing land as warming temperatures are melting coastal ice shelves and frozen sub-soils, which act as natural barriers to protect villages against summer deluges and ocean storm surges. One of these villages is Newtok, an Eskimo village on the banks of the Ninglick River and home to indigenous Yup’ik Eskimos. The river coils around Newtok on three sides before emptying into the Bering Sea. The river has steadily been eating away at the land, carrying away 100 feet or more in some years, in a process accelerated by climate change.  It is estimated that the local school, on the highest point of land in the village, will be under water by 2017.

There are other changes too: Historically, Newtok would expect snow by October. In early December of 2013, snow had not yet fallen. Residents have told media that geese have been altering migratory patterns that had been unchanged for centuries and moose are migrating into caribou country. Comments Nathan Tom, a Yup’ik villager, “The snow comes in a different timing now. The snow disappears way late. That is making the geese come at the wrong time. Now they are starting to lay their eggs when there is still snow and ice and we can’t go and pick them.  It’s changing a lot. It’s real, global warming, it’s real.” [2]

Permafrost

Newtok may well be the site of some of the planet’s first climate refugees.

“Climate refugee” usually refers to a people displaced from their homes by the impact of a changing climate – although the strict definition of a refugee in international law is more narrow – including people displaced by war, violence or persecution, but not environmental changes.

The first image that usually springs to mind for climate refugees are small tropical islands in the Pacific or of a low-lying delta like those in Bangladesh, where inhabitants have been forced out of their homes by sea-level rise. But given the rapidity of the changes in the Arctic regions, this image is about to become more diverse.

But as with most things these days, the variables are complex: As applied to Newtok, the term “climate refugees” is somewhat ironic, given that the Yup’ik were nomadic by nature, migrating over the permafrost.  In the 1950s the U.S. government told the Yup’ik that their nomadic lifestyle was no longer acceptable, they had to settle in one location so their children could go to school.  The Yup’ik begrudgingly accepted, settling in Kayalavik, a village of sod huts, farther north.

When Alaska became a state in 1959, federal officials began to pressure the Yup’ik to relocate, as the Kayalavik village was harder for supply barges to access.  Eventually the ill-fated decision was made to relocate the tribe to Newtok — a seasonal stopping place for the tribe’s late-summer berry picking.

“The places are often where they are because it was easy to unload the building materials and build the school and the post office there,” said Larry Hartig, who heads the state’s Commission on Environmental Conservation. “But they weren’t the ideal place to be in terms of long-term stability and it’s now creating a lot of problems that are exacerbated by melting permafrost and less of the seasonal sea ice that would form barriers between the winter storms and uplands.”[3]

The U.S. Army Corps of Engineers has estimated that moving Newtok could cost $130 million. Twenty-six other Alaskan villages are in immediate danger, with an additional 60 considered under threat in the next decade, according to the corps. But as the villagers of Newtok are discovering, recognizing the gravity of the threat posed by climate change – and responding in time are two very different matters. Since the first meeting in December 2007, at which the villagers held the first public meeting about the move, little has been done, tethered to a dangerous location by bureaucratic obstacles and lack of funds.

 

 

 

[1] http://wwf.panda.org/what_we_do/where_we_work/arctic/what_we_do/climate/

[2]http://www.dailytech.com/Government+Creates+Global+Warming+Refugee+Crisis+in+Alaska/article31546.htm

[3] http://www.theguardian.com/environment/interactive/2013/may/13/newtok-alaska-climate-change-refugees





Fabric and your carbon footprint

3 10 2013

In considering fabric for your sofa, let’s be altruistic and look at the impact textile production has on global climate change.  (I only use the term altruistic  because many of us don’t equate climate change with our own lives, though there have been several interesting studies of just how the changes will impact us directly, like the one in USA Today that explains that wet regions will be wetter, causing flash flooding;  dry regions will get drier, resulting in drought. And  …  a heat wave that used to occur once every 100 years now happens every five years (1)).

Bill Schorr

Bill Schorr


Although most of the current focus on lightening our carbon footprint revolves around transportation and heating issues, the modest little fabric all around you turns out to be from an industry with a gigantic carbon footprint. The textile industry, according to the U.S. Energy Information Administration, is the 5th largest contributor to CO2 emissions in the United States, after primary metals, nonmetallic mineral products, petroleum and chemicals.[2]  And the US textile industry is small potatoes when compared with some other countries I could mention.  Last week we explained that a typical “quality” sofa  uses about 20 yards of decorative fabric, plus 20 yds of lining fabric, 15 yds of burlap and 10 yds of muslin, for a total of 65 yards of fabric – in one sofa.

The textile industry is huge, and it is a huge producer of greenhouse gasses.  Today’s textile industry is one of the largest sources of greenhouse gasses (GHG’s) on Earth, due to its huge size.[3] In 2008,  annual global textile production was estimated at  60 billion kilograms (KG) of fabric.  The estimated energy and water needed to produce that amount of fabric boggles the mind:

  • 1,074 billion kWh of  electricity  or 132 million metric tons of coal and
  • between 6 – 9  trillion liters of water[4]

Fabrics are the elephant in the room.  They’re all around us  but no one is thinking about them.  We simply overlook fabrics, maybe because they are almost always used as a component in a final product that seems rather innocuous:  sheets, blankets, sofas, curtains, and of course clothing.  Textiles, including clothing,  accounted for about one ton of the 19.8 tons of total CO2 emissions produced by each person in the U.S. in 2006. [5] By contrast, a person in Haiti produced a total of only 0.21 tons of total carbon emissions in 2006.[6]

Your textile choices do make a difference, so it’s vitally important to look beyond thread counts, color and abrasion results.

How do you evaluate the carbon footprint in any fabric?  Look at the “embodied energy’ in the fabric – that is, all of the energy used at each step of the process needed to create that fabric.   Not an easy thing to do!  To estimate the embodied energy in any fabric it’s necessary to add the energy required in two separate fabric production steps:

(1)  Find out what the fabric is made from, because the type of fiber tells you a lot about the energy needed to make the fibers used in the yarn.  The carbon footprint of various fibers varies a lot, so start with the energy required to produce the fiber.

(2) Next, add the energy used to weave those yarns into fabric.  Once any material becomes a “yarn” or “filament”, the amount of energy and conversion process to weave that yarn into a textile is pretty consistent, whether the yarn is wool, cotton,  or synthetic.[7]

Let’s look at #1 first: the energy needed to make the fibers and create the yarn. For ease of comparison we’ll divide the fiber types into “natural” (from plants, animals and less commonly, minerals) and “synthetic” (man made).

For natural fibers you must look at field preparation, planting and field operations (mechanized irrigation, weed control, pest control and fertilizers (manure vs. synthetic chemicals)), harvesting and yields.  Synthetic fertilizer use is a major component of the high cost of conventional agriculture:  making just one ton of nitrogen fertilizer emits nearly 7 tons of CO2 equivalent greenhouse gases.

For synthetics, a crucial fact is that the fibers are made from fossil fuels.   Very high amounts of energy are used in extracting the oil from the ground as well as in the production of the polymers.

A study done by the Stockholm Environment Institute on behalf of the BioRegional Development Group  concludes that the energy used (and therefore the CO2 emitted) to create 1 ton of spun fiber is much higher for synthetics than for hemp or cotton:

KG of CO2 emissions per ton of spun   fiber:
crop cultivation fiber production TOTAL
polyester USA 0.00 9.52 9.52
cotton, conventional, USA 4.20 1.70 5.90
hemp, conventional 1.90 2.15 4.05
cotton, organic, India 2.00 1.80 3.80
cotton, organic, USA 0.90 1.45 2.35

The table above only gives results for polyester; other synthetics have more of an impact:  acrylic is 30% more energy intensive in its production than polyester [8] and nylon is even higher than that.

Not only is the quantity of GHG emissions of concern regarding synthetics, so too are the kinds of gasses produced during production of synthetic fibers.  Nylon, for example, creates emissions of N2O, which is 300 times more damaging than CO2 [9] and which, because of its long life (120 years) can reach the upper atmosphere and deplete the layer of stratospheric ozone, which is an important filter of UV radiation.  In fact, during the 1990s, N2O emissions from a single nylon plant in the UK were thought to have a global warming impact equivalent to more than 3% of the UK’s entire CO2 emissions.[10] A study done for the New Zealand Merino Wool Association shows how much less total energy is required for the production of natural fibers than synthetics:

Embodied   Energy used in production of various fibers:
energy use in   MJ per KG of fiber:
flax fibre   (MAT) 10
cotton 55
wool 63
Viscose 100
Polypropylene 115
Polyester 125
acrylic 175
Nylon 250

SOURCE:  “LCA: New Zealand Merino Wool Total Energy Use”, Barber and Pellow,      http://www.tech.plym.ac.uk/sme/mats324/mats324A9%20NFETE.htm

Natural fibers, in addition to having a smaller carbon footprint in the production of the spun fiber, have many additional  benefits:

  1. being able to be degraded by micro-organisms and composted (improving soil structure); in  this way the fixed CO2 in the fiber will be released and the cycle closed.   Synthetics do not decompose: in landfills they release  heavy metals and other additives into soil and groundwater.       Recycling requires costly separation, while incineration produces  pollutants – in the case of high density polyethylene, 3 tons of CO2 emissions are produced for ever 1 ton of material burnt.[11] Left in the environment, synthetic fibers contribute, for example, to the estimated 640,000 tons of abandoned  fishing nets in the world’s oceans.
  2. sequestering  carbon.  Sequestering carbon is the process through which CO2 from the atmosphere is absorbed by plants through photosynthesis and stored as carbon in biomass (leaves, stems, branches, roots, etc.) and soils.       Jute, for example, absorbs 2.4 tons of carbon per ton of dry fiber.[12]

Substituting organic fibers for conventionally grown fibers is not just a little better – but lots better in all respects:

  • uses less energy for production,
  • emits fewer greenhouse gases
  • and supports organic farming (which has myriad environmental, social and health benefits).

A study published by Innovations Agronomiques (2009) found that 43% less GHG are emitted per unit area under organic agriculture than under conventional agriculture.[13] A study done by Dr. David Pimentel of Cornell University found that organic farming systems used just 63% of the energy required by conventional farming systems, largely because of the massive amounts of energy requirements needed to synthesize nitrogen fertilizers. Further it was found in controlled long term trials that organic farming adds between 100-400kg of carbon per hectare to the soil each year, compared to non-organic farming.  When this stored carbon is included in the carbon footprint, it reduces the total GHG even further.[14] The key lies in the handling of organic matter (OM): because soil organic matter is primarily carbon, increases in soil OM levels will be directly correlated with carbon sequestration. While conventional farming typically depletes soil OM, organic farming builds it through the use of composted animal manures and cover crops.

Taking it one step further beyond the energy inputs we’re looking at, which help to mitigate climate change, organic farming helps to ensure other environmental and social goals:

  • eliminates the use of synthetic fertilizers, pesticides and genetically modified organisims      (GMOs) which is  an improvement in human health and agrobiodiversity
  • conserves water  (making the soil more friable so rainwater is absorbed better – lessening      irrigation requirements and erosion)
  • ensures sustained  biodiversity
  • and compared to forests, agricultural soils may be a more secure sink for atmospheric      carbon, since they are not vulnerable to logging and wildfire.

Organic agriculture is an undervalued and underestimated climate change tool that could be one of the most powerful strategies in the fight against global warming, according to Paul Hepperly, Rodale Institute Research Manager. The Rodale Institute Farming Systems Trial (FST) soil carbon data (which covers 30 years)  provides convincing evidence that improved global terrestrial stewardship–specifically including regenerative organic agricultural practices–can be the most effective currently available strategy for mitigating CO2 emissions.

At the fiber level it is clear that synthetics have a much bigger footprint than does any natural fiber, including wool or conventionally produced cotton.   So in terms of the carbon footprint at the fiber level, any natural fiber beats any synthetic – at this point in time.   Best of all is an organic natural fiber.

And next let’s look at #2, the energy needed to weave those yarns into fabric.

There is no dramatic difference in the amount of energy needed to weave fibers into fabric depending on fiber type.[15] The processing is generally the same whether the fiber is nylon, cotton, hemp, wool or polyester:   thermal energy required per meter of cloth is 4,500-5,500 Kcal and electrical energy required per meter of cloth is 0.45-0.55 kwh. [16] This translates into huge quantities of fossil fuels  –  both to create energy directly needed to power the mills, produce heat and steam, and power air conditioners, as well as indirectly to create the many chemicals used in production.  In addition, the textile industry has one of the lowest efficiencies in energy utilization because it is largely antiquated.

(1)    http://www.usatoday.com/story/news/nation/2013/02/28/climate-change-remaking-america/1917169/

(2)    Source: Energy Information Administration, Form EIA:848, “2002 Manufacturing Energy Consumption Survey,” Form EIA-810, “Monthly Refinery Report” (for 2002) and Documentatioin for Emissions of Greenhouse Gases in the United States 2003 (May 2005). http://www.eia.doe.gov/emeu/aer/txt/ptb1204.html

(3)    Dev, Vivek, “Carbon Footprint of Textiles”, April 3, 2009, http://www.domain-b.com/environment/20090403_carbon_footprint.html

(4)    Rupp, Jurg, “Ecology and Economy in Textile Finishing”,  Textile World,  Nov/Dec 2008

(5)    Rose, Coral, “CO2 Comes Out of the Closet”,  GreenBiz.com, September 24, 2007

(6)     U.S. Energy Information Administration, “International Energy Annual 2006”, posted Dec 8, 2008.

(7)    Many discussions of energy used to produce fabrics or final products made from fabrics (such as clothing) take the “use” phase of the article into consideration when evaluating the carbon footprint.  The argument goes that laundering the blouse (or whatever) adds considerably to the final energy tally for natural fibers, while synthetics don’t need as much water to wash nor as many launderings.  We do not take this component into consideration because

  1. it applies only to clothing; even sheets aren’t washed as often as clothing while upholstery is seldom cleaned.
  2. is biodegradeable detergent used?
  3. Is the washing machine used a new low water machine?  Is the water treated by a municipal facility?
  4. Synthetics begin to smell if not treated with antimicrobials, raising the energy score.

Indeed, it’s important to evaluate the sponsors of any published studies, because the studies done which evaluate the energy used to manufacture fabrics are often sponsored by organizations which might have an interest in the outcome.  Additionally, the data varies quite a bit so we have adopted the values which seem to be agreed upon by most studies.

(8)     Ibid.

(9)    “Tesco carbon footprint study confirms organic farming is energy efficient, but excludes key climate benefit of organic farming, soil carbon”, Prism Webcast News, April 30, 2008, http://prismwebcastnews.com/2008/04/30/tesco-carbon-footprint-study-confirms-organic-farming%E2%80%99s-energy-efficiency-but-excludes-key-climate-benefit-of-organic-farming-%E2%80%93-soil-carbon/

(10)  Fletcher, Kate, Sustainable Fashion and Textiles,  Earthscan, 2008,  Page 13

(11) “Why Natural Fibers”, FAO, 2009: http://www.naturalfibres2009.org/en/iynf/sustainable.html

(12)  Ibid.

(13) Aubert, C. et al.,  (2009) Organic farming and climate change: major conclusions of the Clermont-Ferrand seminar (2008) [Agriculture biologique et changement climatique : principales conclusions du colloque de Clermont-Ferrand (2008)]. Carrefours de l’Innovation Agronomique 4. Online at <http://www.inra.fr/ciag/revue_innovations_agronomiques/volume_4_janvier_2009>

(14) International Trade Centre UNCTAD/WTO and Research Institute of Organic Agriculture (FiBL);    Organic Farming and Climate Change; Geneva: ITC, 2007.

(15) 24th session of the FAO Committee on Commodity Problems IGG on Hard Fibers of the United Nations

(16)  “Improving profits with energy-efficiency enhancements”, December 2008,  Journal for Asia on Textile and Apparel,  http://textile.2456.com/eng/epub/n_details.asp?epubiid=4&id=3296





Climate change and extreme weather

23 04 2012

I just saw this powerful video based on a recent editorial by Bill McKibben  in the Washington Post on May 23, 2011.   Narritation is  by Stephen Thomson of Plomomedia.com, who accompanies the piece with striking footage of the events Bill wrote about.





Estimating the carbon footprint of a fabric

19 01 2011

We published this blog almost two years ago, but the concepts haven’t changed and we think it’s very important.   So here it is again:

Although most of the current focus on lightening our carbon footprint revolves around transportation and heating issues, the modest little fabric all around you turns out to be from an industry with a gigantic carbon footprint. The textile industry, according to the U.S. Energy Information Administration, is the 5th largest contributor to CO2 emissions in the United States, after primary metals, nonmetallic mineral products, petroleum and chemicals.[1]

The textile industry is huge, and it is a huge producer of greenhouse gasses.  Today’s textile industry is one of the largest sources of greenhouse gasses (GHG’s) on Earth, due to its huge size.[2] In 2008,  annual global textile production was estimated at  60 billion kilograms (KG) of fabric.  The estimated energy and water needed to produce that amount of fabric boggles the mind:

  • 1,074 billion kWh of electricity  or 132 million metric tons of coal and
  • between 6 – 9 trillion liters of water[3]

Fabrics are the elephant in the room.  They’re all around us  but no one is thinking about them.  We simply overlook fabrics, maybe because they are almost always used as a component in a final product that seems rather innocuous:  sheets, blankets, sofas, curtains, and of course clothing.  Textiles, including clothing,  accounted for about one ton of the 19.8 tons of total CO2 emissions produced by each person in the U.S. in 2006. [4] By contrast, a person in Haiti produced a total of only 0.21 tons of total carbon emissions in 2006.[5]

Your textile choices do make a difference, so it’s vitally important to look beyond thread counts, color and abrasion results.

How do you evaluate the carbon footprint in any fabric?  Look at the “embodied energy’ in the fabric – that is, all of the energy used at each step of the process needed to create that fabric.  To estimate the embodied energy in any fabric it’s necessary to add the energy required in two separate fabric production steps:

(1)  Find out what the fabric is made from, because the type of fiber tells you a lot about the energy needed to make the fibers used in the yarn.  The carbon footprint of various fibers varies a lot, so start with the energy required to produce the fiber.

(2) Next, add the energy used to weave those yarns into fabric.  Once any material becomes a “yarn” or “filament”, the amount of energy and conversion process to weave that yarn into a textile is pretty consistent, whether the yarn is wool, cotton, nylon or polyester.[6]

Let’s look at #1 first: the energy needed to make the fibers and create the yarn. For ease of comparison we’ll divide the fiber types into “natural” (from plants, animals and less commonly, minerals) and “synthetic” (man made).

For natural fibers you must look at field preparation, planting and field operations (mechanized irrigation, weed control, pest control and fertilizers (manure vs. synthetic chemicals)), harvesting and yields.  Synthetic fertilizer use is a major component of the high cost of conventional agriculture:  making just one ton of nitrogen fertilizer emits nearly 7 tons of CO2 equivalent greenhouse gases.

For synthetics, a crucial fact is that the fibers are made from fossil fuels.   Very high amounts of energy are used in extracting the oil from the ground as well as in the production of the polymers.

A study done by the Stockholm Environment Institute on behalf of the BioRegional Development Group  concludes that the energy used (and therefore the CO2 emitted) to create 1 ton of spun fiber is much higher for synthetics than for hemp or cotton:

KG of CO2 emissions per ton of spun fiber:
crop cultivation fiber production TOTAL
polyester USA 0.00 9.52 9.52
cotton, conventional, USA 4.20 1.70 5.90
hemp, conventional 1.90 2.15 4.05
cotton, organic, India 2.00 1.80 3.80
cotton, organic, USA 0.90 1.45 2.35

The table above only gives results for polyester; other synthetics have more of an impact:  acrylic is 30% more energy intensive in its production than polyester [7] and nylon is even higher than that.

Not only is the quantity of GHG emissions of concern regarding synthetics, so too are the kinds of gasses produced during production of synthetic fibers.  Nylon, for example, creates emissions of N2O, which is 300 times more damaging than CO2 [8] and which, because of its long life (120 years) can reach the upper atmosphere and deplete the layer of stratospheric ozone, which is an important filter of UV radiation.  In fact, during the 1990s, N2O emissions from a single nylon plant in the UK were thought to have a global warming impact equivalent to more than 3% of the UK’s entire CO2 emissions.[9] A study done for the New Zealand Merino Wool Association shows how much less total energy is required for the production of natural fibers than synthetics:

Embodied Energy used in production of various fibers:
energy use in MJ per KG of fiber:
flax fibre (MAT) 10
cotton 55
wool 63
Viscose 100
Polypropylene 115
Polyester 125
acrylic 175
Nylon 250

SOURCE:  “LCA: New Zealand Merino Wool Total Energy Use”, Barber and Pellow,      http://www.tech.plym.ac.uk/sme/mats324/mats324A9%20NFETE.htm

Natural fibers, in addition to having a smaller carbon footprint in the production of the spun fiber, have many additional  benefits:

  1. being able to be degraded by micro-organisms and composted (improving soil structure); in this way the fixed CO2 in the fiber will be released and the cycle closed.   Synthetics do not decompose: in landfills they release heavy metals and other additives into soil and groundwater.  Recycling requires costly separation, while incineration produces pollutants – in the case of high density polyethylene, 3 tons of CO2 emissions are produced for ever 1 ton of material burnt.[10] Left in the environment, synthetic fibers contribute, for example, to the estimated 640,000 tons of abandoned fishing nets in the world’s oceans.
  2. sequestering carbon.  Sequestering carbon is the process through which CO2 from the atmosphere is absorbed by plants through photosynthesis and stored as carbon in biomass (leaves, stems, branches, roots, etc.) and soils.  Jute, for example, absorbs 2.4 tons of carbon per ton of dry fiber.[11]

Substituting organic fibers for conventionally grown fibers is not just a little better – but lots better in all respects:  uses less energy for production, emits fewer greenhouse gases and supports organic farming (which has myriad environmental, social and health benefits).  A study published by Innovations Agronomiques (2009) found that 43% less GHG are emitted per unit area under organic agriculture than under conventional agriculture.[12] A study done by Dr. David Pimentel of Cornell University found that organic farming systems used just 63% of the energy required by conventional farming systems, largely because of the massive amounts of energy requirements needed to synthesize nitrogen fertilizers. Further it was found in controlled long term trials that organic farming adds between 100-400kg of carbon per hectare to the soil each year, compared to non-organic farming.  When this stored carbon is included in the carbon footprint, it reduces the total GHG even further.[13] The key lies in the handling of organic matter (OM): because soil organic matter is primarily carbon, increases in soil OM levels will be directly correlated with carbon sequestration. While conventional farming typically depletes soil OM, organic farming builds it through the use of composted animal manures and cover crops.

Taking it one step further beyond the energy inputs we’re looking at, which help to mitigate climate change, organic farming helps to ensure other environmental and social goals:

  • eliminates the use of synthetic fertilizers, pesticides and genetically modified organisims (GMOs) which is  an improvement in human health and agrobiodiversity
  • conserves water (making the soil more friable so rainwater is absorbed better – lessening irrigation requirements and erosion)
  • ensures sustained biodiversity
  • and compared to forests, agricultural soils may be a more secure sink for atmospheric carbon, since they are not vulnerable to logging and wildfire.

Organic agriculture is an undervalued and underestimated climate change tool that could be one of the most powerful strategies in the fight against global warming, according to Paul Hepperly, Rodale Institute Research Manager. The Rodale Institute Farming Systems Trial (FST) soil carbon data (which covers 30 years)  provides convincing evidence that improved global terrestrial stewardship–specifically including regenerative organic agricultural practices–can be the most effective currently available strategy for mitigating CO2 emissions.

At the fiber level it is clear that synthetics have a much bigger footprint than does any natural fiber, including wool or conventionally produced cotton.   So in terms of the carbon footprint at the fiber level, any natural fiber beats any synthetic – at this point in time.   Best of all is an organic natural fiber.

And next let’s look at #2, the energy needed to weave those yarns into fabric.

There is no dramatic difference in the amount of energy needed to weave fibers into fabric depending on fiber type.[14] The processing is generally the same whether the fiber is nylon, cotton, hemp, wool or polyester:   thermal energy required per meter of cloth is 4,500-5,500 Kcal and electrical energy required per meter of cloth is 0.45-0.55 kwh. [15] This translates into huge quantities of fossil fuels  –  both to create energy directly needed to power the mills, produce heat and steam, and power air conditioners, as well as indirectly to create the many chemicals used in production.  In addition, the textile industry has one of the lowest efficiencies in energy utilization because it is largely antiquated.

But there is an additional dimension to consider during processing:  environmental pollution.  Conventional textile processing is highly polluting:

  • Up to 2000 chemicals are used in textile processing, many of them known to be harmful to human (and animal) health.   Some of these chemicals evaporate, some are dissolved in treatment water which is discharged to our environment, and some are residual in the fabric, to be brought into our homes (where, with use, tiny bits abrade and you ingest or otherwise breathe them in).  A whole list of the most commonly used chemicals in fabric production are linked to human health problems that vary from annoying to profound.
  • The application of these chemicals uses copious amounts of water. In fact, the textile industry is the #1 industrial polluter of fresh water on the planet.[16] These wastewaters are discharged (largely untreated) into our groundwater with a high pH and temperature as well as chemical load.

Concerns in the United States continue to mount about the safety of textiles and apparel products used by U.S. consumers.  Philadelphia University has formed a new Institute for Textile and Apparel Product Safety, where they are busy analyzing clothing and textiles for a variety of toxins.  Currently, there are few regulatory standards for clothing and textiles in the United States.  Many European countries,  as well as Japan and Australia, have much stricter restrictions on the use of chemicals in textiles and apparel than does the United States, and these world regulations will certainly impact world production.

There is a bright spot in all of this:  an alternative to conventional textile processing does exist.  The new Global Organic Textile Standard (GOTS) is a  tool for an international common understanding of environmentally friendly production systems and social accountability in the textile sector; it covers the production, processing, manufacturing, packaging, labeling, exportation, importation and distribution of all natural fibers; that means, specifically, for example:  use of certified organic fibers, prohibition of all GMOs and their derivatives; and prohibition of a long list of synthetic chemicals (for example: formaldehyde and aromatic solvents are prohibited; dyestuffs must meet strict requirements (such as threshold limits for heavy metals, no  AZO colorants or aromatic amines) and PVC cannot be used for packaging).

A fabric which is produced to the GOTS standards is more than just the fabric:

It’s a promise to keep our air and water pure and our soils renewed; it’s a fabric which will not cause harm to you or your descendants.  Even though a synthetic fiber cannot be certified to  GOTS, the synthetic mill could adopt the same production standards and apply them.   So for step #2, the weaving of the fiber into a fabric, the best choice is to buy a GOTS certified fabric or to apply as nearly as possible the GOTS parameters.

At this point in time, given the technology we have now, an organic fiber fabric, processed to GOTS standards, is (without a doubt) the safest, most responsible choice possible in terms of both stewardship of the earth, preserving health and limiting toxicity load to humans and animals, and reducing carbon footprint – and emphasizing rudimentary social justice issues such as no child labor.

And that would be the end of our argument, if it were not for this sad fact:  there are no natural fiber fabrics made in the United States which are certified to the Global Organic Textile Standard (GOTS).  The industry has, we feel, been flat footed in applying these new GOTS standards.  With the specter of the collapse of the U.S. auto industry looming large, it seems that the U.S. textile industry would do well to heed what seems to be the global tide of public opinion that better production methods, certified by third parties, are the way to market fabrics in the 21st Century.


[1] Source: Energy Information Administration, Form EIA:848, “2002 Manufacturing Energy Consumption Survey,” Form EIA-810, “Monthly Refinery Report” (for 2002) and Documentatioin for Emissions of Greenhouse Gases in the United States 2003 (May 2005). http://www.eia.doe.gov/emeu/aer/txt/ptb1204.html

[2] Dev, Vivek, “Carbon Footprint of Textiles”, April 3, 2009, http://www.domain-b.com/environment/20090403_carbon_footprint.html

[3] Rupp, Jurg, “Ecology and Economy in Textile Finishing”,  Textile World,  Nov/Dec 2008

[4] Rose, Coral, “CO2 Comes Out of the Closet”,  GreenBiz.com, September 24, 2007

[5] U.S. Energy Information Administration, “International Energy Annual 2006”, posted Dec 8, 2008.

[6] Many discussions of energy used to produce fabrics or final products made from fabrics (such as clothing) take the “use” phase of the article into consideration when evaluating the carbon footprint.  The argument goes that laundering the blouse (or whatever) adds considerably to the final energy tally for natural fibers, while synthetics don’t need as much water to wash nor as many launderings.  We do not take this component into consideration because

  • it applies only to clothing; even sheets aren’t washed as often as clothing while upholstery is seldom cleaned.
  • is biodegradeable detergent used?
  • Is the washing machine used a new low water machine?  Is the water treated by a municipal facility?
  • Synthetics begin to smell if not treated with antimicrobials, raising the energy score.

Indeed, it’s important to evaluate the sponsors of any published studies, because the studies done which evaluate the energy used to manufacture fabrics are often sponsored by organizations which might have an interest in the outcome.  Additionally, the data varies quite a bit so we have adopted the values which seem to be agreed upon by most studies.

[7] Ibid.

[8] “Tesco carbon footprint study confirms organic farming is energy efficient, but excludes key climate benefit of organic farming, soil carbon”, Prism Webcast News, April 30, 2008, http://prismwebcastnews.com/2008/04/30/tesco-carbon-footprint-study-confirms-organic-farming%E2%80%99s-energy-efficiency-but-excludes-key-climate-benefit-of-organic-farming-%E2%80%93-soil-carbon/

[9] Fletcher, Kate, Sustainable Fashion and Textiles,  Earthscan, 2008,  Page 13

[10] “Why Natural Fibers”, FAO, 2009: http://www.naturalfibres2009.org/en/iynf/sustainable.html

[11] Ibid.

[12] Aubert, C. et al.,  (2009) Organic farming and climate change: major conclusions of the Clermont-Ferrand seminar (2008) [Agriculture biologique et changement climatique : principales conclusions du colloque de Clermont-Ferrand (2008)]. Carrefours de l’Innovation Agronomique 4. Online at <http://www.inra.fr/ciag/revue_innovations_agronomiques/volume_4_janvier_2009>

[13] International Trade Centre UNCTAD/WTO and Research Institute of Organic Agriculture (FiBL);    Organic Farming and Climate Change; Geneva: ITC, 2007.

[14] 24th session of the FAO Committee on Commodity Problems IGG on Hard Fibers of the United Nations

[15] “Improving profits with energy-efficiency enhancements”, December 2008,  Journal for Asia on Textile and Apparel,  http://textile.2456.com/eng/epub/n_details.asp?epubiid=4&id=3296

[16] Cooper, Peter, “Clearer Communication,” Ecotextile News, May 2007.





What kind of wood is best for your new “green” sofa?

13 01 2010

From last week’s post, I explained that most people who want to buy a “green” sofa look at two major components:  the wood and the foam.  But our blog post demonstrated how your fabric choice can trump the embodied energy of both these components – in other words, depending on which fiber you choose, fabric can be almost  triple  the embodied energy of wood and foam combined.  But embodied energy is a complicated concept,  and difficult to figure out without lots of time on your hands.  Our next steps will be to examine other issues associated with each of these choices – remember the ecosystem is a vast interconnected network, and we can’t pull any one component out and evaluate it out of context.   Each week we’ll look at one of the components  –  this week it’s wood.

Everybody knows that wood, a natural product, comes from trees,  but it’s important to know much more than whether the wood is cherry or mahagony – it’s also important to know that the wood did not come from an endangered forest (such as a tropical forest, or old growth boreal forests) – and preferably that the wood came from a forest that is sustainably managed.   Well managed forests provide clean water, homes for wildlife, and they help stabilize the climate. As the National Resources Defense Council says:

“Forests are more than a symbolic ideal of wilderness, more than quiet places to enjoy nature. Forest ecosystems — trees, soil, undergrowth, all living things in a forest — are critical to maintaining life on earth. Forests help us breathe by creating oxygen and filtering pollutants from the air, and help stabilize the global climate by absorbing carbon dioxide, the main greenhouse gas. They soak up rainfall like giant sponges, preventing floods and purifying water that we drink. They provide habitat for 90 percent of the plant and animal species that live on land, as well as homelands for many of the earth’s last remaining indigenous cultures. Forests are commercially important, too; they yield valuable resources like wood, rubber and medicinal plants, including plants used to create cancer drugs. Harvesting these resources provides employment for local communities.  Healthy forests are a critical part of the web of life. Protecting the earth’s remaining forest cover is now an urgent task.”

Unsustainable logging, agricultural expansion, and other practices threaten many forests’ existence.  Indeed, half of the Earth’s original forest cover has been lost, mostly in the last three decades.

According to the World Resources Institute (WRI), only 20% of Earth’s original forests remain today in areas large enough to maintain their full complement of biological and habitat diversity and ecological functions.[2]

More than 20% of  worldwide  carbon emissions come from the loss of forests[1], even after counting all the carbon captured by forest growth.  

A sustainable forest is a forest that is carefully managed so that as trees are felled they are replaced with seedlings that eventually grow into mature trees. This is a carefully and skilfully managed system. The forest is a working environment, producing wood products such as wood pulp for the paper / card industry and wood based materials for furniture manufacture and the construction industry. Great care is taken to ensure the safety of wildlife and to preserve the natural environment.

Forest certification is like organic labeling for forest products:  it is intended as a seal of approval — a means of notifying consumers that a wood or paper product comes from forests managed in accordance with strict environmental and social standards. For example, a person shopping for flooring or furniture would seek a certified forest product to be sure that the wood was harvested in a sustainable manner from a healthy forest, and not clearcut from a tropical rainforest or the ancestral homelands of forest-dependent indigenous people.

Choosing products from forests certified by the independent Forest Stewardship Council (FSC) can be an important part of using wood and paper more sustainably.  The FSC, based in Bonn, Germany,  brought together three seemingly antagonistic groups: environmentalists, industrialists and social activists. Its mission and governance reflects the balance between these original constituents in that FSC seeks to promote environmentally appropriate, socially beneficial and economically viable management of the world’s forests. Each is given equal weight.   Formed in 1993, the FSC has established a set of international forest management standards; it also accredits and monitors certification organizations that evaluate on-the-ground compliance with these standards in forests around the world.  Today nearly 125 million acres of forest are FSC certified in 76 countries.

But not all certification programs are credible. Spurred by the success of the FSC and consumer demand for certified products, at least eight other forest certification programs have formed internationally, such as the American Tree Farm System (ATFS), the Canadian Standards Association (CSA) forest certification, and the European Programme for the Endorsement of Forest Certification schemes (PEFC).  However, these programs are often backed by timber interests and set weak standards for forest management that allow destructive and business-as-usual forestry practices.

The most well known of these alternative certifications is the Sustainable Forestry Initiative (SFI).   Created in 1995 by the American Forest & Paper Association (AF&PA), an industry group, SFI was originally created  as a public relations program,  but it now represents itself as a certification system.

There are significant differences between the two systems.  FSC’s conservation standards tend to be more concrete, while SFI’s are vaguer targets with fewer measurable requirements. Here is what is allowed under the SFI standard:

  • Allows large clearcuts
  • Allows use of toxic chemicals
  • Allows conversion of old-growth forests to tree plantations
  • Allows use of genetically modified trees
  • Allows logging close to rivers and streams that harms water supplies

By comparison,  the FSC:

  • Establishes meaningful limits on large-scale clearcutting; harvesting rates and clearing sizes can not exceed a forest’s natural capacity to regenerate.
  • Prohibits the most toxic chemicals and encourages forest practices that reduce chemical use.
  • Does not allow the conversion of old-growth forests to tree plantations, and has guidelines for environmental management of existing plantations.
  • Prohibits use of genetically modified trees and other genetically modified organisms (GMOs).
  • Requires management and monitoring of natural forest attributes, including the water supply; for example,  springs and streams are monitored to detect any signs of pollutants or vegetative disturbance.
  • Requires protection measures for rare old growth in certified forests, and consistently requires protection of other high conservation value forests.
  • Prohibits replacement of forests by sprawl and other non-forest land uses.[4]

Certifiers also grant “chain-of-custody” certifications to companies that manufacture and sell products made out of certified wood. A chain-of-custody assessment tracks wood from the forest through milling and manufacturing to the point of sale. This annual assessment ensures that products sold as certified actually originate in certified forests.

Nearly a decade and a half after the establishment of these two certification bodies, there is a battle between FSC and SFI which is crescendoing in a showdown over recognition in the LEED system, the preeminent green building standard in the U.S.  Since its inception in 2000, LEED (Leadership in Energy and Environmental Design) has recognized only lumber with the FSC label as responsibly sourced. Up until now, credits such as MR 7 – Certified Wood, has awarded points based on the usage of FSC certified wood only (NOTE:  this is not specific to wood;  LEED  only awards points automatically  for Indoor Air Quality to products which are GreenGuard certified) .  Intense timber industry pressure has led the U.S. Green Building Council (USGBC), LEED’s parent,  to evaluate the certified wood credit in LEED, which has been FSC exclusive since inception, and determine whether other certification systems, such as the industry-driven Sustainable Forestry Initiative, should be given credits as well.  As a result, the USGBC  is currently writing new rules about wood-product sourcing.

This would replace the simple FSC monopoly with generalized benchmarks for evaluating systems claiming to enforce sustainable forestry and open up considerations for other “green” wood labeling systems.

Opponents of this action feel that it opens the door to destructive forestry practices under the guise of “green” –  and  to pass off status-quo business practices as environmentally friendly.  One of the leading arguments for loosening the wood credit — and thus lowering the bar for the standards governing the origins of the wood — is that the FSC system doesn’t have enough supply to meet demand.  To which the rejoinder is that the volume of SFI wood speaks to laxness of standards.  SFI contends that since only 10% of the world’s forests are certified sustainable, the important fact to concern us should be to work on the problems plaguing the remaining 90%.

The battle is heating up:  it was reported as recently as the 22nd of December, 2009, that a law suit was filed on behalf of a group calling itself the “Coalition for Fair Forest Certification” against the Forest Stewardship Council (FSC) alleging unfair and deceptive trade practices.  It is believed that the Coalition members are also members of the Sustainable Forestry Initiative.   (see http://greensource.construction.com/news/2009/091222Deception.asp )

We can only hope that USGBC’s certification decision takes place with keen regard to the organization’s guiding principles — high-minded values like “reconciling humanity with nature” and “fostering social equity.” It’s a critical decision that has the potential to help preserve forests by providing incentives for great management and cooling the planet down at the same time.

Once you’ve established whether the wood is from a sustainably managed forest, it’s also important to note whether the wood products in the sofa are composites.  Composites are typically made of wood and adhesive – examples of such composites are laminated veneer lumber (LVL), Medium density fiberboard (MDF), Plywood, and Glue Laminated Beams (Glulam).  Because these products are glued together using phenol formaldehyde resins, there is concern with formaldehyde emissions.  In fact, a bill  introduced in September, 2009, in the U.S.  Senate would limit the amount of allowable formaldehyde emissions in composite wood products.   In addition, the embodied energy in these products is typically higher than that for solid timber.  Based on a  study done by the    School of Engineering, University of Plymouth in the United Kingdom,
the embodied energy in air dried sawn hardwood (0.5 MJ/kg) is considerably less than that of glulam (4.6 to 11.0 MJ/kg)


[1] Van der Werf, G.R, et al, “CO2 Emissions from Forest Loss”, Nature Geoscience, November 1, 2009, pp 737-38.

[2] “Guidelines for Avoiding Wood from Endangered Forests”, http://www.rainforestrelief.org/documents/Guidelines.pdf

[3] Examples of SFI certified companies’ harmful practices are at http://www.dontbuysfi.com.

[4] iGreenBuild.com:  Forest Certification:  Sustainable Forestry or Misleading Marketing?  http://credibleforestcertification.org/fileadmin/materials/old_growth/dont_buy_sfi/sfi_facts/2_-_Still_Not_Equal_igreenbuild.pdf





Embodied energy needed to make one sofa

6 01 2010

I just read the article by Team Treehugger on Planet Green on what to look for if you’re interested in green furniture. And sure enough, they talked about the wood (certified sustainable – but without any  explanation about why Forest Stewardship Council (FSC) certified wood should be a conscientious consumers only choice), reclaimed materials, design for disassembly, something they call “low toxicity furniture”, buying vintage…the usual suspects.  Not once did they mention your fabric choice.

Of course, all these are important considerations and like most green choices, there are tradeoffs and degrees of green.  But if we look at the carbon footprint of an average upholstered sofa and see what kind of energy requirements are needed to produce that sofa, we can show you how your fabric choice is the most important choice you can make in terms of embodied energy.  Later on (next week’s post) we’ll take a look at what your choices mean in terms of toxicity and environmental degredation.

These are the components of a typical sofa:

  • Wood
  • Foam (most commonly) or other cushion filling
  • Fabric
  • Miscellaneous:
    • Glue
    • Varnish/paint
    • Metal springs
    • Thread
    • Jute webbing
    • Twine
  1. WOOD: A 6 foot sofa uses about 32 board feet of lumber (1) .  For kiln dried maple, the embodied energy for 32 board feet is 278 MJ.  But if we’re looking at a less expensive sofa which uses glulam (a laminated lumber product), the embodied energy goes up to 403 MJ.
  2. FOAM:  Assume 12 cubic feet of foam is used, with a density of 4 lbs. per cubic foot (this is considered a good weight for foam);  the total weight of the foam used is 48 lbs. The new buzz word for companies making upholstered furniture is “soy based foam” (an oxymoron which we’ll expose in next week’s post), which is touted to be “green” because (among other things)  it uses less energy to produce.  Based on Cargill Dow’s own web site for the BiOH polyol which is the basis for this new product, soy based foam uses up to 60% less energy than does conventional polyurethane foams.   Companies which advertise foam made with 20% soy based polyols  use 1888 MJ of energy to create 12 cubic feet of foam, versus 2027 MJ if conventional polyurethane was used.  For our purposes of comparison, we’ll use the lower energy amount of 1888 MJ and give the manufacturers the benefit of the doubt.
  3. FABRIC:  Did you know that the decorative fabric you choose to upholster your couch is not the only fabric used in the construction?  Here’s the breakdown for fabric needed for one sofa:
    1. 25 yards of decorative fabric
    2. 20 yards of lining fabric
    3. 15 yards of burlap
    4. 10 yards of muslin

TOTAL amount of fabric needed for one sofa:  70 yards!

Using data from various sources (see footnotes below), the amount of energy needed to produce the fabric varies between 291 MJ (if all components were made of hemp, which has the lowest embodied energy) and 7598 MJ (if all components were made of  nylon, which has the highest embodied energy requirements).  If we choose the most commonly used fibers for each fabric component, the total energy used is 2712 MJ:

fiber Embodied energy in MJ
25 yards decorative fabric/ 22 oz lin. yd = 34.0 lbs polyester 1953
20 yards lining fabric / 15 oz linear yard = 19 lbs cotton 469
15 yards burlap / 10 oz linear yard = 9.4 lbs hemp 41
10 yards muslin / 7 oz linear yard = 4.4 lbs polyester 249
TOTAL: 2712

I could not find any LCA studies which included the various items under “Miscellaneous” so for this example we are discounting that category.  It might very well impact results, so if anyone knows of a study which addresses these items please let us know!

So  we’re looking at three components (wood, foam and fabric), only two of which most people seem to think are important in terms of upholstered furniture manufacture.  But if we put the results in a table, it’s suddenly very clear that fabric is the most important consideration – at least in terms of embodied energy:

Embodied energy in MJ
WOOD: 32 board feet, kiln dried maple 278
FOAM: 12 cubic feet, 20% bio-based polyol 1888
SUBTOTAL wood and foam: 2166
FABRIC: FIBER:
25 yards uphl  fabric/ 22 oz lin. yd = 34.0 lbs polyester 1953
20 yards lining fabric / 15 oz linear yard = 19 lbs cotton 469
15 yards burlap / 10 oz linear yard = 9.4 lbs hemp 41
10 yards muslin / 7 oz linear yard = 4.4 lbs polyester 249
SUBTOTAL, fabric: 2712

If we were to use the most egregious fabric choices (nylon), the subtotal  for the energy used to create just the fabric would be 7598 MJ – more than three times the energy needed to produce the wood and foam!  This is just another instance where  fabric, a forgotten component,  makes a profound impact.

(1)  From: “Life Cycle Analysis of Wood Products: Cradle to Gate LCIof residential wood building material”, Wood and Fiber Science, 37 Corrim Special Issue, 2005, pp. 18 – 29.

(2)  Data for embodied energy in fabrics:

“Ecological Footprint and Water Analysis of Cotton, Hemp and Polyester”, Stockholm Environment Institute, 2005

Composites Design and Manufacture, School of Engineering, University of Plymouth UK, 2008, http://www.tech.plym.ac.uk/sme/mats324/mats324A9%20NFETE.htm

Study: “LCA: New Zealand Merino Wool Total Energy Use”, Barber and Pellow.