Friday, July 09, 2021

A Road Map for Natural Capitalism

by
Amory B. Lovins,
L. Hunter Lovins, and
Paul Hawken
From the Harvard Buisness Magazine (July–August 2007)


Summary. Reprint: R0707P No one would run a business without accounting for its capital outlays. Yet in 1999, when this article was originally published, most companies overlooked one major capital component—the value of the earth’s ecosystem services. It was a...more


Editor’s Note: The unsettling warning this article delivers has only grown more urgent since 1999, when it first appeared in HBR. But the value here lies not so much in the alarm that sounds as in the vivid and sometimes startling reconceptualization of how we think about the environment and economic value.

BLOG EDITORS NOTE 
IT IS NOW THE FIRST DECADE OF THE CLIMATE CRISIS 2021

The value to the economy of the services provided by the earth’s ecosystem—as distinct from the value of the natural resources we extract from it—runs into tens of trillions of dollars annually, say the authors. They provide numerous examples of companies that leverage this insight in the interest of their own bottom lines and the health of the environment as a whole.

On September 16, 1991, a small group of scientists was sealed inside Biosphere II, a glittering 3.2-acre glass and metal dome in Oracle, Arizona. Two years later, when the radical attempt to replicate the earth’s main ecosystems in miniature ended, the engineered environment was dying. The gaunt researchers had survived only because fresh air had been pumped in. Despite $200 million worth of elaborate equipment, Biosphere II had failed to generate breathable air, drinkable water, and adequate food for just eight people. Yet Biosphere I, the planet we all inhabit, effortlessly performs those tasks every day for 6 billion of us.

Disturbingly, Biosphere I is now itself at risk. The earth’s ability to sustain life, and therefore economic activity, is threatened by the way we extract, process, transport, and dispose of a vast flow of resources—some 220 billion tons a year, or more than 20 times the average American’s body weight every day. With dangerously narrow focus, our industries look only at the exploitable resources of the earth’s ecosystems—its oceans, forests, and plains—and not at the larger services that those systems provide for free. Resources and ecosystem services both come from the earth—even from the same biological systems—but they’re two different things. Forests, for instance, not only produce the resource of wood fiber but also provide such ecosystem services as water storage, habitat, and regulation of the atmosphere and climate. Yet companies that earn income from harvesting the wood fiber resource often do so in ways that damage the forest’s ability to carry out its other vital tasks.

Unfortunately, the cost of destroying ecosystem services becomes apparent only when the services start to break down. In China’s Yangtze basin in 1998, for example, deforestation triggered flooding that killed 3,700 people, dislocated 223 million, and inundated 60 million acres of cropland. That $30 billion disaster forced a logging moratorium and a $12 billion crash program of reforestation.

The reason companies (and governments) are so prodigal with ecosystem services is that the value of those services doesn’t appear on the business balance sheet. But that’s a staggering omission. The economy, after all, is embedded in the environment. Recent calculations published in the journal Nature conservatively estimate the value of all the earth’s ecosystem services to be at least $33 trillion a year. That’s close to the gross world product, and it implies a capitalized book value on the order of half a quadrillion dollars. What’s more, for most of these services, there is no known substitute at any price, and we can’t live without them.

This article puts forward a new approach not only for protecting the biosphere but also for improving profits and competitiveness. Some very simple changes to the way we run our businesses, built on advanced techniques for making resources more productive, can yield startling benefits both for today’s shareholders and for future generations.

This approach is called natural capitalism because it’s what capitalism might become if its largest category of capital—the “natural capital” of ecosystem services—were properly valued. The journey to natural capitalism involves four major shifts in business practices, all vitally interlinked:
Dramatically increase the productivity of natural resources. Reducing the wasteful and destructive flow of resources from depletion to pollution represents a major business opportunity. Through fundamental changes in both production design and technology, farsighted companies are developing ways to make natural resources—energy, minerals, water, forests—stretch five, ten, even 100 times further than they do today. These major resource savings often yield higher profits than small resource savings do—or even saving no resources at all would—and not only pay for themselves over time but in many cases reduce initial capital investments.
Shift to biologically inspired production models. Natural capitalism seeks not merely to reduce waste but to eliminate the very concept of waste. In closed-loop production systems, modeled on nature’s designs, every output either is returned harmlessly to the ecosystem as a nutrient, like compost, or becomes an input for manufacturing another product. Such systems can often be designed to eliminate the use of toxic materials, which can hamper nature’s ability to reprocess materials.


Move to a solutions-based business model. The business model of traditional manufacturing rests on the sale of goods. In the new model, value is instead delivered as a flow of services—providing illumination, for example, rather than selling lightbulbs. This model entails a new perception of value, a move from the acquisition of goods as a measure of affluence to one where well-being is measured by the continuous satisfaction of changing expectations for quality, utility, and performance. The new relationship aligns the interests of providers and customers in ways that reward them for implementing the first two innovations of natural capitalism—resource productivity and closed-loop manufacturing.
Reinvest in natural capital. Ultimately, business must restore, sustain, and expand the planet’s ecosystems so that they can produce their vital services and biological resources even more abundantly. Pressures to do so are mounting as human needs expand, the costs engendered by deteriorating ecosystems rise, and the environmental awareness of consumers increases. Fortunately, these pressures all create business value.

Natural capitalism is not motivated by a current scarcity of natural resources. Indeed, although many biological resources, like fish, are becoming scarce, most mined resources, such as copper and oil, seem ever more abundant. Indices of average commodity prices are at 28-year lows, thanks partly to powerful extractive technologies, which are often subsidized and whose damage to natural capital remains unaccounted for. Yet even despite these artificially low prices, using resources manyfold more productively can now be so profitable that pioneering companies—large and small—have already embarked on the journey toward natural capitalism.1

Still the question arises—if large resource savings are available and profitable, why haven’t they all been captured already? The answer is simple: Scores of common practices in both the private and public sectors systematically reward companies for wasting natural resources and penalize them for boosting resource productivity. For example, most companies expense their consumption of raw materials through the income statement but pass resource-saving investment through the balance sheet. That distortion makes it more tax efficient to waste fuel than to invest in improving fuel efficiency. In short, even though the road seems clear, the compass that companies use to direct their journey is broken. Later we’ll look in more detail at some of the obstacles to resource productivity—and some of the important business opportunities they reveal. But first, let’s map the route toward natural capitalism.
Dramatically Increase the Productivity of Natural Resources

In the first stage of a company’s journey toward natural capitalism, it strives to wring out the waste of energy, water, materials, and other resources throughout its production systems and other operations. There are two main ways companies can do this at a profit. First, they can adopt a fresh approach to design that considers industrial systems as a whole rather than part by part. Second, companies can replace old industrial technologies with new ones, particularly with those based on natural processes and materials.
Implementing whole-system design.

Inventor Edwin Land once remarked that “people who seem to have had a new idea have often simply stopped having an old idea.” This is particularly true when designing for resource savings. The old idea is one of diminishing returns—the greater the resource saving, the higher the cost. But that old idea is giving way to the new idea that bigger savings can cost less—that saving a large fraction of resources can actually cost less than saving a small fraction of resources. This is the concept of expanding returns, and it governs much of the revolutionary thinking behind whole-system design. Lean manufacturing is an example of whole-system thinking that has helped many companies dramatically reduce such forms of waste as lead times, defect rates, and inventory. Applying whole-system thinking to the productivity of natural resources can achieve even more.

Consider Interface, a leading maker of materials for commercial interiors. In its new Shanghai carpet factory, a liquid had to be circulated through a standard pumping loop similar to those used in nearly all industries. A top European company designed the system to use pumps requiring a total of 95 horsepower. But before construction began, Interface’s engineer, Jan Schilham, realized that two embarrassingly simple design changes would cut that power requirement to only seven horsepower—a 92% reduction. His redesigned system cost less to build, involved no new technology, and worked better in all respects.

What two design changes achieved this 12-fold saving in pumping power? First, Schilham chose fatter-than-usual pipes, which create much less friction than thin pipes do and therefore need far less pumping energy. The original designer had chosen thin pipes because, according to the textbook method, the extra cost of fatter ones wouldn’t be justified by the pumping energy that they would save. This standard design trade-off optimizes the pipes by themselves but “pessimizes” the larger system. Schilham optimized the whole system by counting not only the higher capital cost of the fatter pipes but also the lower capital cost of the smaller pumping equipment that would be needed. The pumps, motors, motor controls, and electrical components could all be much smaller because there’d be less friction to overcome. Capital cost would fall far more for the smaller equipment than it would rise for the fatter pipe. Choosing big pipes and small pumps—rather than small pipes and big pumps—would therefore make the whole system cost less to build, even before counting its future energy savings.

Schilham’s second innovation was to reduce the friction even more by making the pipes short and straight rather than long and crooked. He did this by laying out the pipes first, then positioning the various tanks, boilers, and other equipment that they connected. Designers normally locate the production equipment in arbitrary positions and then have a pipe fitter connect everything. Awkward placement forces the pipes to make numerous bends that greatly increase friction. The pipe fitters don’t mind: They’re paid by the hour, they profit from the extra pipes and fittings, and they don’t pay for the oversized pumps or inflated electric bills. In addition to reducing those four kinds of costs, Schilham’s short, straight pipes were easier to insulate, saving an extra 70 kilowatts of heat loss and repaying the insulation’s cost in three months.

This small example has big implications for two reasons. First, pumping is the largest application of motors, and motors use three-quarters of all industrial electricity. Second, the lessons are very widely relevant. Interface’s pumping loop shows how simple changes in design mentality can yield huge resource savings and returns on investment. This isn’t rocket science; often it’s just a rediscovery of good Victorian engineering principles that have been lost because of specialization.

Whole-system thinking can help managers find small changes that lead to big savings that are cheap, free, or even better than free (because they make the whole system cheaper to build). They can do this because often the right investment in one part of the system can produce multiple benefits throughout the system. For example, companies would gain 18 distinct economic benefits—of which direct energy savings is only one—if they switched from ordinary motors to premium-efficiency motors or from ordinary lighting ballasts (the transformer-like boxes that control fluorescent lamps) to electronic ballasts that automatically dim the lamps to match available daylight. If everyone in America integrated these and other selected technologies into all existing motor and lighting systems in an optimal way, the nation’s $220-billion-a-year electric bill would be cut in half. The after-tax return on investing in these changes would in most cases exceed 100% per year.

The profits from saving electricity could be increased even further if companies also incorporated the best off-the-shelf improvements into their building structure and their office, heating, cooling, and other equipment. Overall, such changes could cut national electricity consumption by at least 75% and produce returns of around 100% a year on the investments made. More important, because workers would be more comfortable, better able to see, and less fatigued by noise, their productivity and the quality of their output would rise. Eight recent case studies of people working in well-designed, energy-efficient buildings measured labor productivity gains of 6% to 16%. Since a typical office pays about 100 times as much for people as it does for energy, this increased productivity in people is worth about 6 to 16 times as much as eliminating the entire energy bill.

Energy-saving, productivity-enhancing improvements can often be achieved at even lower cost by piggybacking them onto the periodic renovations that all buildings and factories need. A recent proposal for reallocating the normal 20-year renovation budget for a standard 200,000-square-foot glass-clad office tower near Chicago shows the potential of whole-system design. The proposal suggested replacing the aging glazing system with a new kind of window that lets in nearly six times more daylight than the old sun-blocking glass units. The new windows would reduce the flow of heat and noise four times better than traditional windows do. So even though the glass costs slightly more, the overall cost of the renovation would be reduced because the windows would let in cool, glare-free daylight that, when combined with more efficient lighting and office equipment, would reduce the need for air-conditioning by 75%. Installing a fourfold more efficient, but fourfold smaller, air-conditioning system would cost $200,000 less than giving the old system its normal 20-year renovation. The $200,000 saved would, in turn, pay for the extra cost of the new windows and other improvements. This whole-system approach to renovation would not only save 75% of the building’s total energy use, it would also greatly improve the building’s comfort and marketability. Yet it would cost essentially the same as the normal renovation. There are about 100,000 20-year-old glass office towers in the United States that are ripe for such improvement.

Major gains in resource productivity require that the right steps be taken in the right order. Small changes made at the downstream end of a process often create far larger savings further upstream. In almost any industry that uses a pumping system, for example, saving one unit of liquid flow or friction in an exit pipe saves about ten units of fuel, cost, and pollution at the power station.

Of course, the original reduction in flow itself can bring direct benefits, which are often the reason changes are made in the first place. In the 1980s, while California’s industry grew 30%, for example, its water use was cut by 30%, largely to avoid increased wastewater fees. But the resulting reduction in pumping energy (and the roughly tenfold larger saving in power-plant fuel and pollution) delivered bonus savings that were at the time largely unanticipated.

To see how downstream cuts in resource consumption can create huge savings upstream, consider how reducing the use of wood fiber disproportionately reduces the pressure to cut down forests. In round numbers, half of all harvested wood fiber is used for such structural products as lumber; the other half is used for paper and cardboard. In both cases, the biggest leverage comes from reducing the amount of the retail product used. If it takes, for example, three pounds of harvested trees to produce one pound of product, then saving one pound of product will save three pounds of trees—plus all the environmental damage avoided by not having to cut them down in the first place.

The easiest savings come from not using paper that’s unwanted or unneeded. In an experiment at its Swiss headquarters, for example, Dow Europe cut office paper flow by about 30% in six weeks simply by discouraging unneeded information. For instance, mailing lists were eliminated and senders of memos got back receipts indicating whether each recipient had wanted the information. Taking those and other small steps, Dow was also able to increase labor productivity by a similar proportion because people could focus on what they really needed to read. Similarly, Danish hearing-aid maker Oticon saved upwards of 30% of its paper as a by-product of redesigning its business processes to produce better decisions faster. Setting the default on office printers and copiers to double-sided mode reduced AT&T’s paper costs by about 15%. Recently developed copiers and printers can even strip off old toner and printer ink, permitting each sheet to be reused about ten times.

Further savings can come from using thinner but stronger and more opaque paper and from designing packaging more thoughtfully. In a 30-month effort at reducing such waste, Johnson & Johnson saved 2,750 tons of packaging, 1,600 tons of paper, $2.8 million, and at least 330 acres of forest annually. The downstream savings in paper use are multiplied by the savings further upstream, as less need for paper products (or less need for fiber to make each product) translates into less raw paper, less raw paper means less pulp, and less pulp requires fewer trees to be harvested from the forest. Recycling paper and substituting alternative fibers such as wheat straw will save even more.

Comparable savings can be achieved for the wood fiber used in structural products. Pacific Gas and Electric, for example, sponsored an innovative design developed by Davis Energy Group that used engineered wood products to reduce the amount of wood needed in a stud wall for a typical tract house by more than 70%. These walls were stronger, cheaper, more stable, and insulated twice as well. Using them enabled the designers to eliminate heating and cooling equipment in a climate where temperatures range from freezing to 113°F. Eliminating the equipment made the whole house much less expensive both to build and to run while still maintaining high levels of comfort. Taken together, these and many other savings in the paper and construction industries could make our use of wood fiber so much more productive that, in principle, the entire world’s present wood fiber needs could probably be met by an intensive tree farm about the size of Iowa.
Adopting innovative technologies.

Implementing whole-system design goes hand in hand with introducing alternative, environmentally friendly technologies. Many of these are already available and profitable but not widely known. Some, like the “designer catalysts” that are transforming the chemical industry, are already runaway successes. Others are still making their way to market, delayed by cultural rather than by economic or technical barriers.

The automobile industry is particularly ripe for technological change. After a century of development, motorcar technology is showing signs of age. Only 1% of the energy consumed by today’s cars is actually used to move the driver: Only 15% to 20% of the power generated by burning gasoline reaches the wheels (the rest is lost in the engine and drivetrain) and 95% of the resulting propulsion moves the car, not the driver. The industry’s infrastructure is hugely expensive and inefficient. Its convergent products compete for narrow niches in saturated core markets at commodity-like prices. Auto making is capital intensive, and product cycles are long. It is profitable in good years but subject to large losses in bad years. Like the typewriter industry just before the advent of personal computers, it is vulnerable to displacement by something completely different.

Enter the Hypercar. Since 1993, when Rocky Mountain Institute placed this automotive concept in the public domain, several dozen current and potential auto manufacturers have committed billions of dollars to its development and commercialization. The Hypercar integrates the best existing technologies to reduce the consumption of fuel as much as 85% and the amount of materials used up to 90% by introducing four main innovations.

First, making the vehicle out of advanced polymer composites, chiefly carbon fiber, reduces its weight by two-thirds while maintaining crashworthiness. Second, aerodynamic design and better tires reduce air resistance by as much as 70% and rolling resistance by up to 80%. Together, these innovations save about two-thirds of the fuel. Third, 30% to 50% of the remaining fuel is saved by using a “hybrid-electric” drive. In such a system, the wheels are turned by electric motors whose power is made onboard by a small engine or turbine, or even more efficiently by a fuel cell. The fuel cell generates electricity directly by chemically combining stored hydrogen with oxygen, producing pure hot water as its only by-product. Interactions between the small, clean, efficient power source and the ultralight, low-drag auto body then further reduce the weight, cost, and complexity of both. Fourth, much of the traditional hardware—from transmissions and differentials to gauges and certain parts of the suspension—can be replaced by electronics controlled with highly integrated, customizable, and upgradable software.

These technologies make it feasible to manufacture pollution-free, high-performance cars, sport utilities, pickup trucks, and vans that get 80 to 200 miles per gallon (or its energy equivalent in other fuels). These improvements will not require any compromise in quality or utility. Fuel savings will not come from making the vehicles small, sluggish, unsafe, or unaffordable, nor will they depend on government fuel taxes, mandates, or subsidies. Rather, Hypercars will succeed for the same reason that people buy compact discs instead of phonograph records: The CD is a superior product that redefines market expectations. From the manufacturers’ perspective, Hypercars will cut cycle times, capital needs, body part counts, and assembly effort and space by as much as tenfold. Early adopters will have a huge competitive advantage—which is why dozens of corporations, including most automakers, are now racing to bring Hypercar-like products to market.2

In the long term, the Hypercar will transform industries other than automobiles. It will displace about an eighth of the steel market directly and most of the rest eventually, as carbon fiber becomes far cheaper. Hypercars and their cousins could ultimately save as much oil as OPEC now sells. Indeed, oil may well become uncompetitive as a fuel long before it becomes scarce and costly. Similar challenges face the coal and electricity industries because the development of the Hypercar is likely to accelerate greatly the commercialization of inexpensive hydrogen fuel cells. These fuel cells will help shift power production from centralized coal-fired and nuclear power stations to networks of decentralized, small-scale generators. In fact, fuel cell–powered Hypercars could themselves be part of these networks. They’d be, in effect, 20-kilowatt power plants on wheels. Given that cars are left parked—that is, unused—more than 95% of the time, these Hypercars could be plugged into a grid and could then sell back enough electricity to repay as much as half the predicted cost of leasing them. A national Hypercar fleet could ultimately have five to ten times the generating capacity of the national electric grid.

As radical as it sounds, the Hypercar is not an isolated case. Similar ideas are emerging in such industries as chemicals, semiconductors, general manufacturing, transportation, water and wastewater treatment, agriculture, forestry, energy, real estate, and urban design. For example, the amount of carbon dioxide released for each microchip manufactured can be reduced almost 100-fold through improvements that are now profitable or soon will be.

Some of the most striking developments come from emulating nature’s techniques. In her book, Biomimicry, Janine Benyus points out that spiders convert digested crickets and flies into silk that’s as strong as Kevlar without the need for boiling sulfuric acid and high-temperature extruders. Using no furnaces, abalone can convert seawater into an inner shell twice as tough as our best ceramics. Trees turn sunlight, water, soil, and air into cellulose, a sugar stronger than nylon but one-fourth as dense. They then bind it into wood, a natural composite with a higher bending strength than concrete, aluminum alloy, or steel. We may never become as skillful as spiders, abalone, or trees, but smart designers are already realizing that nature’s environmentally benign chemistry offers attractive alternatives to industrial brute force.

Whether through better design or through new technologies, reducing waste represents a vast business opportunity. The U.S. economy is not even 10% as energy efficient as the laws of physics allow. Just the energy thrown off as waste heat by U.S. power stations equals the total energy use of Japan. Materials efficiency is even worse: only about 1% of all the materials mobilized to serve America is actually made into products and still in use six months after sale. In every sector, there are opportunities for reducing the amount of resources that go into a production process, the steps required to run that process, and the amount of pollution generated and by-products discarded at the end. These all represent avoidable costs and hence profits to be won.
Redesign Production According to Biological Models

In the second stage on the journey to natural capitalism, companies use closed-loop manufacturing to create new products and processes that can totally prevent waste. This plus more efficient production processes could cut companies’ long-term materials requirements by more than 90% in most sectors.

The central principle of closed-loop manufacturing, as architect Paul Bierman-Lytle of the engineering firm CH2M Hill puts it, is “waste equals food.” Every output of manufacturing should be either composted into natural nutrients or remanufactured into technical nutrients—that is, it should be returned to the ecosystem or recycled for further production. Closed-loop production systems are designed to eliminate any materials that incur disposal costs, especially toxic ones, because the alternative—isolating them to prevent harm to natural systems—tends to be costly and risky. Indeed, meeting EPA and OSHA standards by eliminating harmful materials often makes a manufacturing process cost less than the hazardous process it replaced. Motorola, for example, formerly used chlorofluorocarbons for cleaning printed circuit boards after soldering. When CFCs were outlawed because they destroy stratospheric ozone, Motorola at first explored such alternatives as orange-peel terpenes. But it turned out to be even cheaper—and to produce a better product—to redesign the whole soldering process so that it needed no cleaning operations or cleaning materials at all.

Closed-loop manufacturing is more than just a theory. The U.S. remanufacturing industry in 1996 reported revenues of $53 billion—more than consumer-durables manufacturing (appliances; furniture; audio, video, farm, and garden equipment). Xerox, whose bottom line has swelled by $700 million from remanufacturing, expects to save another $1 billion just by remanufacturing its new, entirely reusable or recyclable line of “green” photocopiers. What’s more, policy makers in some countries are already taking steps to encourage industry to think along these lines. German law, for example, makes many manufacturers responsible for their products forever, and Japan is following suit.

Combining closed-loop manufacturing with resource efficiency is especially powerful. DuPont, for example, gets much of its polyester industrial film back from customers after they use it and recycles it into new film. DuPont also makes its polyester film ever stronger and thinner so it uses less material and costs less to make. Yet because the film performs better, customers are willing to pay more for it. As DuPont chairman Jack Krol noted in 1997, “Our ability to continually improve the inherent properties [of our films] enables this process [of developing more productive materials, at lower cost, and higher profits] to go on indefinitely.”

Interface is leading the way to this next frontier of industrial ecology. While its competitors are “down cycling” nylon-and-PVC-based carpet into less valuable carpet backing, Interface has invented a new floor-covering material called Solenium, which can be completely remanufactured into identical new product. This fundamental innovation emerged from a clean-sheet redesign. Executives at Interface didn’t ask how they could sell more carpet of the familiar kind; they asked how they could create a dream product that would best meet their customers’ needs while protecting and nourishing natural capital.

Solenium lasts four times longer and uses 40% less material than ordinary carpets—an 86% reduction in materials intensity. What’s more, Solenium is free of chlorine and other toxic materials, is virtually stainproof, doesn’t grow mildew, can easily be cleaned with water, and offers aesthetic advantages over traditional carpets. It’s so superior in every respect that Interface doesn’t market it as an environmental product—just a better one.

Solenium is only one part of Interface’s drive to eliminate every form of waste. Chairman Ray C. Anderson defines waste as “any measurable input that does not produce customer value,” and he considers all inputs to be waste until shown otherwise. Between 1994 and 1998, this zero-waste approach led to a systematic treasure hunt that helped to keep resource inputs constant while revenues rose by $200 million. Indeed, $67 million of the revenue increase can be directly attributed to the company’s 60% reduction in landfill waste.

Subsequently, president Charlie Eitel expanded the definition of waste to include all fossil fuel inputs, and now many customers are eager to buy products from the company’s recently opened solar-powered carpet factory. Interface’s green strategy has not only won plaudits from environmentalists, it has also proved a remarkably successful business strategy. Between 1993 and 1998, revenue has more than doubled, profits have more than tripled, and the number of employees has increased by 73%.
Change the Business Model

In addition to its drive to eliminate waste, Interface has made a fundamental shift in its business model—the third stage on the journey toward natural capitalism. The company has realized that clients want to walk on and look at carpets—but not necessarily to own them. Traditionally, broadloom carpets in office buildings are replaced every decade because some portions look worn out. When that happens, companies suffer the disruption of shutting down their offices and removing their furniture. Billions of pounds of carpets are removed each year and sent to landfills, where they will last up to 20,000 years. To escape this unproductive and wasteful cycle, Interface is transforming itself from a company that sells and fits carpets into one that provides floor-covering services.

Under its Evergreen Lease, Interface no longer sells carpets but rather leases a floor-covering service for a monthly fee, accepting responsibility for keeping the carpet fresh and clean. Monthly inspections detect and replace worn carpet tiles. Since at most 20% of an area typically shows at least 80% of the wear, replacing only the worn parts reduces the consumption of carpeting material by about 80%. It also minimizes the disruption that customers experience—worn tiles are seldom found under furniture. Finally, for the customer, leasing carpets can provide a tax advantage by turning a capital expenditure into a tax-deductible expense. The result: The customer gets cheaper and better services that cost the supplier far less to produce. Indeed, the energy saved from not producing a whole new carpet is in itself enough to produce all the carpeting that the new business model requires. Taken together, the fivefold savings in carpeting material that Interface achieves through the Evergreen Lease and the sevenfold materials savings achieved through the use of Solenium deliver a stunning 35-fold reduction in the flow of materials needed to sustain a superior floor-covering service. Remanufacturing, and even making carpet initially from renewable materials, can then reduce the extraction of virgin resources essentially to the company’s goal of zero.

Interface’s shift to a service-leasing business reflects a fundamental change from the basic model of most manufacturing companies, which still look on their businesses as machines for producing and selling products. The more products sold, the better—at least for the company, if not always for the customer or the earth. But any model that wastes natural resources also wastes money. Ultimately, that model will be unable to compete with a service model that emphasizes solving problems and building long-term relationships with customers rather than making and selling products. The shift to what James Womack of the Lean Enterprise Institute calls a “solutions economy” will almost always improve customer value and providers’ bottom lines because it aligns both parties’ interests, offering rewards for doing more and better with less.

Interface is not alone. Elevator giant Schindler, for example, prefers leasing vertical transportation services to selling elevators because leasing lets it capture the savings from its elevators’ lower energy and maintenance costs. Dow Chemical and Safety-Kleen prefer leasing dissolving services to selling solvents because they can reuse the same solvent scores of times, reducing costs. United Technologies’ Carrier division, the world’s largest manufacturer of air conditioners, is shifting its mission from selling air conditioners to leasing comfort. Making its air conditioners more durable and efficient may compromise future equipment sales, but it provides what customers want and will pay for—better comfort at lower cost. But Carrier is going even further. It’s starting to team up with other companies to make buildings more efficient so that they need less air-conditioning, or even none at all, to yield the same level of comfort. Carrier will get paid to provide the agreed-upon level of comfort, however that’s delivered. Higher profits will come from providing better solutions rather than from selling more equipment. Since comfort with little or no air-conditioning (via better building design) works better and costs less than comfort with copious air-conditioning, Carrier is smart to capture this opportunity itself before its competitors do. As they say at 3M: “We’d rather eat our own lunch, thank you.”

The shift to a service business model promises benefits not just to participating businesses but to the entire economy as well. Womack points out that by helping customers reduce their need for capital goods such as carpets or elevators, and by rewarding suppliers for extending and maximizing asset values rather than for churning them, adoption of the service model will reduce the volatility in the turnover of capital goods that lies at the heart of the business cycle. That would significantly reduce the overall volatility of the world’s economy. At present, the producers of capital goods face feast or famine because the buying decisions of households and corporations are extremely sensitive to fluctuating income. But in a continuous-flow-of-services economy, those swings would be greatly reduced, bringing a welcome stability to businesses. Excess capacity—another form of waste and source of risk—need no longer be retained for meeting peak demand. The result of adopting the new model would be an economy in which we grow and get richer by using less and become stronger by being leaner and more stable.
Reinvest in Natural Capital

The foundation of textbook capitalism is the prudent reinvestment of earnings in productive capital. Natural capitalists who have dramatically raised their resource productivity, closed their loops, and shifted to a solutions-based business model have one key task remaining. They must reinvest in restoring, sustaining, and expanding the most important form of capital—their own natural habitat and biological resource base.

This was not always so important. Until recently, business could ignore damage to the ecosystem because it didn’t affect production and didn’t increase costs. But that situation is changing. In 1998 alone, violent weather displaced 300 million people and caused upwards of $90 billion worth of damage, representing more weather-related destruction than was reported through the entire decade of the 1980s. The increase in damage is strongly linked to deforestation and climate change, factors that accelerate the frequency and severity of natural disasters and are the consequences of inefficient industrialization. If the flow of services from industrial systems is to be sustained or increased in the future for a growing population, the vital flow of services from living systems will have to be maintained or increased as well. Without reinvestment in natural capital, shortages of ecosystem services are likely to become the limiting factor to prosperity in the next century. When a manufacturer realizes that a supplier of key components is overextended and running behind on deliveries, it takes immediate action lest its own production lines come to a halt. The ecosystem is a supplier of key components for the life of the planet, and it is now falling behind on its orders.

Failure to protect and reinvest in natural capital can also hit a company’s revenues indirectly. Many companies are discovering that public perceptions of environmental responsibility, or its lack thereof, affect sales. MacMillan Bloedel, targeted by environmental activists as an emblematic clear-cutter and chlorine user, lost 5% of its sales almost overnight when dropped as a U.K. supplier by Scott Paper and Kimberly-Clark. Numerous case studies show that companies leading the way in implementing changes that help protect the environment tend to gain disproportionate advantage, while companies perceived as irresponsible lose their franchise, their legitimacy, and their shirts. Even businesses that claim to be committed to the concept of sustainable development but whose strategy is seen as mistaken, like Monsanto, are encountering stiffening public resistance to their products. Not surprisingly, University of Oregon business professor Michael Russo, along with many other analysts, has found that a strong environmental rating is “a consistent predictor of profitability.”

The pioneering corporations that have made reinvestments in natural capital are starting to see some interesting paybacks. The independent power producer AES, for example, has long pursued a policy of planting trees to offset the carbon emissions of its power plants. That ethical stance, once thought quixotic, now looks like a smart investment because a dozen brokers are now starting to create markets in carbon reduction. Similarly, certification by the Forest Stewardship Council of certain sustainably grown and harvested products has given Collins Pine the extra profit margins that enabled its U.S. manufacturing operations to survive brutal competition. Taking an even longer view, Swiss Re and other European reinsurers are seeking to cut their storm-damage losses by pressing for international public policy to protect the climate and by investing in climate-safe technologies that also promise good profits. Yet most companies still do not realize that a vibrant ecological web underpins their survival and their business success. Enriching natural capital is not just a public good—it is vital to every company’s longevity.

It turns out that changing industrial processes so that they actually replenish and magnify the stock of natural capital can prove especially profitable because nature does the production; people need to just step back and let life flourish. Industries that directly harvest living resources, such as forestry, farming, and fishing, offer the most suggestive examples. Here are three:
Allan Savory of the Center for Holistic Management in Albuquerque, New Mexico, has redesigned cattle ranching to raise the carrying capacity of rangelands, which have often been degraded not by overgrazing but by undergrazing and grazing the wrong way. Savory’s solution is to keep the cattle moving from place to place, grazing intensively but briefly at each site, so that they mimic the dense but constantly moving herds of native grazing animals that coevolved with grasslands. Thousands of ranchers are estimated to be applying this approach, improving both their range and their profits. This “management-intensive rotational grazing” method, long standard in New Zealand, yields such clearly superior returns that over 15% of Wisconsin’s dairy farms have adopted it in the past few years.
The California Rice Industry Association has discovered that letting nature’s diversity flourish can be more profitable than forcing it to produce a single product. By flooding 150,000 to 200,000 acres of Sacramento valley rice fields—about 30% of California’s rice-growing area—after harvest, farmers are able to create seasonal wetlands that support millions of wildfowl, replenish groundwater, improve fertility, and yield other valuable benefits. In addition, the farmers bale and sell the rice straw, whose high silica content—formerly an air-pollution hazard when the straw was burned—adds insect resistance and hence value as a construction material when it’s resold instead.


John Todd of Living Technologies in Burlington, Vermont, has used biological Living Machines—linked tanks of bacteria, algae, plants, and other organisms—to turn sewage into clean water. That not only yields cleaner water at a reduced cost, with no toxicity or odor, but it also produces commercially valuable flowers and makes the plant compatible with its residential neighborhood. A similar plant at the Ethel M Chocolates factory in Las Vegas, Nevada, not only handles difficult industrial wastes effectively but is showcased in its public tours.

Although such practices are still evolving, the broad lessons they teach are clear. In almost all climates, soils, and societies, working with nature is more productive than working against it. Reinvesting in nature allows farmers, fishermen, and forest managers to match or exceed the high yields and profits sustained by traditional input-intensive, chemically driven practices. Although much of mainstream business is still headed the other way, the profitability of sustainable, nature-emulating practices is already being proven. In the future, many industries that don’t now consider themselves dependent on a biological resource base will become more so as they shift their raw materials and production processes more to biological ones. There is evidence that many business leaders are starting to think this way. The consulting firm Arthur D. Little surveyed a group of North American and European business leaders and found that 83% of them already believe that they can derive “real business value [from implementing a] sustainable-development approach to strategy and operations.”
A Broken Compass?

If the road ahead is this clear, why are so many companies straying or falling by the wayside? We believe the reason is that the instruments companies use to set their targets, measure their performance, and hand out rewards are faulty. In other words, the markets are full of distortions and perverse incentives. Of the more than 60 specific forms of misdirection that we have identified,3 the most obvious involve the ways companies allocate capital and the way governments set policy and impose taxes. Merely correcting these defective practices would uncover huge opportunities for profit.

Consider how companies make purchasing decisions. Decisions to buy small items are typically based on their initial cost rather than their full life-cycle cost, a practice that can add up to major wastage. Distribution transformers that supply electricity to buildings and factories, for example, are a minor item at just $320 apiece, and most companies try to save a quick buck by buying the lowest-price models. Yet nearly all the nation’s electricity must flow through transformers, and using the cheaper but less efficient models wastes $1 billion a year. Such examples are legion. Equipping standard new office-lighting circuits with fatter wire that reduces electrical resistance could generate after-tax returns of 193% a year. Instead, wire as thin as the National Electrical Code permits is usually selected because it costs less up front. But the code is meant only to prevent fires from overheated wiring, not to save money. Ironically, an electrician who chooses fatter wire—thereby reducing long-term electricity bills—doesn’t get the job. After paying for the extra copper, he’s no longer the low bidder.

Some companies do consider more than just the initial price in their purchasing decisions but still don’t go far enough. Most of them use a crude payback estimate rather than more accurate metrics like discounted cash flow. A few years ago, the median simple payback these companies were demanding from energy efficiency was 1.9 years. That’s equivalent to requiring an after-tax return of around 71% per year—about six times the marginal cost of capital.

Most companies also miss major opportunities by treating their facilities costs as an overhead to be minimized, typically by laying off engineers, rather than as a profit center to be optimized—by using those engineers to save resources. Deficient measurement and accounting practices also prevent companies from allocating costs—and waste—with any accuracy. For example, only a few semiconductor plants worldwide regularly and accurately measure how much energy they’re using to produce a unit of chilled water or clean air for their clean-room production facilities. That makes it hard for them to improve efficiency. In fact, in an effort to save time, semiconductor makers frequently build new plants as exact copies of previous ones—a design method nicknamed “infectious repetitis.”

Many executives pay too little attention to saving resources because they are often a small percentage of total costs (energy costs run to about 2% in most industries). But those resource savings drop straight to the bottom line and so represent a far greater percentage of profits. Many executives also think they already “did” efficiency in the 1970s, when the oil shock forced them to rethink old habits. They’re forgetting that with today’s far better technologies, it’s profitable to start all over again. Malden Mills, the Massachusetts maker of such products as Polartec, was already using “efficient” metal-halide lamps in the mid-1990s. But a recent warehouse retrofit reduced the energy used for lighting by another 93%, improved visibility, and paid for itself in 18 months.

The way people are rewarded often creates perverse incentives. Architects and engineers, for example, are traditionally compensated for what they spend, not for what they save. Even the striking economics of the retrofit design for the Chicago office tower described earlier wasn’t incentive enough actually to implement it. The property was controlled by a leasing agent who earned a commission every time she leased space, so she didn’t want to wait the few extra months needed to refit the building. Her decision to reject the efficiency-quadrupling renovation proved costly for both her and her client. The building was so uncomfortable and expensive to occupy that it didn’t lease, so ultimately the owner had to unload it at a fire-sale price. Moreover, the new owner will for the next 20 years be deprived of the opportunity to save capital cost.

If corporate practices obscure the benefits of natural capitalism, government policy positively undermines it. In nearly every country on the planet, tax laws penalize what we want more of—jobs and income—while subsidizing what we want less of—resource depletion and pollution. In every state but Oregon, regulated utilities are rewarded for selling more energy, water, and other resources, and penalized for selling less, even if increased production would cost more than improved customer efficiency. In most of America’s arid western states, use-it-or-lose-it water laws encourage inefficient water consumption. Additionally, in many towns, inefficient use of land is enforced through outdated regulations, such as guidelines for ultrawide suburban streets recommended by 1950s civil-defense planners to accommodate the heavy equipment needed to clear up rubble after a nuclear attack.

The costs of these perverse incentives are staggering: $300 billion in annual energy wasted in the United States, and $1 trillion already misallocated to unnecessary air-conditioning equipment and the power supplies to run it (about 40% of the nation’s peak electric load). Across the entire economy, unneeded expenditures to subsidize, encourage, and try to remedy inefficiency and damage that should not have occurred in the first place probably account for most, if not all, of the GDP growth of the past two decades. Indeed, according to former World Bank economist Herman Daly and his colleague John Cobb (along with many other analysts), Americans are hardly better off than they were in 1980. But if the U.S. government and private industry could redirect the dollars currently earmarked for remedial costs toward reinvestment in natural and human capital, they could bring about a genuine improvement in the nation’s welfare. Companies, too, are finding that wasting resources also means wasting money and people. These intertwined forms of waste have equally intertwined solutions. Firing the unproductive tons, gallons, and kilowatt-hours often makes it possible to keep the people, who will have more and better work to do.
Recognizing the Scarcity Shift

In the end, the real trouble with our economic compass is that it points in exactly the wrong direction. Most businesses are behaving as if people were still scarce and nature still abundant—the conditions that helped to fuel the first Industrial Revolution. At that time, people were relatively scarce compared with the present-day population. The rapid mechanization of the textile industries caused explosive economic growth that created labor shortages in the factory and the field. The Industrial Revolution, responding to those shortages and mechanizing one industry after another, made people a hundred times more productive than they had ever been.

The logic of economizing on the scarcest resource, because it limits progress, remains correct. But the pattern of scarcity is shifting: Now people aren’t scarce but nature is. This shows up first in industries that depend directly on ecological health. Here, production is increasingly constrained by fish rather than by boats and nets, by forests rather than by chain saws, by fertile topsoil rather than by plows. Moreover, unlike the traditional factors of industrial production—capital and labor—the biological limiting factors cannot be substituted for one another. In the industrial system, we can easily exchange machinery for labor. But no technology or amount of money can substitute for a stable climate and a productive biosphere. Even proper pricing can’t replace the priceless.

Natural capitalism addresses those problems by reintegrating ecological with economic goals. Because it is both necessary and profitable, it will subsume traditional industrialism within a new economy and a new paradigm of production, just as industrialism previously subsumed agrarianism. The companies that first make the changes we have described will have a competitive edge. Those that don’t make that effort won’t be a problem because ultimately they won’t be around. In making that choice, as Henry Ford said, “Whether you believe you can, or whether you believe you can’t, you’re absolutely right.”

1. Our book, Natural Capitalism, provides hundreds of examples of how companies of almost every type and size, often through modest shifts in business logic and practice, have dramatically improved their bottom lines.

2. Nonproprietary details are posted at www.hypercar.com

3. Summarized in the report “Climate: Making Sense and Making Money,” at www.rmi.org/images/other/Climate/C97-13_ClimateMSMM.pdf

A version of this article appeared in the
July–August 2007 issue of Harvard Business Review.


AL
Amory B. Lovins is a cofounder and the chairman of Rocky Mountain Institute (RMI), a nonprofit resource policy center in Snowmass, Colorado.
LL
L. Hunter Lovins is a cofounder of RMI and the president and founder of Natural Capitalism, a firm that helps organizations create sustainability strategies, in Boulder, Colorado.
PH
Paul Hawken is the founder and the executive director of Natural Capital Institute, a research group based in Sausalito, California. He has also founded or cofounded several companies,

 NATURAL CAPITALI$M

Researchers propose a scheme that treats carbon emissions like financial debt

Paying off our carbon debt

UNIVERSITY OF CALIFORNIA - SANTA BARBARA

Research News

The recent extreme heat in the Western United States and Canada may seem remarkable now, but events like these are made more likely, and more severe, under climate change. The consequences are likely to be far-reaching, with overwhelmingly negative impacts on land and ocean ecosystems, biodiversity, food production and the built environment.

"The main lever we have to slow global warming is the rate at which CO2 is added to the atmosphere," said Marcus Thomson, a postdoctoral scholar at the National Center for Ecological Analysis & Synthesis at UC Santa Barbara. Thomson is a co-author of a research article just published in Nature that presents a scheme to slow global warming by tying CO2 emissions to carbon removal obligations.

In spite of several high-profile attempts to limit emissions caused by human activities over the past several decades, atmospheric carbon dioxide has continued to rise steadily. If this trend continues, sufficient CO2 will be added to the atmosphere -- the "remaining carbon budget" will be depleted -- in about a decade to raise the long-term average global temperature by 1.5°C. That in turn raises the likelihood of dangerous and irreversible socioeconomic and ecological damage.

The most recent attempt to cooperatively limit global greenhouse gas emissions was COP21 in 2015, which resulted in the "Paris Agreement", an international treaty that has been in force since. Under the Paris Agreement, individual countries pledge to reduce their emissions in order to keep global warming to no more than +1.5°C and "well below" 2°C. For the Paris Agreement to have any hope of succeeding, and for dangerous global warming to be avoided, it will be necessary to actively remove CO2 from the atmosphere, in addition to limiting emissions. Technically, once the remaining carbon budget is depleted, for every ton of CO2 added to the atmosphere, it will be necessary to remove a ton of CO2 later this century.

In other words, the researchers assert, should emissions continue after the carbon budget is depleted -- which seems likely -- the budget will go negative, and we will begin accruing a carbon debt. The greater this carbon debt grows, the faster and more dramatically the climate will change -- it will become a more difficult problem to fix. This assumption is already baked into the net-zero pledges that countries have made. However, these pledges are still insufficient. There remains no uniform global strategy for national and sub-national governments, public organizations and private companies to get behind to pay down this carbon debt. This raises the risk that future generations will be unfairly burdened with massive debt, and challenges any long-term strategy to limit warming to +1.5°C. In short, in spite of near universal agreement on the need to achieve net-zero emissions, there remains a significant challenge to operationalize concerted action.

Before It's Too Late

In their article, the researchers argue that to assure the viability of a future net-negative carbon economy, funds for future carbon debt repayment ought to be collected through a carbon pricing scheme before and while carbon debt is accrued. As lead author Johannes Bednar, a research scholar at the International Institute for Applied Systems Analysis (IIASA) in Austria and a Ph.D. student at Oxford University explained, "Economic logic dictates that the latest possible time to start doing that is [the moment] when the carbon budget becomes depleted."

In the case of an idealized global emissions trading scheme, emission caps become more stringent as the carbon budget is depleted. For existing schemes, like that used by the European Union, this would mean reducing the quantity of currently scheduled emissions allowances. This risks making the whole scheme economically and politically untenable. The reduced number of allowances would, however, be compensated by Carbon Removal Obligations (CROs), obligating emitters to remove an equivalent quantity of CO2 in the future instead of paying a carbon price now, which may be insufficient to compensate for the eventual cost of warming. In the plan, carbon debt would be managed through CROs which establish legal responsibility for carbon debt repayment.

"We needed a scheme that would be resilient to future interference in its primary goal, which is to decarbonize the environment, yet still be as simple as possible," Thomson said. "CROs work within the existing and foreseeable regulatory environment, and should also be appealing for capital markets. We started with the germ of an idea and worked it through collaboratively. Johannes developed a rigorous proof of concept model, and then pulled everything together beautifully."

Emission trading schemes backed by CROs carry the risk of default by debtors. The authors propose that the latter be addressed by treating carbon debt like financial debt, and by imposing interest on carbon debt. Interest payments would be treated as a rental fee for temporarily storing CO2 in the atmosphere. Additionally, making CROs tradable assets facilitates the de-risking of intertemporal carbon markets.

The proposal resolves some of the inconsistencies in the current academic understanding of scenarios as well as foreseeable failures in climate policy over the long term. Instead of burdening future generations with excessive debt, CROs imply a more equitable distribution of financial flows and costs over time. Moreover, in climate mitigation scenarios, a larger portfolio of CO2 removal technologies usually goes hand in hand with increased carbon debt and therefore a greater reliance on CO2 removal in the future.

"CROs completely change how we see [carbon dioxide removals], from magical tools to enable a 30 year long period of the 'grand atmospheric restoration project' to a technology option that is developed and tested today and flexibly and more incrementally scaled throughout the 21st century and possibly beyond," noted study co-author Michael Obersteiner, director of the Environmental Change Institute (ECI) at Oxford University and a senior research scholar at IIASA.

With CROs in place, carbon debt is penalized through interest payments. Should CROs be rolled out rapidly, the interest on carbon debt would incentivize large-scale near-term CO2 removal on top of conventional emission reductions. This would help to minimize carbon debt and its associated risks, and consequently facilitate a more rapid path to net-zero than scheduled by most countries.

###

UB team analyzes the impact of climate change in dry and hot periods in the Pyrenees

UNIVERSITY OF BARCELONA

 NEWS RELEASE 

Research News

IMAGE

IMAGE: PYRENEES VIEW. view more 

CREDIT: B. BONMATÍ

A team of the University of Barcelona has analysed for the first time what the dry and hot periods could be like in the area of the Pyrenees depending on different greenhouse emission scenarios. The results, published in the journal Natural Hazards and Earth System Sciences, show that under an intermediate scenario, where these emissions that accelerate the climate change could be limited, there would not be a rise in long-lasting dry episodes, but temperatures would rise during these periods. On the other hand, if those emissions were not reduced during the 21st century, the summer no-rain periods would last an average of five more and, in addition, they would go with a rise of temperatures 6ºC over the current ones in the Pyrenees. According to the authors, these results would involve "a potential increase in environmental risks such as wildfires, crop yield losses, negative effects on biodiversity and water resources, etc.".

The study counts on the participation of the researcher Marc Lemus-Canovas, from the Climatology Groupof the UB, and the lecturer Joan Albert López-Bustins, from the Department of Geography. Both are members of the Water Research Institute of the UB.

Two variables that increase environmental risks

The study analysed, on the one hand, whether the length of consecutive days without rain has increased or will increase in the future, and on the other, whether the highest temperatures during the long-lasting dry periods will be higher than the current ones. This is the first time these variables are studied together in the area of the Pyrenees, in an approximation that enables avoiding an underestimation of the risk these climate conditions bring to the area. "Plants are under a hydric stress due to a combination of a long-lasting dry periods and a high temperature, and the stress is higher than if we analyse one of the compounds. The concurrence of long-lasting dry periods and extremely hot temperatures can bring environmental risks such as wildfires, crop yield losses, and in general, serious problems regarding the biodiversity of this area, which would not be detected by considering only one of the variables", says Marc Lemus.

The study used climate data from several parts of the Pyrenees (Catalan Pyrenees, Aragon Pyrenees, etc.) from 1981 to 2015, in the information obtained from the work carried out at the Pyrenees Climate Change Observatory, thanks to the CLIMPY project, which enabled recovering a great part of climate series. "These data show that to date, the risk of the simultaneous concurrence of long-lasting droughts and extreme temperatures has been increased by the raise of one of these cmpounds: temperature. This has taken place similarly in spring and summer and over the general area of the Pyrenees", notes the researcher.

More and more extreme temperatures

In order to estimate the evolution of these two variables during the rest of the 21st century, the researchers considered two out of the future scenarios of greenhouse emissions established by the UN Representative Concentration Pathways group. "Under an intermediate scenario of emissions (RCP4.5), assuming that by the middle of the century the emissions will start a process of stabilization and that by 2100 there will not be a growing trend of gas emissions, the pattern will continue to be the same: temperatures will be more extreme when these dry spells occur, but the length of these dry periods will not increase", describes the researcher.

On the other hand, this situation would substantially change under a scenario of high emissions (RCP8.5), where the volume of emissions would continue to rise during the whole century. Under these conditions, the authors detected that there would be, in spring, an increase in the length of dry periods, mainly in the eastern side of the Pyrenees, and a strong increase in thermal extremes during these dry spells. "Regarding summer, the length of days without rain will increase notably in the northern side of the Pyrenees (the wettest area of this territory) and there will also be a rise of extreme temperatures. The less exposed area to this factor in both elements would be the western area, with a higher Atlantic influence", notes Marc Lemus. According to the researchers, these results highlight the importance of stopping the increasing trend of greenhouse emissions. "We saw it is not ideal in an intermediate scenario because the thermal increase is notable. However, a dramatic increase in the length of dry periods and in extreme temperatures at the same time could lead to a catastrophic scenario, due to the involvements it could have in a fragile area where the 59% of the surface is covered by forests", they warn.

In this sense, the research states that this study should provide "more arguments to the provision of public resources for the actors that work on forest and ecological management of the Pyrenees, in order to adapt it for the future. And mainly, to promote a mitigation policy on climate change which is our pending subject", he concludes.

Recently, the Climatology Group of the UB has received a favourable resolution from the Spanish Ministry on Science and Innovation for the grant of a research project titled "Eventos compuestos secos y cálidos en la España peninsular", which will enable the team to receive resources to continue working on this research line for the next three years.

###

 

Many nonprofits, companies report using commercial species in tree planting projects

NORTH CAROLINA STATE UNIVERSITY

Research News

Nonprofits and companies planting trees in the tropics may often pick species for their commercial rather than ecological value, researchers found in a new analysis of organizations' publicly available data. They also found many may not have tracked the trees' survival.

Tree planting is a promising, but controversial, restoration strategy for fighting climate change. A new study in the journal Biological Conservation provides a detailed look at what restoration organizations across the tropics are actually doing on the ground.

"We found some organizations placed an emphasis on biological diversity and forest restoration in their mission statements. When we looked at the species they reported planting, many organizations reported planting commercial species, with chocolate, mango and teak in the top five," said the study's first author Meredith Martin, assistant professor of forestry and environmental resources at NC State. Martin led the study with researchers from The Nature Conservancy, a nonprofit that was also included in the analysis.

For the study, researchers analyzed publicly available data from websites and annual reports for 136 nonprofits and 38 for-profit companies, gathered using internet searches and referrals from Yale University's Environmental Leadership and Training Initiative. Their analysis included projects focused on forest conservation, economic development, or humanitarian aims in 74 different countries, all located in the tropics or subtropics. Brazil, Kenya and Indonesia were the countries with the largest number of projects.

Of these organizations, 118 reported the numbers of trees they planted. In total, they reported planting a total of 1.4 billion trees since 1961. At their estimated average rate of planting in the tropics, it would take more than a thousand years to plant a trillion trees - a goal set by at least three global initiatives.

Organizations reported planting a total of 682 species - a fraction of the roughly 50,000 species of trees found in the tropics, Martin said. Without having access to data about numbers of trees planted by species, they estimated the percentage of organizations planting certain species. The most commonly reported species, ranked by number of projects reporting those species, were cacao, teak, moringa, mango and coffee.

Nearly half of the groups didn't mention their planting method. The most common planting method was agroforestry, which is the integration of trees into animal or crop farming operations. Ten percent talked about planting using assisted regeneration, seven percent focused on enrichment planting, and two percent focused on natural regeneration.

"There's been a lot of research looking at natural regeneration, which is protecting a forest and letting it regrow," Martin said. "It can be cheaper, and more effective in terms of accumulating biomass and species diversity. There are also ways of assisting regeneration to encourage the species you want."

Thirty-two individual organizations mentioned monitoring tree survival. Of those, eight mentioned measuring survival rates and seven mentioned maintenance of plantings. Three groups gave detailed information about monitoring, and two mentioned they worked with outside groups for monitoring or certification.

"If you're not monitoring whether the trees you're planting are surviving, or taking steps to ensure they're surviving or growing, that could be a waste of money and effort," Martin said.

Researchers say the findings are important as groups increasingly look to plant trees to mitigate climate change.

"Trees are natural and incredibly efficient carbon capture entities," Martin said. "They're also living organisms. They're not just machines we can put down anywhere. Organizations need to be thoughtful about what species they are going to use and how they make sure they match the environment, as well as tracking to make sure they're not wasting money on something that doesn't work."

###

The study, "People plant trees for utility more often than for biodiversity or carbon," was published online in Biological Conservation on July 7, 2021. In addition to Martin, the other authors were David J. Woodbury, Danica A. Doroski, Eliot Nagele, Michael Storace, Susan C. Cook-Patton, Rachel Pasternack and Mark S. Ashton. Funding was provided by The Nature Conservancy to Yale University under grant No. P117456, GLT Global Forestry and Wood Products. Martin completed the work while based at Yale.

Note to editors: The abstract follows.

"People plant trees for utility more often than for biodiversity or carbon"

Authors: Meredith Martin, David J. Woodbury, Danica A. Doroski, Eliot Nagele, Michael Storace, Susan C. Cook-Patton, Rachel Pasternack and Mark S. Ashton.

Published online July 7, 2021, in Biological Conservation.

DOI: 10.1016/j.biocon.2021.109224

Abstract: Tree planting is both a promising and controversial solution to climate change and biodiversity loss. However, this controversy is largely theoretical because we lack detailed information of how tree planting is proceeding on-the-ground. Here, we compiled a pantropical dataset of 174 tree planting organizations to determine the type of organizations involved in tree planting, their geographic locations and tree planting approaches. We found that the number of organizations have increased by 288% in the past 30 years, especially for-profit organizations. These organizations reported planting nearly 1.4 billion trees across 74 countries since 1961. Most frequently organizations reported establishing agroforestry systems or mixed species and single species plantations or using assisted natural regeneration suggesting that tree planting programs are designed to support local communities as well as environmental objectives. Moreover, the most frequently reported species were commercial or utilitarian, with the top five including cacao, teak, moringa, mango and coffee. Finally, despite widespread efforts to plant more trees, there was a pronounced lack of monitoring on websites and in reports; only 18% of organizations mention monitoring at all, and only 5% mention measuring survival rate of plantings. Greater transparency and greater communication are needed between planting organizations and researchers to apply the most effective ways to restore forest cover. Further, while organizations often aimed to counter environmental problems, the use of the same sets of commercially useful species to meet economic development goals across the global indicates a need for greater coordination among organizations to avoid biotic homogenization.

FIRST PERSON 'SHOOTER' GAME

Red Dead Redemption 2 teaches players about wildlife

UNIVERSITY OF EXETER

Research News

IMAGE

IMAGE: BLUE JAY view more 

CREDIT: MATTHEW SILK

Players of the popular game Red Dead Redemption 2 learn how to identify real American wildlife, new research shows.

The game, set in the American West in 1899, features simulations of about 200 real species of animals.

The new study, by the University of Exeter and Truro and Penwith College, challenged gamers to identify photographs of real animals.

On average, RDR2 players were able to identify 10 of 15 American animals in a multiple-choice quiz - three more than people who had not played the game.

The best performers were players who had completed the game's main storyline (meaning they had played for at least 40-50 hours) or had played more recently.

As well as learning to identify wildlife, some players reported learning about animal behaviour and ecology.

One gamer who participated in the study said RDR2 taught them how to spot a ram that's about to charge, adding: "No joke saved me from breaking a leg in real life."

Dr Sarah Crowley, of the Centre for Geography and Environmental Science at the University of Exeter, said: "The level of detail in Red Dead Redemption 2 is famously high, and that's certainly the case in terms of animals.

"Many of the animals not only look and behave realistically, but interact with each other. Possums play dead, bears bluff charge and eagles hunt snakes."

Co-author Dr Matthew Silk added: "The game features a couple of species that are now much rarer, and one - the Carolina parakeet - that's extinct.

"Hunting played a role in the Carolina parakeet's extinction; if players shoot this species in the game, they are warned of their endangered status. If they continue shooting, the species becomes extinct, highlighting the environmental consequences of players' actions."

The study used real photos of 15 species featured in the game, including the white-tailed deer, jackrabbit, alligator snapping turtle, lake sturgeon, blue jay and roseate spoonbill.

Gamers participating in the study could first enter the name of each animal as text, and were then shown multiple choice options.

The difference in identification skills between players and non-players was generally greatest for animals that are useful in the game, such as fish that can be caught and eaten.

Animals that are rarer in the game, such as the golden eagle, were less commonly identified.

The game also includes an online "naturalist" role that allows players to take up a new life as a protector of the Old West's wildlife - and people who had played this were better still at identifying the real-life animals.

In total, 586 people from 55 countries completed the quiz. 444 had played RDR2.

"We know that many gamers value realism, so game producers might be interested to see these findings, but we realise these games aren't designed to be educational," said Ned Crowley, of Truro and Penwith College.

"We don't expect big-budget games to include messages about conservation, but educators and conservationists can learn from the techniques used in games - such as making things immersive, and having each action mean something in terms of wider progress in the game.

"Being indoors on a computer is often seen as the opposite of engaging with nature, but our findings show that games can teach people about animals without even trying.

"Gaming is very popular, and should be taken seriously by ecologists and conservationists as a force for communication."

CAPTION

White-tailed deer

CREDIT

Matthew Silk

The paper, published in the journal People and Nature, is entitled: "The educational value of virtual ecologies in Red Dead Redemption 2."