CHAPTER SEVENTEEN RICHARD A. TRACY SUSTAINABLE BUILDING MATERIAL TRANSITION IN THE UNITED STATES: TOWARD A SUSTAINABLE FUTURE
Not so long ago Buckminster Fuller reminded us that we are all travelers on Spaceship Earth. Since that time there has been a growing concern and awareness about how we manage the natural environment and resources within that environment. One need only look at the increase in fuel efficiency in automobiles to see evidence of this trend. Evidence of this trend may also be found in the building industry. That industry is constantly looking for new technology to save energy. The explosion in the number of materials with increased insulative capacities is just one example of this search for better technology. It is important that planners, architects, engineers, builders, and governmental bodies realize the necessity for responsible use of natural resources. The building industry uses these resources in both the construction and the operation of buildings. In addition, the industry uses vital resources at the end of the life of a building. These resources are used for the demolition and disposal of materials from a building. As fuller reminded us, we are part of an intricate system. That system has its limitations and advantages. Some of the resources within the system can be regenerated, some cannot. While it is important to understand that technology plays an important role in the building industry, it is equally important to realize that money may play an even bigger role. Clearly these new technologies come at a cost to the consumer. Thus, in addition to the building industry's responsibility, there is a large measure of responsibility placed on the consumer. It is the focus of this paper to deal with the issues of resource use in the building industry. Specifically, this paper will deal with the topic of renewable and nonrenewable resources as they apply to the materials used for the structure of buildings. Of interest are the choices people in the United States make with regard to the way they build in the context of the environment as a whole. Of particular interest is the comparison of the impact of traditionally popular methods/materials of construction and "Green" or "Sustainable" methods/materials of construction. It may be of some great use to define sustainability in terms of its use within this paper. In this paper sustainability is best defined in the words used by the Rainforest Action Network to define sustainability for their home page on the World Wide Web. "Sustainability is when the functions and processes of an ecosystem can be maintained (or sustained) while the needs of the present are met without compromising the needs of future generations."(Rainforest Action Network, 1995) This notion of sustainability has a great deal of importance in the discussion and evaluation of new technologies. There are many new building materials and methods of construction developed each year. What is important to evaluate is not just the performance of these materials and methods, but the impacts these materials/methods have on the environment. The manufacture of new materials can have profound ecological ramifications. Too often these ramifications are not weighed in the overall evaluation of new materials. The example of asbestos insulation comes to mind. We are now faced with finding ways of removing and disposing of a health threatening material used in hundreds, if not thousands, of buildings here in the United States. It is now clear that the costs of manufacture, removal, and disposal (or recycling) of building materials must be taken into account when evaluating building materials. Another cost to consider is the cost involved in developing a sustainable replacement. Life Cycle Assessment At this point it is useful to bring up the issue of life-cycle assessment. Life-cycle assessment is a means of applying a "cradle-to-grave" or "cradle-to-cradle" approach to looking at buildings and building materials.(Wilson, 1995) In other words, it is looking at buildings and their components from their origins to the eventual demise and/or the potential reuse of specific components or the building as a whole. How are materials obtained? What types and amounts of pollutants, if any, are given off during manufacture? Are there health concerns during manufacture, installation, use or disposal? What happens at the end of the material's useful life? It is important to note the difference between life-cycle assessment (LCA) and life-cycle cost analysis (LCCA). "Life-cycle costing applies economic principles for the specific purpose of improving design and management of resource allocation decisions by considering the total long-term costs of facility ownership."(Johnson, 1990) In other words, life-cycle cost analysis allows us to consider purchase, operating, and maintenance costs of a piece of equipment. This enables one to make the choice between several options and potentially justifies the selection of an initially more costly system, such as compact fluorescent lights, over an initially cheaper alternative, such as incandescent lights. The key difference being that LCCA takes into account only traditional economic factors. Brandle (Brandle, 1995) expresses the following concerns: "1) The prices of nonrenewable resources are low. They do not reflect the real costs, only the production and marketing costs. The costs of depletion are not included. 2) The burden of paying for inefficiencies and waste, mostly as pollution, is often not carried by those who cause it. This is most evident in the difficulties of assigning responsibility for the pollution of air, water, and earth. 3) The dangers from depleting nonrenewable resources and the benefits from using renewable resources for overall society are not well understood by the general public."(Brandle, 1995) It is apparent that some form of ecological currency is necessary. Some have argued that ecological currency is a part of economic currency. These individuals usually point to the example of gasoline. Currently gasoline prices in the United States hover somewhere around $1 per gallon. In the United Kingdom the cost is over $2 per gallon. In Italy the price is nearly $4 per gallon.1 In his course Energy, Entropy, and the Environment, Rycus argues that as accessible reserves are diminished the cost of oil will increase. This price increase, in turn, is evidence of ecological currency being a factor of economic currency. However, Rycus is quick to point out that the point at which this price increase begins to affect the general populace's thinking and buying habits can be at a point beyond that of sustainability. It is evident that some means of translating ecological cost into economic costs at earlier stages may be necessary. However this is not without certain risks. Classical economic theory holds that correct prices are an essential factor for maximizing economic benefits. Some may argue that this may also hold true for prices reflecting the truth about external costs. This does not necessarily hold true at all times. Unforeseen or abrupt changes, even for the better, may cause massive upheavals and economic losses. The painful restructuring of the economies of Eastern Europe are a good example of this.(Dutch Committee for Long-Term environmental Policy, 1994) Great care must be taken in introducing ecological costs at earlier stages of the proposed building materials transition. One can also see that it is necessary that better systems of accountability for pollution should be devised. Those parties wasting materials should bear the burden of doing so. This burden should also be heavy enough so as to encourage the reduction, if not the elimination, of inefficiencies in material usage. It is also apparent that the general population should be made aware of the dangers of depleting nonrenewable resources. As the general population in the U.S. elects the officials who control many resource management policies, the education of the general population would aid in obtaining governmental officials who are sensitive to the very same issues. Another pitfall of conventional life-cycle cost analysis is that it traditionally considers the life of a building to be 20-40 years. There are wood structures all across the United States with ages exceeding 100 years. Within the confines of conventional thinking a building becomes disposable after a 20-40 year lifetime. This is somehow appropriate coming from the land of disposable diapers. This type of thinking cannot exist if sustainable development is to occur. Greater attention must be given towards the adaptive reuse of structures. In addition to the reuse of structures, Brandle (Brandle, 1995) encourages the exploration of design for recycling. He states, "the concept of recycling must become as much a part of building design as the other concepts of design that we are so familiar with, such as functional integrity and aesthetic appearance."(Brandle, 1995) He points to the work of the German auto manufacturer BMW as an example. BMW is pushing for as near complete recyclability of an automobile as possible. They are literally designing some of their cars for disassembly. Brandle points to the obvious transfer of this type of thinking into building terms. He points to the graduate level design studio he recently conducted as an example of this type of thinking. Students were encouraged to design such structural systems as pre-cast concrete panels with bolt connections to enhance the reusability of these elements. Traditionally these systems are connected by welding or site-cast concrete joints. These types of joints make recyclability very tenuous at best. Brandle also encouraged students to specify components made from recycled wood, automobile tires, and aluminum or steel.(Brandle, 1995) Life-cycle assessment is clearly necessary. It will develop somewhat differently than traditional life-cycle cost analysis. Though LCA may development differently than LCCA its development is necessary for both sustainable design and for the successful building materials transition proposed by this text. Conditions and Trends Over the years building construction methods in the United States have gone through a series of changes. Early methods used timber framing for structural support. Later, brick and stone were used. Then came an interesting system called "balloon framing". This system uses a series of repeated small dimensional structural members. This method has been popular for quite some time. The major application of this building system has been in the arena of housing. It appears that this method of construction became popular for several reasons. First, with increased population the supply of stone and brick materials was too small to meet building needs. Secondly, the new system of building was less economically expensive than the prior systems. However, recently there has been a trend away from this system of building structure. The use of steel and pre-engineered wood structural products seems to be increasing. It appears that the United States is in a transition of building materials. As mentioned above, one of the options is steel. Another option is pre-engineered wood products, some of which use recycled wood materials. As prime dimensional lumber is used up, there may be an increased use of laminated and recycled wood chip products. The following two graphs show and project the growth of roundwood production and the decline of steel production. From the two graphs (graph; next graph) one sees a steady decline in steel usage and a steady increase in sawnwood production. This is somewhat different than what is occurring in the architectural world today. Presently, in some markets in the U.S. it is cheaper to use residential scale steel structural members than it is to use wood. This is an alarming trend when put in the total ecological context. Steel is a nonrenewable resource. We should carefully consider how we use this resource. In light of the more environmentally friendly option that engineered wood products offer, the application of steel on the residential market seems a bad move in the long run. The graphs bear witness to the economic pressures put on the market. With decreasing steel production the demand appears to be low and the price must therefore be low. With the steadily increasing sawnwood production we see an increased demand and an increased price. Current national average prices bear out this line of thinking. As an example, a typical wall assembly consisting of 2x4 stud with 5/8 fire resistant drywall on both sides of the stud costs roughly $2.98 per square foot of the wall assembly. A comparable assembly substituting a 35/8 metal stud for the wood member costs roughly $2.80 per square foot of the wall assembly. However, we should also bear in mind the ecological as well as the economic costs involved. Building Materials At this point it may be useful to discuss the definitions of some of the terms that will be used frequently in this paper. First among these terms is "dimensional" lumber. Nearly everyone has heard of a "two-by-four".2 This is a piece of wood with nominal dimensions3 of two inches thickness and four inches width producing a simple rectangular cross section. The same follows for other pieces of dimensional lumber: 2"x6", 2"x8" and so forth. The largest pieces used in typical house construction are 2"x12". These are used primarily for the support of floors on long spans. Traditionally, these pieces of wood were cut from the large, old trees of the forest. These trees yielded better quality lumber than smaller, faster growing trees. In addition to quality there is also the factor of quantity. The larger the tree cut for lumber is the greater the dimension of the lumber cut from that tree.
Two-by-four cross section
Glue-laminated timber Once spans stretch beyond the capacity of a 2"x12" a different type of lumber may be necessary. This type of lumber is the glue laminated timber. This type of lumber is constructed of a series of 1.5" wood laminations.(Wright, 1994) This type of structural member can be manufactured in a variety of different sizes to fit various spanning conditions. These timbers are manufactured under tightly controlled conditions. Another important type of wood based building product is LVL or Laminated Veneer Lumber. This type of lumber generally consists of a series of thin wood layers affixed to one another with a resin of some sort. The fibers of each layer can be oriented so as to give the structural member the greatest strength. LVL construction is similar to plywood except that the grain of alternate layers is not oriented at right angles to that of adjacent layers.
Laminated Veneer Lumber
This type of lumber can be manufactured in any number of sizes. It can be used similarly to plywood and is an important component in the next type of wood structural member. Again, this type of lumber is manufactured under tightly controlled conditions. The next type of wood structural member is the wooden I-joist. This element, like LVL is manufactured under rigidly controlled conditions. It consists of two flanges made up of a series of 1/10-inch wood veneers or stress-rated (high quality dimensional) lumber. The other component of I-joists is the web which is commonly made with plywood or oriented strand board (OSB). Oriented strand board is a panel type material made from wood strands that have face wafers oriented in the long direction to provide additional strength in that direction.(Wright, 1994)
OSB/Plywood Web
One may ask why it is important to manufacture the above mentioned elements under tightly controlled conditions. The answer lies in the fact that when these controls are in place, the load bearing capacity of the member can be more precisely determined. This allows for a savings in the amount of wood materials used. With traditional dimensional construction only "mother nature" controls the production of the materials. The load bearing capacity of a member can thus vary significantly from one 2"x4" to the next. This then requires a large margin of safety in the structural design process and leads to a greater degree of overdesign of the structural systems. Clearly this has an environmental impact. The last structural building element this paper will deal with is the metal (or steel) stud. This is a piece of metal, usually a roughly hollow tube-like construction, that is often used in place of traditional dimensional lumber in wall assemblies. The load bearing capacity of this type of material is even better known than the manufactured wood products mentioned above. Thus these elements can be used with even greater structural efficiencies. This type of material is seen as a significant competitor to wood. Such thinking could have serious repercussions on the environment. In addition to being a nonrenewable resource steel is also a good conductor of heat. The application of steel/metal members in an exterior wall structural system leads to an increased loss of heat through the buildings skin. Engineered wood products have a few drawbacks. They pose potential off-gassing hazards as well as potential chemical pollution from their manufacture. This leads to potential health and ground water problems. In the past one of the biggest pollution problems was the use of formaldehyde as part of an adhesive in manufactured wood products. The use of this material is being quickly phased out. In fact, some of the newer products use a process or pressing wood scraps under great pressure to form a beam. The pressure and resultant heat release chemicals in the wood scraps that form a binding agent. Pre-engineered wood products have some potential benefits as well. First, as mentioned above they can be made using recycled wood materials. A quick look at construction site waste is very telling.
Survey of Construction Waste (GBB, 1995)
Concrete 32.9%
Dimen. Wood 15.1%
Roofing 9.6%
Metal 8.8%
Other 8.1%
Cardboard 7.5%
Brick 6.7% Drywall 6.6% Pallets 2.6% Asphalt 0.6% Plastic 0.5
Plywood 0.5%
Clearly dimensional wood is one of the top contributors to construction waste. It is estimated that as much as 11% of traditional lumber may be thrown away on job sites due to poor quality. When engineered lumber is used that number drops below one 1%.(Wright, 1994) The use of finger jointing this scrap wood, formerly put into landfills or burnt for fuel, into larger pieces is a viable solution to the waste problem that leads to an additional saving of wood.(Loken, Miner, Mumma; 1994) In addition to the waste at the job site there is waste at the manufacturing site of all wood products. One company, Trus Joist MacMillan, claims that its manufacturing process for engineered wood I-joists converts 43% more of a log into structural lumber than does solid-sawn (dimensional) lumber.(Wright, 1994) Traditional sawmilling converts 40.6% of any given log, by weight, into dimensional lumber. Trus Joist MacMillan says that its process converts 58% of a given log into its TJI/15 joists, in addition to yielding a small amount of plywood.(Wright, 1994) It is apparent that some headway is being made towards the more efficient use of our forests. Secondly, engineered wood products can provide structural lumber from fast growing, small trees. This would add great value to the smaller diameter trees of second and third growth forests.(Loken, Miner, Mumma; 1994) With a dwindling supply of straight, dimensionally stable heartwood it may be argued that builders will turn, more and more, to other options such as engineered wood and metal products. Finally, engineered wood products allow for a greater efficiency in structural design. This directly translates into a savings, both in the number of elements used per project versus dimensional lumber and less lumber per element versus dimensional lumber. That means that not only are you using fewer pieces of wood, you are using less wood per piece. At this point it may be of particular use to look at a series of transitions that affect and interact with the proposed building materials transition. The other transitions examined will be the demographic transition, the forestry transition, and the urbanization transition. Each of these transitions has potential consequences for the building materials transition. Demographic Transition Drake (Drake, 1993)characterizes the demographic transition as follows. At the onset of the transition the numbers of births and deaths are high and are in relative equilibrium with each other. During the transition death rates drop dramatically. After a period of time the birth rates begin to fall. If these two rates track on another then growth may be significant, yet manageable.(Drake, 1993) The graph below roughly shows the crude birth and death rates tracking one another. Clearly, the United States is in a period of relative equilibrium following a demographic transition. The U.S. is in a position of manageable population growth and thus has some hope of being able to sustainably manage its natural resources. If the birth and death rates do not track one another there can be a population explosion. The second graph below shows the birth and death rate for Africa. Clearly Africa is in the midst of a demographic transition. Africa has little hope of being able to sustainably manage its natural resources while it is in the grip of a demographic transition.
Crude birth and death rate for the United States
It is important to note that all data in the graphs beyond 1995 is projected. What impact does this have on the proposed building materials transition in the United States? One obvious relationship is drawn from the population. A greater population size means a greater usage of resources. More specifically, a greater number of buildings are built and thus more steel, concrete, wood, and other materials are used. This puts a direct stress on those resources. With a manageable population, i.e. one that has gone through the demographic transition, there is hope of managing those resources sustainably. A prolonged demographic transition could lead to a collapse/depletion of natural resources. In that situation the population would be growing at a great rate and using an ever increasing amount of natural resources. A population undergoing a demographic transition has very little, if any, hope of managing its resources sustainably in the short term. Included directly above is a graph showing the demographic transition for the continent of Africa. On the whole the graph shows a wide gap between the crude birth and death rates. This is an indicator of rapid population growth for the continent. The graph is included to show a region undergoing the population transition. Any country, continent, or geographical region at a similar point in the demographic transition would not be in a position favorable to the proposed building materials transition. The population growth pressure would put great pressure on building material resources. People would be looking to obtain whatever building materials they could, as cheaply as they could. This could potentially slow or even halt a transition towards sustainable building materials. Forestry Transition The forestry transition is similar to the demographic transition. At its outset a large percentage of a region is covered with forest. During the transition rapid deforestation occurs. At the end of the transition forest cover stabilizes at a level lower than was previously the case.(Drake, 1993) The graph below shows an increasing gap between the total forest cover and the extent of the natural forest cover. The gap shows that the extent of natural forest cover as a portion of the total forest cover is decreasing. This is significant for two reasons. The first is that the United States is continuing to use up its old growth forests. The second significance of this graph is that there is an attempt being made to replace wood harvested, although the decline of total forest cover is evidence that this replacement is not on a one for one basis.
Total Forest vs. Natural Forest Extent in the United States
With respect to the proposed building materials transition, the forestry transition has several implications. First is the eventual necessity of using faster growing, smaller diameter trees form second and third growth forests. This shift occurs either because of the total depletion of old growth forests or it occurs as a result of conservation efforts. As noted earlier in this text this shift towards the use of smaller, faster growing trees is occurring in the United States. This is evidenced by increases in the use of glue laminated lumber, LVL, and engineered wood I-joists.
Roundwood Production--industrial
The graph above clearly shows the link between increased population and increased demand for roundwood. A shift towards utilization of smaller, faster growth tree species could aid in meeting this demand while slowing or reversing total forest area depletion. This can be an important factor with respect to the environment as a whole. As forest land is depleted, there is more soil erosion. This erosion can lead to ground water contamination and the reduction of arable land. Both of these factors directly affect the lives of the population in terms of drinkable water and the amount of food produced. This can put the population (human, plant and animal) at risk. What bearing does this have on other countries? Certainly any country at the start of, or midst of, a sustainable building materials transition should look to information about their forestry assets and practices. If large numbers of old growth trees exist the price of products made from these old trees may be smaller than the prices of sustainable materials. In turn, this could slow or halt a transition towards sustainable building materials. Attention must also be paid as to what is being done to replace the trees harvested. Are the species being planted the same as the ones that are harvested? Perhaps faster growing trees are being planted. If the latter is the case it must be made clear that the same building materials are not obtained from the two different types of trees. There is a reduction in size and quality of materials that can be obtained. Urbanization Transition As with the above transitions, the urbanization is characterized at the outset by a large rural population and a small urban population. This transition is driven by two factors. The first is the rural to urban migration of the population. The second is the growth of the existing urban population.(Drake, 1993)
Rural vs. Urban Population in the United States
In the later stages of the transition urban population growth declines and potentially reverses itself. The above graph shows that the United States is in a period following an urbanization transition. Urban population growth may be slowing. With the rapid growth of the suburbs, some may argue that the trend is reversing. The graph below shows the beginnings of an urbanization transition in Africa. Currently the urban population is increasing at a rate that is beginning to surpass the rural growth rate. Again it should be brought to the readers attention that all post 1995 data in the graphs is projected data. From this projected data it appears that the rural and urban populations of Africa will reach the turning point somewhere near the year 2020.
Rural vs. Urban Population in Africa.
Again, what does this information mean in terms of the proposed building materials transition? As with the demographic transition there are obvious connections between the number of people and the number of dwelling units. This, as before, impacts the natural resources of the region. However, the urban transition is likely to lead to higher population densities. The graph below clearly represents the occurrence of this trend in the United States. Higher densities also usually lead to different building materials. These are traditionally nonrenewable materials. The significance of this is that there is some savings in the amount of materials used for construction in high density construction although those materials may be nonrenewable. Higher density construction means a potentially smaller total exterior building surface area. This not only saves materials, and thus natural resources in the form of building materials, but also allows for a savings in energy usage. Population Density in the United States
Policy Implications There are several policy implications fostered by a proposed transition of building materials. First, forest management policies will be impacted. As evidenced in the graph entitled "Total Forest vs. Natural Forest Extent in the United States" which appears in the Forestry Transition section of this text, the amount of total forest cover in the United States is decreasing. Steps must be taken to halt this reduction of forest cover or a transition to sustainable building materials may not be possible. Great care must be used in halting this forest cover reduction. Sandra Postel and John C. Ryan point out that, "When diverse populations of trees are replaced with genetically uniform stands, future timber harvests are put at risk."(Postel & Ryan, 1991) Efforts must be made to maintain biodiversity. Secondly waste disposal policies must be changed. The cost of disposing of materials in a landfill should carry some weight in the decision of discard materials. An example of this is the formal plan to recycle wastes during the construction of the $262 million Portland Trailblazers' Arena project in Portland, Oregon. All contractors' bid specifications included a section on waste management. With 62% of construction complete, nearly 97% of construction debris was sent to recyclers. This saved and estimated $141,000 in landfill dumping fees.(Building Design and Construction, 1995) The fact that this recycling program was prompted by high dumping fees shows that this type of policy change can be an effective way of channeling ecological costs into economic costs. Lastly, the general public and governmental bodies must be made aware of the ramifications of their choices of building materials and policies. While this may be difficult, it is a worthwhile endeavor. One need only look at the spiraling national debt of the federal government of the United States to see the consequences of ignoring future costs. That government is facing substantial cuts in its programs of elderly health insurance and student financial aid. The short sighted approach to policy can clearly have drastic, long term repercussions. Recommendations
1) A transition towards sustainable building materials/methods should be encouraged. This could be the encouraged use of potentially renewable materials such as wood. It could also take the form of adaptive reuse of structures. In addition, it could also take the form of reuse of specific, nonrenewable building components. Certainly this should become a part of the education of every designer and builder.
2) As the earlier discussion of Life-Cycle Assessment suggested, the early merging of ecological and economic costs should be studied and striven for. This has been described by others as a series of phases:
Phase 1: Environmental pollution as a side effect.
Phase 2:
Environmental pollution as a cost factor
Polluters begin to see that it may be beneficial to reduce pollution
levels (adaptations at process level).
Phase 3:
The environment as a boundary condition
Polluters incorporate the environmental factors when planning new
investments, and are thereby forced to produce or consume
differently (adaptations at process and product levels).
Phase 4:
The environment as a policy-determining factor
The environment factor plays a role for polluters when optimizing
their activities, and this leads to different system designs (adaptation
at system level).
Phase 5:
The environment as an objective
Society incorporates the environment as a logical factor and goal in
social and economic policy. As a result of this, there will be
changes in the pattern of production and consumption as well as in
the mental attitudes (adaptations at structural level){Dutch Committee
for Long-
Term Environmental Policy}
Currently the United States is in Phase 2. The example of the
Portland
Trailblazers project clearly demonstrates that environmental pollution
is
beginning to be seen as having a cost. This train of thought
leads
directly to the next recommendation.
3) The cost of dumping materials in landfills should be raised
to a
level which encourages builders to minimize the amount of materials
they
dump. Certainly this should go hand in hand with an increased
recycling
effort to re-use those items that are, at present, thrown away on a
construction site.
4) The widespread use of sustainable materials should be encouraged
through governmental actions. This could take the form of building
design standards that specify the amount of nonrenewable materials
that
can be used in a building. Several states already mandate the
maximum
amount of energy a building can use during one year. Similar
thinking
and legislation could apply to nonrenewable building materials.
5) An effort should be made so that all people, from the business
executive to the factory worker, are aware of how their decisions about
building materials affect the environment. This may sound like
grand,
abstract thinking. However, each of us spends countless hours
of our
lives in buildings of one sort or another. Our use of these structures
implies a responsibility for these structures: for their design, use
and
eventual demolition, recycling, or reuse. We all make decisions
regarding our responsibility, whether it be to take an active role
in the
decision making process or to ignore the decision making process
entirely. Those decisions are of vital importance to the continued
existence of humankind on the spaceship Earth.
NOTES
1. All dollar amounts are in U.S. dollars.
2. Common designation 2x4.
3. It is important to note the difference between nominal and
actual
dimensions. For example; a 2x4 has actual dimensions of 1.5x3.5.
REFERENCES
1.Kurt Brandle, The Systems Approach to Sustainability in Building,
paper
presented to the Architectural Institute of Korea, 4/29/95.
2.William D. Drake, Population-Environment Dynamics, chapter XIV Towards
Building a Theory of Population-Environment Dynamics: A Family of
Transitions, copyright 1993, University of Michigan Press.
3.Dutch Committee for Long-Term Environmental Policy (editor),The
Environment: Towards A Sustainable Future, copyright 1994, published
by
Kulwer Academic Publishers.
4.Robert Johnson, The Economics of Building, copyright 1990.,
published
by John Wiley & Sons, INC.
5.Steve Loken, Rod Miner, Tracy Mumma, Guide to Resource Efficient
Building Elements 4th. ed., copyright 1994, published by the Center
for
Resourceful Building Technology.
6.Sandra Postel and John C. Ryan, State of the World 1991, Chapter
5
Reforming Forestry, copyright 1991 Worldwatch Institute, published
by
W.W. Norton and Company.
7.Alex Wilson, P/A April 1995, How Green is Your Building? .
8.Gordon Wright, Building Design and Construction, February 1994,
Ecology and Economy Boost Use of Engineered Wood.
9.Building Design and Construction, February 1995, Arena's waste
recycling plan pays dividends.
ELECTRONIC REFERENCES
10. Rainforest Action Network, Rainforest Action Network
Home Page,
World Wide Web.