Wood economy


The existence of a wood economy, or more broadly, a forest economy (since in many countries a bamboo economy predominates), is a prominent matter in many developing countries as well as in many other nations with temperate climate and especially in those with low temperatures. These are generally the countries with greater forested areas. The uses of wood in furniture, buildings, bridges, and as a source of energy are widely known. Additionally, wood from trees and bushes, can be employed in a wide variety, including those produced from wood pulp, as cellulose in paper, celluloid in early photographic film, cellophane, and rayon (a substitute for silk).


At the end of their normal usage, wood products can be burnt to obtain thermal energy, or can be used as a fertilizer. The potential environmental damage that a wood economy could occasion include (problems of reduction the biodiversity due to monoculture forestry—the intensive cultivation of very few types of trees); and CO2 emissions. However, forests can aid in reduction of atmospheric carbon dioxide and therefore decrease global warming.[1]




A massive log raft headed down the Columbia River (year 1902), containing an entire year's worth of logs from one timber camp.




Contents





  • 1 Introduction

    • 1.1 History of use of wood


    • 1.2 Dimensions and geography


    • 1.3 Importance in fighting greenhouse effect



  • 2 Per nation/continental area

    • 2.1 In Australia


    • 2.2 In Brazil


    • 2.3 In Canada and the US

      • 2.3.1 Canada


      • 2.3.2 US



    • 2.4 In the Caribbean and Central America


    • 2.5 In Europe

      • 2.5.1 Italy


      • 2.5.2 Portugal



    • 2.6 In Scandinavia and Russia



  • 3 Uses of wood


  • 4 Combustion

    • 4.1 Charcoal


    • 4.2 Wood gasogen


    • 4.3 Methanol


    • 4.4 Gas turbine

      • 4.4.1 Tanks




  • 5 Construction

    • 5.1 Bridges, levees, microhydro, piers


    • 5.2 Housing

      • 5.2.1 Earthquake resistant buildings



    • 5.3 Shipbuilding



  • 6 History of crisis in wood economies

    • 6.1 Classical Greece


    • 6.2 Rapa Nui



  • 7 See also


  • 8 Notes and references


  • 9 Bibliography

    • 9.1 In English


    • 9.2 In Italian



  • 10 External links

    • 10.1 In English:


    • 10.2 In Italian:





Introduction



History of use of wood


The wood economy is historically the starting point of the civilizations worldwide, since eras preceding the Paleolithic and the Neolithic. It necessarily preceded ages of metals by many millenia, as the melting of metals was possible only through the discovery of techniques to light fire (usually obtained by the scraping of two very dry wooden rods) and the building of many simple machines and rudimentary tools, as canes, club handles, bows, arrows, lances. One of the most ancient handmade articles ever found is a polished wooden spear tip (Clacton Spear) 250,000 years old (third interglacial period), that was buried under sediments in England, at Clacton-on-Sea.[2][3]


Successive civilizations such as the Egyptians and Sumerians built sophisticated objects of furniture. Many types of furniture in ivory and valuable woods have survived to our time practically intact, because secluded in inviolated secret tombs, they were protected from decay also by the dry environment of desert.[4] Many buildings and parts of these (above all roofs) contained elements in wood (often of oak) forming structural supports and covering; means of transport such as boats, ships; and later (with the invention of the wheel) wagons and carriages, winches, flour mills powered by water, etc.



Dimensions and geography


The main source of the lumber used in the world is forests, which can be classified as virgin, semivirgin and plantations. Much timber is removed for firewood by local populations in many countries, especially in the third world, but this amount can only be estimated, with wide margins of uncertainty.


In 1998, the worldwide production of "roundwood" (officially counted wood not used as firewood), was about 1,500,000,000 cubic metres (2.0×109 cu yd), amounting to around 45% of the wood cultivated in the world. Cut logs and branches destined to become elements for building construction accounted for approximately 55% of the world's industrial wood production. 25% became wood pulp (including wood powder and truccioli) mainly destined for the production of paper and paperboard, and approximately 20% became panels in plywood and valuable wood for furnitures and objects of common use (FAO 1998).[5] The World's largest producer and consumer of officially accounted wood is the United States, although the country that possesses the greatest area of forest is Russia.


In the 1970s, the countries with the largest forest area were: Soviet Union (approximately 8,800,000 km²), Brazil (5,150,000 km²), Canada (4,400,000 km²), United States (3,000,000 km²), Indonesia (1,200,000 km²) and Democratic Republic of Congo (1,000,000 km²). Other countries with important production and consumption of wood usually have a low density of population in relation to their territorial extension, here we can include countries as Argentina, Chile, Finland, Poland, Sweden, Ukraine.[citation needed]


By 2001 the rainforest areas of Brazil were reduced by a fifth (respect of 1970), to around 4,000,000 km²; the ground cleared was mainly destined for cattle pasture—Brazil is the world's largest exporter of beef with almost 200,000,000 head of cattle.[6] The booming Brazilian ethanol economy based upon sugar cane cultivation, is likewise reducing forests area. Canadian forest was reduced by almost 30% to 3,101,340 km² over the same period.[7]



Importance in fighting greenhouse effect


Regarding the problem of climate change, it is known that burning forests increase CO2 in atmosphere, while intact virgin forest or plantations act as sinks for CO2, for these reasons wood economy fights greenhouse effect. The amount of CO2 absorbed depends on the type of trees, lands and the climate of the place where trees naturally grow or are planted. Moreover, by night plants do not photosynthesize, and produce CO2, eliminated the successive day. Paradoxically in summer oxygen created by photosynthesis in forests near to cities and urban parks, interacts with urban air pollution (from cars, etc.) and is transformed by solar beams in ozone (molecule of three oxygen atoms), that while in high atmosphere constitutes a filter against ultraviolet beams, in the low atmosphere is a pollutant, able to provoke respiratory disturbances.[8][9]


In a low-carbon economy, forestry operations will be focused on low-impact practices and regrowth. Forest managers will make sure that they do not disturb soil based carbon reserves too much. Specialized tree farms will be the main source of material for many products. Quick maturing tree varieties will be grown on short rotations in order to maximize output.[10]



Per nation/continental area



In Australia



  • Eucalyptus: these are seven hundred tree species from Australia, that grow very fast in tropical, sub-tropical and semi-arid climates, and are very resistant to forest fires (with their tree cortex) and drought. Its essential oil is used in pharmacology, its wood for building, and the small branches as firewood and pulpwood.


In Brazil


Brazil has a long tradition in the harvesting of several types of trees with specific uses. Since the 1960s, imported species of pine tree and eucalyptus have been grown mostly for the plywood and paper pulp industries. Currently high-level research is being conducted, to apply the enzymes of sugar cane fermentation to cellulose in wood, in order to obtain methanol, but the cost is much higher when compared with ethanol derived from corn costs.[11]



  • Brazilwood: has a dense, orange-red heartwood that takes a high red shine (brasa=ember), and it is the premier wood used for making bows for string instruments from the violin family. These trees soon became the biggest source of red dye, and they were such a large part of the economy and export of that country, that slowly it was known as Brazil.[12]


  • Hevea brasiliensis: is the biggest source of the best latex, that is used to manufacture many objects in rubber, as an example gloves, condoms, anti-allergic mattresses and tires (vulcanized rubber). Latex has the ability to adjust to the exact shape of the body part, an advantage over polyurethane or polyethylene gloves.


In Canada and the US


There is a close relation in the forestry economy between these countries; they have many tree genera in common, and Canada is the main producer of wood and wooden items destined to the US, the biggest consumer of wood and its byproducts in the world. The water systems of the Great Lakes, Erie Canal, Hudson River and Saint Lawrence Seaway to the east coast and the Mississippi River to the central plains and Louisiana allows transportation of logs at very low costs. On the west coast, the basin of the Columbia River has plenty of forests with excellent timber.



Canada


The agency Canada Wood Council calculates that in the year 2005 in Canada, the forest sector employed 930,000 workers (1 job in every 17), making around $108 billion of value in goods and services. For many years products derived from trees in Canadian forests had been the most important export items of the country. In 2011, exports around the world totaled some $64.3 billion – the single largest contributor to Canadian trade balance.[7][13]


Canada is the world leader in sustainable forest management practices. Only 120,000,000 hectares (1,200,000 km2; 463,320 sq mi) (28% of Canadian forests) are currently managed for timber production while an estimated 32,000,000 hectares (320,000 km2; 123,550 sq mi) are protected from harvesting by the current legislation.[14]



US




Logging in Oregon



  • Cherry: a hardwood prized for its high quality in grain, width, color, and rich warm glow.[15] The first trees were carried to the lands surrounding Rome (Latium) from Armenia.[16] In the United States, most cherry trees are grown in Washington, Pennsylvania, West Virginia, California and Oregon.[17]


  • Cedar: this genus is a group of conifers of the Pinaceae family, originating from high mountain areas from the Carpathians, Lebanon and Turkey to the Himalayas. Their scented wood make them suitable for chests and closet lining. Cedar oil and wood is known to be a natural repellent to moths.[18] Actually are planted in western and southern US, mostly for ornamental purposes, but also for the production of pencils (specially incense-cedar).


  • Douglas fir: a native tree of the United States west coast and mountain states, with records in fast growth and high statures in brief time. The coast Douglas fir grows in coastal regions up to altitudes of about 1,800 meters; the Rocky Mountain Douglas fir grows farther inland, at altitudes ranging from 800 m to 3,000 m or higher. The wood is used for construction, for homebuilt aircraft, for paper pulp, and also as firewood.


  • Hybrid poplar is being investigated by Oak Ridge National Laboratory in Tennessee [19][20] for genetic engineering in order to obtain a tree with a higher content of cellulose and a lower content in lignin, in such a way that the extraction of bioethanol (useful as a fuel) could be easier and less expensive.


  • Walnut: a prized furniture and carving hardwood because of its colour, hardness, grain and durability. Walnut wood has been the timber of choice for gun makers for centuries. It remains one of the most popular choices for rifle and shotgun stocks.[21]


In the Caribbean and Central America



  • Mahogany: has a straight grain, usually free of voids and pockets. The most prized species come from Cuba and Honduras. It has a reddish-brown color, which darkens over time, and displays a beautiful reddish sheen when polished. It has excellent workability, is available in big boards, and is very durable. Mahogany is used in the making of many musical instruments, as drums, acoustic and electric guitars' back and side, and luxury headphones.


In Europe



Italy


The species that are ideal for the many uses in this type of economy are those employed by arboriculture, that are very well known for their features and the need for certain types of ground and climates.



  • Fraxinus: being a lightweight wood is easy to transport, as firewood burns easily, grows in damp environments like those present in river flooding areas, stands pollution of water and air.


  • Larix: in Italy it grows at high altitudes around mountain tops, its timber stand sudden climatic change, from icy winds to high temperatures in sunny afternoon summers, it is excellent for use in the building of exposed structures as bridges, roofs, etc.


  • Stone pine: "Mediterranean pine" could be the noble emblem of many coastal areas in Italy, originally giant forests of pines extended from the mouth of the Tiber river until Liguria and Provence in France, over soils with high salinity, not very apt for agriculture. Its trees produce a vast amount of dry branches that can be burnt, cones (used for Christmas decoration) and needle-like foliage that can be burnt, or used as mulch. Oils and resins can be used in scents and ointments. The pinoli are useful elements in Italian cooking (along with basil are tritured to make pesto sauce). Currently, "progress" has brought to a severe reduction of this magnificent tree extensions, and in many places cheap beach buildings, car-parking and semi-abandoned areas have taken their place.


  • Poplar: in Italy is the most important species for tree plantations, is used for several purposes as plywood manufacture, packing boxes, paper, matches, etc. It needs good quality grounds with good drainage, but can be used to protect the cultivations if disposed in windbreak lines. More than 70% of Italian poplar cultivations are located in the pianura Padana. Constantly the extension of the cultivation is being reduced, from 650 km² in the 1980s to current 350 km². The yield of poplars is about 1,500 t/km² of wood every year.[22] The production from poplars is around 45–50% of the total Italian wood production.[23]
    • In the history of art poplar was the wood of choice for painting surfaces as panels, as in Renaissance (The Mona Lisa by Leonardo da Vinci). Because of this reason, many of the products with the highest added value, extremely expensive, are made with wood from the humble but durable poplar.

    • Because of the presence of tannic acid, poplar cortex was often used in Europe for the tanning of leather.



Portugal



  • Oak for cork: are trees with a slow growth, but long life, are cultivated in warm hill areas (min. temp. > -5°Celsius) in all the west area of Mediterranean shores. Cork is popular as a material for bulletin boards. Even if the production as stoppers for wine bottles is diminishing in favor of nylon stoppers, in the sake of energy saving granules of cork can be mixed into concrete. These composites have low thermal conductivity, low density and good energy absorption (earthquake resistant). Some of the property ranges of the composites are density (400–1500 kg/m³), compressive strength (1–26 MPa) and flexural strength (0.5–4.0 MPa).[24] Because of this cork can be used as thermal isolation in buildings (as well in its natural form and as a mixture), useful also as sound insulation. In the shoe industry cork is used for soles and insoles. In the world there are 20,000 km² of cork oak plantations, and every year are extracted around 300,000 tons of cork, 50% in Portugal, 15,000 in Italy (12,000 in the island of Sardinia). The advantage of this natural industry is that the extraction of cork from layers outer to the cortex does not kill the tree.


In Scandinavia and Russia


In Sweden, Finland and to an extent Norway, much of the land area is forested, the pulp and paper industry is one of the most significant industrial sectors. Chemical pulping produces an excess of energy, since the organic matter in black liquor, mostly lignin and hemicellulose breakdown products, is burned in the recovery boiler. Thus, these countries have high proportions of renewable energy use (25% in Finland, for instance). Considerable effort is directed towards increasing the value and usage of forest products by companies and by government projects.



  • Scots pine and Norway spruce: These species comprise most of boreal forest, and together as a softwood mixture they are converted chemical pulp for paper.


  • Birch: is a genus with many species of trees from Scandinavia and Russia, excellent for acid grounds. They act as pioneer species in the frozen border between taiga and tundra, are very resistant to periods of drought and icy conditions. The species Betula nana has been identified as the ideal tree for the acid grounds of the sides of sloped mountains, also in southern Europe, with soils poor in nutrients, where these trees can be used to restrain landslides. Dissolving pulp is produced from birch. Xylitol can be produced by hydrogenation of xylose, which is a byproduct of chemical pulping of birch.


Uses of wood




Combustion



The burning of wood is currently the largest use of energy derived from a solid fuel biomass. Wood fuel may be available as firewood (e.g. logs, bolts, blocks), charcoal, chips, sheets, pellets and sawdust. Wood fuel can be used for cooking and heating through stoves and fireplaces, and occasionally for fueling steam engines and steam turbines that generate electricity. For many centuries many types of traditional ovens were used in order to benefit from the heat generated by wood combustion. Now, more efficient and clean solutions have been developed: advanced fireplaces (with heat exchangers), wood-fired ovens, wood-burning stoves and pellet stoves, that are able to filter and separate pollutants (centrifuging ashes with rotative filters), thus eliminating many emissions, also allowing to recover a higher quantity of heat that escaped with the chimney fumes.


Mean energy density of Wood, was calculated at around 6–17 Megajoule/Kilogram, depending on species and moisture content.


Combustion of wood is, however, linked to the production of micro-environmental pollutants, as carbon dioxide (CO2), carbon monoxide (CO) (an invisible gas able to provoke irreversible saturation of blood's hemoglobine), as well as nanoparticles.[25]


In Italy poplar has been proposed as a tree cultivated to be transformed into biofuels, because of the excellent ratio of energy extracted from its wood because of poplar's fast growing and capture of atmospheric carbon dioxide to the small amount of energy needed to cultivate, cut and transport the trees. Populus x canadensis 'I-214', grows so fast that is able to reach 14 inches (36 cm) in diameter and heights of 100 feet (30 m) in ten years.



Charcoal



Charcoal is the dark grey residue consisting of impure carbon obtained by removing water and other volatile constituents from animal and vegetation substances. Charcoal is usually produced by slow pyrolysis, the heating of wood or other substances in the absence of oxygen. Charcoal can then be used as a fuel with a higher combustion temperature.



Wood gasogen


Wood gas generator (gasogen): is a bulky and heavy device (but technically simple) that transforms burning wood in a mix of molecular hydrogen (H2), carbon monoxide (CO), carbon dioxide (CO2), molecular nitrogen (N2) and water vapor (H2O). This gas mixture, known as "wood gas", "poor gas" or "syngas" is obtained after the combustion of dry wood in a reductive environment (low in oxygen) with a limited amount of atmospheric air, at temperatures of 900° Celsius, and can fuel an internal combustion engine.[26]




A car built in the 1940s by Ilario Bandini, with a wood gas generator device.


In the time between World War I and World War II included, because of the lack of oil, in many countries, like Italy, France, Great Britain and Sweden, several gasoline-powered cars were modified, with the addition of a wood gas generator (a "gasogen"), a device powered by wood, coal, or burnable waste, able to produce (and purify) gas that immediately, in the same vehicle, could power a slightly modified ICE engine of a standard car (low-compression engine). Carburetor had to be changed with an air-gas mixer). There were several setbacks, as the great reduction of maximum speed and the need to drive using low gears and wisely dosing the amount of air. In modern cars, modified with a wood gas generator, gas emissions (CO, CO2 and NOx) are lower to those of the same vehicle running with gasoline (keeping the same catalytic converter).



Methanol



Methanol (the simplest alcohol) behaves as a liquid at 25 °C, is toxic and corrosive, and in organic chemistry basic books is often called "the spirit of wood", since it can be obtained from wood fermentation. Rarely, when unwise wine-makers mix small chunks of wood and leaves with grapes, methanol can be found as a pollutant of the blend of water, ethanol and other substances derived from grape's fermentation.


The best way to obtain methanol from wood is through syngas (CO, CO2, H2) produced by the anhydrous pyrolysis of wood, a method discovered by ancient Egyptians.


Methanol can be used as an oxygen-rich additive for gasoline. However, it is usually much cheaper to produce methanol from methane or from syngas. Methanol is the most important base material for industrial chemistry, where it is often used to make more complex molecules through reactions of halogenation and chemical addition reaction.



Gas turbine



Tanks


The American M1 Abrams main battle tank is powered by a gas turbine of 1,500 hp (1,100 kW),[27] that it is able to function also with a mix at 50% of wood powder and biodiesel, diesel fuel or kerosene. Its advantages over turbo-diesel engine, are the small size and light weight, the lack of a radiator (which gives an advantage against the effect of gun and cannon shots and missile strikes suffered in battle). A setback is the high fuel consumption, since the turbine engine has not the ability to work at a low revolutions per minute rate, much lower than ideal, and during the march this engine consumes twice as much fuel as a modern turbo-diesel engine with intercooler and direct injection.



Construction



Wood is relatively light in weight, because its specific weight is less than 500 kg/m³, this is an advantage, when compared against 2,000-2,500 kg/m³ for armed concrete or 7,800 kg/m³ for steel.


Wood is strong, because the efficiency of wood for structural purposes has qualities that are similar to steel.




















MaterialE/f
Concrete(Rck300, fck 25 M-Pascal)1250
Structural steelFe430 (ft = 430 MPa)480
Glued laminated timber(BS 11 ÷ BS 18)470
Aluminium(alloy 7020, ft 355 MPa)200


Bridges, levees, microhydro, piers


Wood is used to build bridges (as the Magere bridge in Amsterdam), as well as water and air mills, and microhydro generators for electricity.



Housing


Hardwood is used as a material in wooden houses, and other structures with a broad range of dimensions. In traditional homes wood is preferred for ceilings, doors, floorings and windows. Wooden frames were traditionally used for home ceilings, but they risk collapse during fires.


The development of energy efficient houses including the "passive house" has revamped the importance of wood in construction, because wood provides acoustic and thermal insulation, with much better results than concrete.



Earthquake resistant buildings


In Japan, ancient buildings, of relatively high elevation, like pagodas, historically had shown to be able to resist earthquakes of high intensity, thanks to the traditional building techniques, employing elastic joints, and to the excellent ability of wooden frames to elastically deform and absorb severe accelerations and compressive shocks.


In 2006, Italian scientists from CNR patented[28] a building system that they called "SOFIE",[29] a seven-storey wooden building, 24 meters high, built by the "Istituto per la valorizzazione del legno e delle specie arboree" (Ivalsa) of San Michele all'Adige. In 2007 it was tested with the hardest Japanese antiseismic test for civil structures: the simulation of Kobe's earthquake (7.2 Richter scale), with the building placed over an enormous oscillating platform belonging to the NIED-Institute, located in Tsukuba science park, near the city of Miki in Japan. This Italian project, employed very thin and flexible panels in glued laminated timber, and according to CNR researchers could brought to the construction of much more safe houses in seismic areas.[30]



Shipbuilding


One of the most enduring materials is the lumber from virginian southern live oak and white oak, specially live oak is 60% stronger than white oak and more resistant to moisture. As an example, the main component in the structure of battle ship USS Constitution, the world's oldest commissioned naval vessel afloat (launched in 1797) is white oak.[31]



History of crisis in wood economies



Classical Greece


One of the most famous crisis of a wood-based economy is what happened in Classical Greece, where trees began to disappear specially in the areas of Attica, Boeotia and Peloponnesus where indiscriminate cutting of trees for several uses, associated to drought and wildfires led to a severe lack of timber in order to build lances, shields, ships, etc. and to a slow but progressive weakening in military and naval power of the peninsular kingdoms in Greece, that were overwhelmed by Epirus and by the Kingdom of Macedon, much more fertile lands because of their rainy winters. This process arrived to the apex with the conquest of Greece by Phillip II of Macedon.


The secret weapon of the Sarissaphoros soldiers (supported by peltast javelineers), commanded by Philipp II in the Battle of Chaeronea (338 BC) and in those that followed fought by Alexander the Great (which brought to the conquest of Lesser Asia, Babylon, Persia and Egypt), was the sarissa, a type of pike, longer and stronger (5–7 m.) than the other Greek lances, obtained from the heavy and strong cornel wood.[32]



Rapa Nui


Rapa Nui, best known as "Easter Island", is a typical example of malthusianism,[33] specifically how the exponential growth of a populace leads to the end of a renewable resource. At a certain point, the compelling societal need forces exploitation of the resource above and beyond the resource's natural rate of renewal.


It has been calculated [34] that after the year 1000, around 10 million palmtrees were cut in Rapa Nui, resulting in the erosion of the fertile land, and eventually to a desertification around the 15th century. (This deforestation may have also been aggravated and/or caused by a rat infestation[35]). This provoked a population reduction from 15,000 to 2,500 individuals. Without palmtree wood, no boats, or lances could be constructed. Without palm fibers, construction of ropes and fishing nets halted. This led to a decrease in the local fish harvest, which in turn led to a decrease in the quantity of dietary protein available to the island's inhabitants. At the end, the society became an easy prey for hunger and civil war. From 1600 to 1700, the people became superstitious in a fanatical way. In the last moments, there was a disintegration of society and total chaos. The destruction of the traditional symbols followed, leading to the eventual extinction of the Moais civilization and culture, even if there was not any external human enemy.



See also


  • Autarchy

  • Biofuels

  • Biomass

  • Forestry

  • Forest Stewardship Council

  • Hardwood

  • Low-carbon economy

  • Lumber

  • Wood


Notes and references




  1. ^ "Adaptation of Forests and Forest Management to Changing Climate with Emphasis on Forest Health: a Review of Science, Policies, and Practices. Umeå, Sweden. August 25-28, 2008". Retrieved 13 May 2017..mw-parser-output cite.citationfont-style:inherit.mw-parser-output .citation qquotes:"""""""'""'".mw-parser-output .citation .cs1-lock-free abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-limited a,.mw-parser-output .citation .cs1-lock-registration abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-subscription abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registrationcolor:#555.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration spanborder-bottom:1px dotted;cursor:help.mw-parser-output .cs1-ws-icon abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Wikisource-logo.svg/12px-Wikisource-logo.svg.png")no-repeat;background-position:right .1em center.mw-parser-output code.cs1-codecolor:inherit;background:inherit;border:inherit;padding:inherit.mw-parser-output .cs1-hidden-errordisplay:none;font-size:100%.mw-parser-output .cs1-visible-errorfont-size:100%.mw-parser-output .cs1-maintdisplay:none;color:#33aa33;margin-left:0.3em.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-formatfont-size:95%.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-leftpadding-left:0.2em.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-rightpadding-right:0.2em


  2. ^ Tecnologia Dalle Origini al 2000, pag. 18


  3. ^ "The Clacton Spear". Natural History Museum. Archived from the original on October 28, 2014. Retrieved 2012-02-16.


  4. ^ "History of Egyptian Furniture". 27 October 2009. Archived from the original on 27 October 2009.CS1 maint: BOT: original-url status unknown (link)


  5. ^ FAO 1998 Archived July 24, 2008, at the Wayback Machine


  6. ^ "Brazil seizes cattle illegally grazing on Amazon forest lands". Retrieved 13 May 2017.


  7. ^ ab "Canadian Forests - Quick Facts". Retrieved 13 May 2017.


  8. ^ "Air quality levels in Europe — European Environment Agency".


  9. ^ "YourLungHealth.org - The Effects of Ozone Pollution".


  10. ^ Trees and their role in carbon management for land and business Archived 2007-09-27 at the Wayback Machine, The Woodland Trust.


  11. ^ "Brazzil Mag - Trying to understand Brazil since 1989".


  12. ^ "Harvesting wood in Brazil". Retrieved 13 May 2017.


  13. ^ "Wood-Works - Program of the Canadian Wood Council".


  14. ^ "Canadian Forests Website - Home Page".


  15. ^ "Classic American Furniture for the Home and Office from Green Design Furniture".


  16. ^ A History of the Vegetable Kingdom - Page 334


  17. ^ Cherry Production National Agricultural Statistics Service, USDA, Retrieved on August 19, 2008.


  18. ^ "Cedarwood Oils".


  19. ^ "Biofuels from Trees: Renewable Energy Research Branches Out".


  20. ^ Graham, R. L.; Walsh, M. E. (1 February 1999). "A National Assessment of Promising Areas for Switchgrass, Hybrid Poplar, or Willow Energy Crop Production" – via www.osti.gov.


  21. ^ "Walnut Council--Growing Walnut and Other Fine Hardwoods".


  22. ^ "Federlegno - Italian federation of wood producers and industry". Retrieved 13 May 2017.


  23. ^ Fonte:http://www.federlegno.it/tool/home.php?s=0,1,29,37,417,1042


  24. ^ Karade SR. 2003. An Investigation of Cork Cement Composites. PhD Thesis. BCUC. Brunel University, UK.


  25. ^ Olivares G, Ström J, Johansson C, Gidhagen L (June 2008). "Estimates of black carbon and size-resolved particle number emission factors from residential wood burning based on ambient monitoring and model simulations". J Air Waste Manag Assoc. 58 (6): 838–48. doi:10.3155/1047-3289.58.6.838. PMID 18581814.


  26. ^ UNITED STATES DEPARTMENT OF AGRICULTURE Gasogens Report (Original report dated 1944): now in the possession of the University of Wisconsin


  27. ^ "AGT1500 Turbine Technology on Honeywell.com" (PDF). Archived from the original (PDF) on 9 September 2016. Retrieved 13 May 2017.


  28. ^ Girodivite.it. "Girodivite: Terremoti: dal Cnr arriva il palazzo antisismico".


  29. ^ PROGETTOSOFIE: Edificio Antisismico in Legno


  30. ^ "Dalla ricerca italiana la casa  di legno che resiste al terremoto - Il Sole 24 ORE".


  31. ^ "HMS Victory Service Life". HMS Victory website. Archived from the original on 28 August 2012.


  32. ^ "Parco Naturale Valpometto - I boschi di casa nostra".


  33. ^ "Why Easter Island Collapsed: An Answer for an Enduring Question" (PDF). Retrieved 13 May 2017.


  34. ^ "What Has Science Learned about the People Who Settled Easter Island?".


  35. ^ "USATODAY.com - Did Easter Island get 'ratted' out?".



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  • (in English) Diamond, Jared. 2005. Collapse. How Societies Choose to Fail or Succeed. New York: Viking.
    ISBN 0-14-303655-6.


  • (in English) "Construction of a Simplified Wood Gas Generator for Fueling Internal Combustion Engines in a Petroleum Emergency"


In Italian



  • (in Italian) Conti, L., Lamera C. "Tecnologie dalle Origini al 2000", Arnoldo Mondadori Editore, 1981. ISBN


  • (in Italian) Appunti del corso di formazione "Energie Alternative e Risparmio Energetico", presso Ordine degli Ingegneri di Padova, De Carli M 2006


  • (in Italian) Frank Rosillo-Calle, Biomasse. Manuale per un uso sostenibile, Franco Muzzio editore,
    ISBN 978-88-7413-160-0


  • (in Italian) Rapporto "Lo sviluppo delle rinnovabili in Italia tra necessità e opportunità", Enea 2005


  • (in Italian) Rapporto "Utilizzo energetico della biomassa", Opet (Organisations for the Promotion of Energy Technologies), 2001


External links



In English:



  • (in English) Fast Growing Trees


  • (in English) Forestry Encyclopedia - Forests and Forestry in the Americas


  • (in English) Canadian Forests - Quick Facts


  • (in English) Canadian Forests - Information Reseources


  • (in English) UNECE - FAO - Timber Committee - European Forestry Commission


  • (in English) WOODGAS: Biomass Energy Foundation (BEF) website

  • Oldest Wood house at Czech Republic


In Italian:



  • (in Italian) Distillazione gassificata dal legno, con produzione di metano, idrogeno e monossido di carbonio


  • (in Italian) Forest Sterwardship Council - Italia


  • (in Italian) Federlegno - Arredo


  • (in Italian) Jolly_Mec_Catalogo_Termojolly_IT.pdf Jolly Mec: l’economia della legna, l’efficacia dell’impianto


  • (in Italian) Holzenergie: sfruttare resti delle lavorazioni forestali e del legno


  • (in Italian) Thermojolly: economia e fascino della legna - Da caminetti supertecnologici molto più calore


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