{"id":114600,"date":"2013-04-17T16:32:52","date_gmt":"2013-04-17T19:32:52","guid":{"rendered":"http:\/\/revistapesquisa.fapesp.br\/?p=114600"},"modified":"2017-03-07T17:48:10","modified_gmt":"2017-03-07T20:48:10","slug":"amazonia-in-three-dimensions","status":"publish","type":"post","link":"https:\/\/revistapesquisa.fapesp.br\/en\/amazonia-in-three-dimensions\/","title":{"rendered":"Amazonia in three dimensions"},"content":{"rendered":"
\"The

ASTRONAUT PHOTOGRAPH ISS017-E-13856\/ NASA<\/span>The forest as seen from the International Space Station: 150 kilometers of the Amazon River, its tributaries and the many lakes and floodplains along its courseASTRONAUT PHOTOGRAPH ISS017-E-13856\/ NASA<\/span><\/p><\/div>\n

The trees appear as red, yellow and other vibrant colors, as if each had been hand-painted on the maps posted alongside scientific articles and invitations to seminars in the hallway of the building that is home to the Biological Dynamics of Forest Fragments Project (BDFFP) at the National Institute for Amazonian Research (Inpa) in the Brazilian city of Manaus. The technique that made it possible to assemble the maps\u2014LiDAR, or Light Detection and Ranging, which records variations in light reflected by the trees\u2014is greatly facilitating the work of the researchers in the oldest tropical-forest monitoring program in Brazil, one of the world\u2019s longest-running programs of its type. Launched in 1979 to gauge the impact of road construction and expanded farming on the Amazon forest, the BDFFP monitors changes over time in 11 forest fragments, as well as in adjacent continuous forest areas that serve as controls for comparison purposes. The total area under study encompasses a thousand square kilometers (km\u00b2) of forest and includes trees up to 55 meters in height.<\/p>\n

Until a few years ago, the only way to obtain detailed data on forest composition and changes was to travel for many hours on unpaved roads in rain, heat, mosquitoes and fungi to reach the areas under study, some of which are 80 kilometers from Manaus. \u201cThis new technique will of course not solve all of our problems, nor will it spare us from making field trips, but it\u2019s a great help,\u201d says Jos\u00e9 Lu\u00eds Camargo, an ecologist from S\u00e3o Paulo State and scientific coordinator of the BDFFP, which is presently funded by the Smithsonian Institution and Inpa, in conjunction with research-supporting foundations and agencies in both Brazil and the United States. Satellite images are two-dimensional, but LiDAR images are three-dimensional. They are created from light reflected off the tops of trees and captured by planes flying over the areas under study. \u201cWe can map clearings, which are important to the functioning of the forest, and get a good idea of the relief that sustains the vegetation,\u201d Camargo says.<\/p>\n

LiDAR, alone or in combination with other remote sensing techniques, can provide detailed data on the height, concentration and distribution of trees and can indicate which animal groups are likely to be living there. A more matted\u2014or, as Camargo says, structurally complex\u2014forest is less likely to be a habitat for certain groups of birds and bats, for example. In a recently completed study in one of the project areas, Brazilian biologist Karl Mokross of Louisiana State University in the U.S. confirmed that birds living in the understory\u2014the area below the tree canopy\u2014prefer to feed on insects in the primary forest, and rarely feed in the secondary forest, also known as the capoeira.<\/p>\n

\"\"<\/a>In addition to using three-dimensional images, the Inpa team borrowed from the field of chemistry a technique for identifying chemical compounds, known as near-infrared spectroscopy, to classify plants. This technique is based on the fact that the chemical bonds of certain molecules have specific vibration frequencies. These frequencies can be recorded by an instrument and expressed in graphical form. Using this method, biologist Fl\u00e1via Machado Durgante and other researchers at Inpa examined 159 leaves from 10 tree species collected from a preserved forest area near Manaus and from the BDFFP study areas and retained in the program\u2019s collection, which currently has 54,000 samples of leaves and reproductive structures (flowers and fruits) from the monitored trees. They then obtained the so-called spectral signature of each species and concluded that the technique is a simple, low-cost method for identifying plant species and differentiating very closely related species, even when they lack reproductive structures such as flowers and fruits that would facilitate recognition by botanists and ecologists. In their paper, published in March in the journal Forest Ecology and Management, they reported an average accuracy of 96.6%. Biologist Carla Lang has begun to analyze the spectral signatures of leaves from trees and seedlings of the same species to determine whether they are consistent with one another. If so, this will facilitate the rather difficult work of identifying seedlings and predicting the distribution of species in the forest.<\/p>\n

Early alliances<\/strong>
\nThe working methods now available provide a modicum of well-deserved comfort for the researchers in the Amazon studies program that two biologists from the U.S., Thomas Lovejoy and David Conway Oren, started designing in the mid-1970s. Both had already had several years of experience conducting field research in the region. At that time, the government was promoting occupation of the forests north of Manaus by cattle ranchers. \u201cI was the one who alerted Lovejoy about this unique opportunity to talk with the land owners, go into the forest prior to deforestation and do biological inventories\u2014something that had not been done in Panama,\u201d recalls Oren, an ornithologist who has worked at Inpa, the Goeldi Museum and the Federal University of Par\u00e1 (UFPA) at Bel\u00e9m and who is currently the biodiversity coordinator for the Ministry of Science, Technology and Innovation (MCTI). The biologists did not forget the fact that construction of the Panama Canal, completed in 1914, had isolated areas of a tropical forest about which they knew very little. Lovejoy liked the idea and said he would seek funding.<\/p>\n

\"Flocks

SCOTT SALESKA \/ UNIVERSITY OF ARIZONA AND MICHAEL LEFSKY \/ COLORADO STATE UNIVERSITY <\/span>Flocks of birds (in red<\/em>) prefer the primary forest in a 10-hectare fragment…SCOTT SALESKA \/ UNIVERSITY OF ARIZONA AND MICHAEL LEFSKY \/ COLORADO STATE UNIVERSITY <\/span><\/p><\/div>\n

Lovejoy became the program\u2019s spokesman and became an international authority on biodiversity. He is presently a professor of environmental science and policy at George Mason University in the United States (see Pesquisa FAPESP<\/em> n\u00ba 171<\/a>). A clipping of a page from the journal A Prov\u00edncia do Par\u00e1 from January 7, 1979, which hangs in the hallway of the building that houses the BDFFP, announces the Minimum Critical Size of Ecosystems Project, as it was then called, with expected annual costs of $500,000 and support from Inpa, the Brazilian Institute for Forestry Development (IBDF), which gave rise to the Brazilian Institute of the Environment and Renewable Natural Resources (IBAMA), and the Manaus Free Trade Zone Authority (Suframa). Determining the minimum area needed to effectively preserve a forest was a concern of the Brazilian government, as well as \u201ca global problem,\u201d argued Lovejoy, who at the time was with the World Wildlife Fund (WWF), the first international institution to fund this work.<\/p>\n

\u201cIt was the golden age of Inpa, under the direction of Warwick Kerr. In just a day or two, I received approval from the director and the head of Inpa\u2019s Department of Ecology, Herbert Schubart, and from Suframa, which was also very open to the idea. The cattle ranchers cooperated as well,\u201d Lovejoy said, recalling the creation of the research program in Amazonia. \u201cI basically accompanied Rob (Richard Bierregaard, a biologist and first scientific coordinator of the BDFFP, now with the University of North Carolina at Charlotte in the U.S.), introduced him to the people in Manaus and left him to work. Rob made friends with the ranchers, who were pleased to participate in work that was receiving media attention.\u201d<\/p>\n

The program provided for isolation of forest areas of varying sizes and for surveying and monitoring of trees, insects, amphibians, reptiles, birds and mammals. The objective was to determine which species die off and which survive as the forest decreases in size. This program was a way to examine the impact of fragmentation on the forest and the organisms that live there. Even today, the reduced size of the native vegetation that has resulted from the expansion of roads, agriculture and cattle ranching is a principal cause of the loss of biodiversity in Amazonia, the world\u2019s largest tropical forest.<\/p>\n

Amazon database<\/strong>
\nThe field work, conducted over a 33-year period and completed in 2012, resulted in an immense database of trees and birds. The researchers are now observing the growth of 45,376 trees and 178,295 saplings (less than 10 centimeters in diameter at chest height) on 55 hectares of continuous forest and 39 hectares of fragmented forest. \u201cWe are monitoring a forest with one of the most diverse tree communities in the world,\u201d Camargo says. In addition to monitoring trees, they recently began to include records for lianas. In a recently completed survey on 69 hectares, they counted 33,154 lianas. \u201cLianas are generally not a subject of forest surveys, but they represent an important component of a forest\u2019s biomass and biodiversity.\u201d<\/p>\n

\"...

SCOTT SALESKA \/ UNIVERSITY OF ARIZONA AND MICHAEL LEFSKY \/ COLORADO STATE UNIVERSITY <\/span>… and seldom traverse the capoeira (in light green, magnified at right<\/em>) SCOTT SALESKA \/ UNIVERSITY OF ARIZONA AND MICHAEL LEFSKY \/ COLORADO STATE UNIVERSITY <\/span><\/p><\/div>\n

The database contains information on 60,000 birds from 400 species that live in the understory, the intermediate level between the canopy and the forest floor. Each bird was banded with a number that will enable biologists to learn where they have been when they are captured in what are called \u201cmist nets.\u201d \u201cThis database enables us to ask more complex questions that arise only after decades of monitoring and that build a basis for public policies and help solve new problems such as the impact of climate change on Amazonia,\u201d Camargo says. \u201cMany researchers come to work here because we have a long track record, so they don\u2019t need to start at square one. This knowledge is a national asset.\u201d<\/p>\n

Many conclusions of the BDFFP would have been impracticable in a shorter-term study, according to a January 2011 article in the journal Biological Conservation that synthesizes 32 years of field work. The article is signed by 16 biologists from institutions in Brazil, the United States, Australia and Mexico connected with the BDFFP. The first author is U.S. biologist William Laurance, who lived in Manaus for five years and is currently working in Australia. The vulnerability of large trees to fragmentation and the effects of ephemeral events such as El Ni\u00f1o and storms, they argue, became evident only after decades of monitoring. They noted that when trees fall, they may create clearings that draw moisture away from nearby trees and alter the light and temperature (see illustration<\/em><\/a>). Fragmentation can reduce water circulation; limit the territory of many species of birds that are unable to traverse large deforested areas; reduce the populations of bees, wasps, beetles and ants; and increase the populations of frogs and spiders. These changes result in a cumulative loss of biodiversity and a reduction in water reserves.<\/p>\n

Fragile forest<\/strong>
\nSimulations of forest behavior using data from the BDFFP suggested that even 10-hectare fragments need at least a century to recover their earlier biological diversity and biomass. Once established, these fragments undergo a profound reorganization of their communities of trees, palms, climbing plants, and animals. \u201cAs a general rule, the smaller the area, the more severe the effects of fragmentation,\u201d says Camargo. Anyone passing through the study areas will notice the difference: the smaller fragments of a hectare or less in size have now lost part of their original forest structure and look like a capoeira struggling to survive, while the larger fragments, particularly those 100 hectares in size, still harbor tree species that grow in the low light and high moisture conditions that are typical of an Amazon forest. Small areas are more fragile \u201cand suffer more from more intense droughts, such as those that occurred in 2005 and 2010,\u201d Camargo observes.<\/p>\n

\"044-049_Amazonia_205-2\"<\/a>One consequence of fragmentation is the so-called edge effect: changes that occur at the edges of a forest due to solar radiation, light and wind from outside the periphery of the forest. Because they are exposed to more changes in the microclimate, the trees closest to the edge may fall more easily or dry up and die standing. As a result of the edge effect and forest fragmentation, \u201chalf the understory birds and mammals may become locally extinct, sometimes irreversibly so,\u201d Camargo warns. According to the 2011 article, deforestation to open up pastureland creates 32,000 kilometers of new forest edge each year and produces landscapes dominated by irregularly shaped small fragments of less than 400 hectares, which increases the effect of solar radiation and wind on the native vegetation. \u201cIf it\u2019s this way here, it may be even worse in other areas, such as the Arc of Fire, the region in the states of Par\u00e1, Mato Grosso and Rond\u00f4nia that is the most subject to deforestation.\u201d<\/p>\n

Two days ago, you couldn\u2019t get through the hallway because of all the luggage,\u201d Camargo said on the morning of November 9, 2012. \u201cOur twenty-first training course ended yesterday. We\u2019ve trained 420 ecologists.\u201d Every year, the course in Amazonian Landscape Ecology\u2014usually held in July or August and occasionally in October, as it was last year\u2014brings together 20 graduate students and 15 professors from universities throughout Brazil. \u201cMost of the participants have never set foot in Amazonia,\u201d Camargo says. The professors introduce the different environments in the region, from the v\u00e1rzea, or floodplain, to archipelagos such as Anavilhanas, to train professionals to understand and help solve the problems in the region.<\/p>\n

Another way to share the researchers\u2019 findings and increase understanding of the region is through three-week courses for undergraduate students. \u201cRecently, I was one of the people responsible for that course at the Universidade Estadual Paulista (Unesp) in Rio Claro, the State University of Minas Gerais and the Federal University of Amazonas,\u201d Camargo says. \u201cToday the BDFFP trains more researchers from Brazil than from the United States.\u201d<\/p>\n

\"Roads

SERGIO JORGE BRAZIL \/ PHOTONONSTOP<\/span>Roads like this one destroy forest unity and create fragments that limit the movements of animals, reduce biodiversity and affect climateSERGIO JORGE BRAZIL \/ PHOTONONSTOP<\/span><\/p><\/div>\n

According to Camargo, at the present time, the Smithsonian and Inpa cover only 20% of the annual costs, and most of the annual budget of R$1.2 million comes from grants or from funding agencies or foundations in the United States and Brazil. \u201cIn the past decade, it was difficult to obtain funding because the focus of the grants changed. The money migrated from forest fragmentation studies to climate change studies,\u201d Camargo notes. \u201cAnother major problem we face is the devaluation of the dollar. Some years we lose a third of the anticipated budget because of the exchange rate.\u201d There are other concerns, such as a possible redistribution of land near the study areas, which could change the land use and amplify the negative impacts on the fragments.<\/p>\n

Scientific articles<\/em>
\nDURGANTE, F.M. et al<\/em>. Species spectral signature: Discriminating closely related plant species in the Amazon with near-infrared leaf-spectroscopy.<\/a> Forest Ecology and Management<\/strong>. v. 291, pp. 240-248. 2013.
\nLAURANCE, W. et al.<\/em> The fate of Amazonian forest fragments: a 32-year investigation. Biological Conservation<\/a>. v. 144, n. 1, p. 56-67. 2011.
\nSTARK, S.C. et al.<\/em> Amazon forest carbon dynamics predicted by profiles of canopy leaf area and light environment<\/a>. Ecology Letters<\/strong>. v. 15, n. 12, p. 1.406-14. 2012.<\/p>\n","protected":false},"excerpt":{"rendered":"Maps show details of forest structure and native vegetation","protected":false},"author":17,"featured_media":0,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"_exactmetrics_skip_tracking":false,"_exactmetrics_sitenote_active":false,"_exactmetrics_sitenote_note":"","_exactmetrics_sitenote_category":0,"footnotes":""},"categories":[159],"tags":[224],"coauthors":[5968],"class_list":["post-114600","post","type-post","status-publish","format-standard","hentry","category-science","tag-ecology"],"acf":[],"_links":{"self":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts\/114600","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/users\/17"}],"replies":[{"embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/comments?post=114600"}],"version-history":[{"count":0,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/posts\/114600\/revisions"}],"wp:attachment":[{"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/media?parent=114600"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/categories?post=114600"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/tags?post=114600"},{"taxonomy":"author","embeddable":true,"href":"https:\/\/revistapesquisa.fapesp.br\/en\/wp-json\/wp\/v2\/coauthors?post=114600"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}