Multiple Uses of Forests

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Multiple Uses of Forests

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ISIS Press Release 03/03/05

 

Multiple Uses of Forests

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A global trend away from monoculture tree plantations

towards multiple uses of native forests is good for

conserving forest ecosystems, but progress is hampered by a

dominant paradigm that treats forests like cornfields. Dr.

Mae-Wan Ho

 

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All commercial forests should be managed for multiple-use

 

Dr. Erkki Lähde, Finland's foremost forestry scientist, is

convinced that forests can no longer be divided into those

focussing on timber production and others with multiple

uses. Instead, all commercial forests, in Finland and

elsewhere on our planet, should be treated with their

multiple uses in mind, in order to sustain their ecology and

biodiversity in a `close-to-nature' state. Merely

safeguarding the productivity of timber and pulp – in

monoculture plantations - while preserving `key biotopes' in

their natural state is no longer considered sufficient for

species conservation.

 

I met Dr. Erkki Lähde very briefly while on a hectic lecture

tour in Finland in November-December 2004 as guest of

Finland's People's Biosafety Association, and immediately

recognized the profound significance of his work.

 

The emphasis on multiple uses of commercial forests is

particularly important for many indigenous peoples who have

been an integral part of forest ecosystems for millennium;

whose livelihoods are being threatened by deforestation,

which includes replacing native forests with monoculture

tree plantations.

 

Monoculture tree plantations are anathema to the biodiverse

native forest ecosystems of the world. The United Nations

Environment Programme (UNEP) estimated that about 60

percent, and possibly closer to 90 percent of all living

species are found in tropical forests. Thus, adopting

multiple uses of forests that can sustain their biodiversity

is extremely significant for conserving the earth's species;

and there has been a growing trend towards doing just that,

though not quite fast enough.

 

Recent research in Mexico also shows that cacao and coffee-

based agroforestry systems managed with low inputs by small

holders harbour significant biodiversity compared to the

monoculture plantations (see " Agroecology versus

ecoagriculture " , SiS 25

http://www.i-sis.org.uk/isisnews/sis25.php).

 

A major obstacle is the prevailing paradigm that treats

natural forests like cornfields

 

One major obstacle to adopting multiple uses of forests is

the lack of a good model of the natural forest ecosystem.

" The prevailing paradigm still treats natural forests as if

they are cornfields, " says Lähde, " The entire stand is

supposed to be destroyed at certain intervals by natural

disturbances such as forest fires or storms. After that a

new forest would grow from the saplings. "

 

Based on that model, thinning and clear-cutting forests are

routinely carried out to this day. The smallest and youngest

trees and the under storey are cleared away, leaving uniform

trees standing like " rows of carrots " ; and when the trees

are ready for harvesting, they are clear-cut, and the stock

replaced. This is said to `mimic' nature. More accurately,

it is supposed that natural forests imitate their cultivated

counterparts, producing stands of trees that are uniform in

size or age.

 

However, when real forests are examined, they tell a very

different tale; there are no uniform or even stands of

trees. Instead, native forests - especially mature and long

established forests - tend to have diverse, uneven-sized

mixed stands.

 

Forest trees come in all sizes

 

Finland was the first country in the world to carry out a

national forest inventory as early as the beginning of the

1920s. The inventories have since been repeated once every

decade. Measuring tree diameter at breast height has been

one of the ways to investigate forest stand structure. It

fell to the lot of Lähde and his research team to carry out

the ninth inventory in the early 1990s; and for the first

time since inventory began in Finland, the distribution of

stem diameters of the trees was published.

 

Lähde went through the old inventory data for advanced and

mature forests in Southern Finland for 1920s, 1950s and

1985. He found four possible distributions in the data: even

or uniform sized, two-storeyed, " moundy uneven-sized "

(normal distribution), and " regularly all-sized " (see Fig.

1). The vast majority of advanced and mature forests had the

" regularly all-sized " distribution. This was also true of

data from the Swedish National Forest Inventory.

 

Fig 1. Different distributions of tree sizes and their

percentage occurrence in natural or mature forests in three

surveys carried out in 1921, 1951 and 1985.

 

Biological significance of the " all size " distribution

 

The " regularly all-sized " distribution discovered by Lähde

and colleagues for the stem diameter of forest trees is

commonly referred to as the 1/f distribution, where f is the

frequency of the size class. It says that the frequency of

the size class varies inversely as the diameter: the bigger

the trees, the less frequently they occur. The 1/f

distribution is possibly the most significant `law'

discovered within the past 15 years for natural processes

ranging from earthquakes and avalanches to the branching of

trees; and is especially relevant for biology (see " Living

energies " series, SiS 21

http://www.i-sis.org.uk/isisnews/sis21.php).

This distribution is characteristic of fractals – such as

coastlines and trees - which have fractional dimensions

between the usual 1, 2 or 3; as well as the same or similar

structure over many scales.

 

I have suggested that the " regular all size " or fractal

distribution applies to the totality of species in an

ecosystem, which enables the ecosystem to maximize energy

capture and storage and minimize dissipation. Translated

into biological terms, it would predict an increase in

biodiversity and productivity (see " Energy, productivity &

biodiversity " and " Why are organisms so complex? A lesson in

sustainability " , SiS 21

http://www.i-sis.org.uk/isisnews/sis21.php).

 

Sure enough, there is evidence for that in forest

ecosystems. The " regular all size " distribution supports

more biodiversity of trees and higher productivity, and any

measure that destroys that fractal structure diminishes

both.

 

Lähde and his colleagues calculated the diversity index of

trees in forests with the four different distributions: the

even sized stands scored 7, the two-storeyed stands scored

15, the " moundy " , 21.5, and " regular all-sized " , a clear

winner at 39.5.

 

Researchers in the Canadian Forest Service in the forests of

North Central British Columbia had previously shown that the

impact on biodiversity was dependent on the method of

harvesting, with single-tree selection and group selection

causing the minimum damage (see Table 1).

 

Table 1. Harvesting method and diversity

Treatment Diversity (%)

Untreated 100

Single-tree selection 90

Group selection 80

Shelterwood cutting 55

Remodelled clear-cutting 24

Seedtree cutting 20

Clear cutting 5

 

 

Lähde and colleagues compared the productivity of even-sized

stands with uneven-sized stands in experimental plots in

southern Finland.

 

The results (Table 2) showed that clear cutting leads to

unstable wood production. During regeneration and sapling

stages, growth remains low, reaching its peak only when

maturing. At maximum, it is still lower than the average

production of regularly all-sized stands. Thus, the latter

are more productive and more profitable on average than

even-sized stands. The quality of the wood produced is

better and it is able to sustain multiple uses on account of

its higher diversity.

 

Table 2. Productivity of even-sized and uneven-sized stands

Stand/developmental stage Volume m3 CAI* m3

Clear cut area 0 0.0

Regeneration area with seed trees 28 0.8

Regeneration area with sapling stand 26 2.7

Young thinning stand 140 5.1

Advanced thinning stand 178 5.1

Mature stand 180 4.4

Regularly all sized stand 194 5.9

*Current Annual Increase

 

 

In the short-term, clearcutting is a cheap and technically

easy option, and hence " an obvious favourite of the forest

industry " which enjoys the full benefits while leaving

forest owners to bear the costs of long and often expensive

process of regeneration. " Then, not only the timber

production is at its minimum but the multiple use and sales

values of the forest are also at the lowest. " Furthermore,

the risk of failure remains high throughout the regeneration

process.

 

Somewhat surprisingly, low thinning of small trees - a

common practice in forestry carried out in the belief that

it favours the growth of large trees by removing

" competition " – also reduces wood productivity (see Table

2). And this was confirmed in another set of experiments

involving 23 Norway spruce-dominated experimental stands

extending from southern to northern Finland, where Lähde and

coworkers found that CAI averaged 5.4 m3ha-1 in single-tree

selection plots compared with 4.6 m3ha-1 in low thinning

plots.

 

The reason why single-tree selection favours wood growth,

they suggest, may be because removing slow-growing dominant

trees releases space and nutrients to enable small trees to

grow more rapidly; while removing small trees in low

thinning results in little or no benefit for the remaining

dominants.

 

Tree plantations do not make economic sense

 

In order to counter the market-driven economic arguments all

too often used to justify the destruction of our natural

resources, there have been valiant attempts to estimate the

value of `ecosystem goods and services' in monetary terms.

 

An international team of conservationists led by Andrew

Balmford in Cambridge University, UK, estimated the monetary

value of benefits from relatively intact biomes compared

with those converted to intensive human use. These include

the tropical forest in Malaysia under reduced impact logging

as opposed to conventional logging, and the tropical forest

in Cameroon under reduced-impact logging or small-scale

farming as opposed to conversion into oil-palm and rubber

plantations.

 

In the case of Malaysia, the high-intensity, unsustainable

logging was associated with greater private benefits through

timber harvesting, but reduced social and global benefits

through loss of non-timber forest products, flood

protection, carbon stocks and endangered species. Summed

together, the total economy value of the forest was some 14%

greater when placed under more sustainable management.

 

In the case of Cameroon, conversion to oil palm and rubber

plantations yielded negative private benefits, while social

benefits from non-timber forest products, sedimentation

control, and flood prevention were highest under sustainable

forestry, as were global benefits from carbon storage and

other values. Overall, the total economic value of

sustainable forestry was 18% greater than that of small-

scale farming, whereas it was negative for plantations.

 

The total economic value of sustainable uses of the forests

were underestimated in that report, as only a handful of

well-established ecosystem services were considered, while

some particularly valuable services, such as nutrient

cycling, waste treatment and the provision of cultural

values were not examined.

 

It would appear that forestry is in for a complete shake-up,

if we are to make the best use of a resource that's

essential to the survival of our planet and its teeming

biodiversity.

 

 

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