01

2.1 Environmental impacts

2.1.1 Soil
2.1.2 Water
2.1.3 Air
2.1.4 Biosphere

2.2 Protective measures

2.2.1 General conditions
2.2.2 Ecofarming

3. Notes on the analysis and evaluation of environmental impacts

4. Interaction with other sectors

5. Summary assessment of environmental relevance

6. References

1. Scope

The following terms recur frequently in this environmental brief and therefore require definition:

- Single cropping involves growing only one crop on a particular area of land, e.g. rice. The sequence in which various single crops are grown one after the other in a field is known as the crop rotation.
- Intercropping is a system in which a number of different crops grow together for the entire vegetation period or part of it, e.g. a combination of cassava, cowpeas and millet.
- Annual crops are generally herbaceous plants with a one-year vegetation cycle (e.g. cereals, legumes, various vegetables, tobacco).
- Perennial crops are plants which are used over a number of years; each plant is sowed or planted only once, e.g. fruit trees, tea, coffee and cocoa.
- Monoculture involves growing a particular crop on the same area of land over a number of cultivation periods, e.g. sugar cane.

Taking into account the production of wood, self-regenerating raw materials, animal fodder and crops used in the manufacture of semi-luxury goods, plant production represents - in terms of area - man's major form of interference with the Earth's natural balance.

Traditional farming systems are usually based on intercropping and tend to be subsistence-oriented. External inputs such as fertilisers and pesticides are uncommon and are used on only a small scale.

By contrast, large-scale plantation farming generally takes the form of monoculture (sugar cane, cotton) or permanent cropping (coffee, tea, cocoa). These forms of cultivation are market-oriented and dependent on external inputs.

Plant production involves activities in areas such as

- plant protection
- agricultural engineering and animal traction
- irrigation
- species and variety selection
- tillage and fertilising
- crop tending and weed control, harvesting, post-harvest treatment, storage
- erosion protection and control.

Crops are grown to meet the needs of the producer or the market. They also play a role in protecting soil, air and water.

Plant production is carried out on farms, for the most part using family labour, in order to ensure subsistence and earn monetary income.

2. Environmental impacts and protective measures

In agroecosystems, man becomes the dominant element in the ecosystem (anthropogenically oriented ecosystems). Agroecosystems differ in particular from natural ecosystems in that natural regulation processes take second place to control by man.

In the natural environment, plants form part of the ecosystem and play a key role in preserving it. Depending on the cropping method used, the nature, intensity and interaction of cultivation measures give rise to specific environmental impacts. These may cause a reduction in the diversity of species, disruption of the soil structure and pollution of the soil, water and air (pesticides, salts resulting from irrigation and fertilisation, nitrate etc.) Natural ecosystems with their wide variety of functions are replaced by artificial land-use systems poor in species.

Growing use of industrially produced inputs (fertilisers, pesticides, machines, energy) and inappropriate cultivation techniques lead to contamination of drinking water by fertilisers and pesticides, as well as causing soil erosion, desertification and genetic erosion.

2.1 Environmental impacts

2.1.1 Soil

Soil forms the basis for plant production and thus performs a vital function in guaranteeing human survival.

Soil conservation is essential if man's living environment is to be maintained in a healthy state and a sustained supply of high-quality foods is to be ensured.

Opportunities for changing the conditions prevailing on a particular site are limited. Cultivation measures must therefore be geared to the natural conditions under which the land is used.

Erosion - in other words the removal of soil by water and wind - is one of the most problematic consequences of agriculture, particularly in the tropics.

The actual extent of erosion depends on the type of crop and form of cropping. To minimise erosion, efforts should be made to ensure that there is ground cover all year round. In the case of monoculture and single cropping, the risk of erosion becomes greater the more slowly the young plants develop (e.g. maize, grain legumes), the lower the planting density is and the more comprehensive the weed control measures are. As annual crops such as cereals, tubers and grain legumes entail frequent tillage, they have an adverse effect on the soil structure and are thus conducive to erosion.

Perennial crops such as fruit trees generally prevent soil erosion once the stand is complete; they provide permanent shade, which has a positive effect on the soil structure.

A soil's erodibility depends among other things on its physical properties. Fine sand and abraded particles can be displaced most easily, whereas a high stone and clay content inhibits erosion. A high humus content stabilises the soil structure and increases the water storage capacity; both of these factors inhibit erosion.

The most important ways of controlling erosion are:

- adequate ground cover (intercropping, underseeding etc.);
- "storeyed" cultivation through integration of trees and shrubs;
- division of cropping areas into small units and creation of windbreaks at right angles to the direction of the prevailing wind;
- avoidance of overstocking and measures to prevent animals from grazing on newly sown areas (see environmental brief Livestock Farming).

Excessive mechanisation of tillage and harvesting can lead to compaction, plough sole formation and puddling, particularly in the case of tropical soils with a weak structure. This may have the adverse effect of reducing water infiltration and the air supply for the soil flora and fauna as well as for the crops. Mechanisation can also lead to changes in the division of labour between men and women.

Although frequent tillage generally has a stimulating effect on microbial activity and thus also on replenishment of the nutrient supply, it has disadvantages in the tropics:

- humus decomposition is excessively rapid on account of the high temperatures,
- the soil fauna are adversely affected and formation of new humus is thereby delayed.

Single cropping promotes the spread of pests on a large scale and tends to necessitate substantial use of pesticides. Introduction of pesticides into the soil has adverse effects on the soil fauna and flora.

Organic matter plays a major role in the dynamics of tropical soils. It stores water, provides a living environment for soil organisms, promotes structural stability, and both supplies and stores nutrients. It is above all in storing nutrients that organic matter performs an especially vital function, as tropical soils seldom contain high-quality nutrient-fixing clay minerals. Use of mineral fertilisers therefore depends on the proportion of organic matter in the soil. If the amount of fertiliser used is not in correct proportion to the organic matter, there is a danger of leaching and of the fertiliser passing into deeper soil layers. Use of too much fertiliser is thus ecologically undesirable and economically disadvantageous.

The risk of unbalanced nutrient depletion is greatest in the case of monoculture and single cropping, e.g. in the case of maize, cocoa, root crops and tubers. Where a number of plant species are grown in an intercropping or crop rotation system this risk becomes smaller, as differing nutrient requirements have to be met. As such forms of cropping incorporate plants with different root systems (shallow, deep) and nutrient requirements (high, low), competition for nutrients, water and light is substantially reduced.

2.1.2 Water

The erosion referred to above can lead to eutrophication of bodies of water through the introduction of nutrients, e.g. liquid manure and nitrate, and to contamination with toxic pesticide residues.

2.1.3 Air

The climate in multi-storeyed stands growing in an intercropping system is better i.e. more balanced, than that in stands of annual crops forming a monoculture or single cropping system. The wind velocity is lower and thus better for crops susceptible to the wind (e.g. bananas).

Air pollution caused as a result of plant production stems primarily from chemical plant protection measures. Evaporation of ammonia during application of solid or liquid manure has hitherto been of only minor significance. Under tropical conditions (high temperatures, low soil sorption capacity), up to 80% of the total nitrogen may evaporate.

Pollution of the air and atmosphere is caused by waste gases resulting from use of machinery, slash-and-burn techniques and burning-off of crop residues, as well as by discharge of gases such as methane and nitrous oxide by swamp rice and large herds of cattle. These factors play a part in the greenhouse effect.

2.1.4 Biosphere

The risk of both the loss of species and a change in the balance of species increases in proportion to the intensity of plant production activities. Controlled shifting cultivation - observing the necessary fallow periods - encroaches least on the natural environment in terms of area if only level areas are cleared on a selective basis. This helps not only to preserve the forests, particularly the rainforests and their resources, but also to protect forest-dwellers, who often possess know-how about things such as plants with potential pharmacological uses and the ecological interrelationships within their living environment.

Systematic cultivation of crops and the related mechanical and chemical forms of weed control cause wild plants to be largely displaced, leading to a reduction in the number of species.

In regions subject to periodic droughts, large-scale cultivation of certain woody plants in a monoculture system substantially increases the fire risk. In addition to nutrient and leaching losses, this can also result in unwanted destruction of grass and tree species not resistant to fire.

Displacement and destruction of plants leads to a reduction in biological diversity. Extensive use of rainforests also substantially reduces the variety of animal species, e.g. in the case of primates and birds.

Natural ecosystems are adversely affected not only by land being required for plant production but also by being broken up (e.g. by traffic routes), which can result in a loss of stability.

Use of land for plant production generally leads to the loss of forest, dry, wet and aquatic biotopes and causes the landscape to take on a uniform nature, e.g. as a consequence of land clearance, drainage, levelling and irrigation.

By comparison with the natural vegetation, plant production destroys habitats and reduces regional diversity. Standardisation of products for the market and breeding to obtain specific traits (e.g. yield, shape, colour) play a part in the loss of local varieties (genetic erosion).

2.2 Protective measures

2.2.1 General conditions

Plant production is influenced to a particularly large extent by general conditions; these may relate not only to climate but also to national (e.g. land ownership situation) or international (economic relations) factors.

Many climatic and vegetation zones are highly sensitive to interference by man, whose activities generally destroy the vegetation, as in the following cases:

- clearance of the tropical rainforest in the Amazon basin for the purpose of obtaining high-grade timber
- slash-and-burn land clearance by arable farmers in Nigeria's tree-studded savannah, where the transition to permanent cultivation no longer allows the land the opportunity to regenerate
- overgrazing in the Sahel zone as a result of overstocking with large numbers of livestock which remove the already sparse vegetation.

The consequences are disastrous, not only in the humid tropics but also in places which receive less rainfall. As there are virtually no plants left to provide ground cover, the soil undergoes changes within the space of a few years; a key role is played here by the increased decomposition of organic matter in the soil and the fact that the introduction of new organic matter is reduced to a minimum.

Within the existing world economic order, the terms of trade for the countries concerned have steadily deteriorated. It is above all these countries which have been hit by the increased cost of energy and finished products. International agricultural policy likewise does nothing to ensure balanced promotion of plant production.

Rapid population growth means that farms are becoming increasingly small and the land is thus being used more and more intensively. Farms in Latin America today already have an average size of only 2.7 hectares; those in Africa on average cover 1.3 hectares, while the corresponding figure for Asia is less than one hectare. What is more, 10% of persons deriving their living from agriculture in Africa, 25% of those in the Middle East and 30% of those in Latin America own no land at all. Two thirds of those who do possess land own only a tiny area and cannot afford capital-intensive technical inputs such as pesticides, herbicides and mineral fertilisers.

As land becomes increasingly scarce, farming systems undergo a transition from shifting cultivation to semi-permanent and eventually permanent arable farming. This process has already been largely completed in Asia, while in much of Africa and Latin America it is still under way. The changeover to permanent arable farming means that there are no longer any fallow periods (forest, bush, pasture) which allow the soil to regenerate; soil fertility declines and eventually remains at a fairly low level permitting only substantially smaller yields. The shortage of land also necessitates use of areas such as slopes at risk from erosion and thus contributes to environmental degradation.

The relative importance of the crops grown also changes. In the humid and semi-humid tropics the cultivation of yams, sorghum, and maize declines in significance, while crops such as cassava and sweet potatoes become more important. The last-mentioned crops produce relatively good yields even on poor sites, but at the same time cause the soil to become exhausted more quickly.

In many countries, both intensification of agriculture and the industrialisation process are having increasingly adverse impacts on the environment. Waterlogging, salinisation and sedimentation cause the irrigated cropping areas - often created at considerable expense - to lose their fertility after only a few years, which gives a rise to a considerable drop in yield. Traces of persistent pesticides are being increasingly found in bodies of surface water and groundwater reservoirs. The past decade has seen a sharp rise in the number of people suffering pesticide poisoning, while at the same time there has been an enormous increase in the number of pest species resistant to the commonly used pesticides.

The factors described here are generally to be found wherever efforts are being made to raise yields through targeted, conventional modernisation of agriculture. However, such problems are not simply consequences of large-scale agricultural projects, but also arise as the cumulative result of numerous activities on the part of smallholders.

As the actual environmental costs have little or no impact from the farm management viewpoint, there is no incentive to take measures aimed at conserving natural resources or producing sustained improvements in efficiency. Land law, taxation policy and subsidisation policy, along with ascertainment of the external costs involved in production and consumption, are areas which the state must tackle in the interest of promoting environmentally oriented plant production.

There are certain concepts, such as that of ecodevelopment, which are based on the necessary integrated approaches. Tried and tested measures such as integrated plant protection, ecofarming and others point the way towards sustainable development.

2.2.2 Ecofarming

Ecofarming aims to achieve a high sustained level of productivity on the site in question under "low external input" conditions and at the same time to preserve or recreate a balanced ecosystem.

This applies in particular in densely populated regions with smallholder-based farming structures and under economic conditions which largely preclude use of external inputs (e.g. mineral fertilisers), for in many cases such inputs are economically non-viable, unaffordable or unavailable on account of supply shortages. Intensification of agriculture must therefore be based on more productive use of scarce goods (nutrients, water, energy) and underutilised idle resources (e.g. labour, individual initiative).

The demand for stability and sustainability stems from the obligation of each generation to pass on to future generations an environment that remains capable of guaranteeing the fundamentals of human existence. The demand for productivity coupled with stability is often seen as a conflict of objectives between irreconcilable short-term and long-term (and frequently also between microeconomic and macroeconomic) viewpoints; in most cases it is the short-term microeconomic considerations that prevail. Ecofarming must endeavour to achieve both objectives to an equal extent.

Ecofarming, or "site-appropriate agriculture" as it is also known, involves treating both regions used for agriculture and individual farms as ecological systems. However, the concept of "site" must not be restricted to natural conditions (soil, climate).

Consideration must also be given to economic development (price-cost ratios, incomes), farm-specific conditions (access to factors of production) and the internal forces influencing a farm's operations (self-sufficiency, risk minimisation, preservation of soil fertility). Last but not least, it is essential that man, together with his culture, needs, taboos and habits, be viewed as a component of the ecological system and not as an outsider.

This integrated approach requires a certain degree of geographical differentiation. Agriculture in many countries is affected by a growing shortage of raw materials and energy and by the accompanying rise in prices. This is particularly true of countries which are in debt and possess little foreign exchange. It is thus these countries above all which must develop forms of agriculture that permit a high degree of self-sufficiency (within a self-contained system) and decentralisation (as well as self-regulation) at national and regional level and within individual farms.

The major elements of ecofarming are as follows:

- creation of appropriate vegetation

· inclusion of trees and shrubs in arable farming
· creation of erosion-protection strips parallel to the incline on slopes and planting of hedges to divide a farm into numerous small fields
· afforestation on the poorest and most degraded soils

- intercropping, alternating with intensive fallow
- organic manuring
- integrated livestock husbandry
- improved mechanisation
- supplementary use of mineral fertiliser
- integrated plant protection and selective weed control

The elements listed above are given in order of precedence. As it is impossible to introduce the entire package of measures immediately, this form of classification indicates which measures must be given top priority for the purpose of preserving, increasing and stabilising soil productivity.

The following key areas of activity and options in the plant production sector should be combined with one another according to the nature of the site:

- farm planning and organisation (information systems, economic thresholds, soil investigations, climatic data)
- design of cropping system (single cropping, intercropping etc.)
- variety and seed selection (resistance, quality, quantity)
- tillage

· conventional
· minimum tillage
· direct drilling

- cultivation and land use (crop rotation, sustainable cropping capacity)
- plant nutrition (fertilising)

· organic
· mineral

- plant protection

· mechanical
· biological
· chemical

To sum up, it can be said that environmentally sound, site-appropriate agriculture aims

- to guarantee that plant production is geared to natural conditions, i.e. site-appropriate;
- to preserve the soil structure, the biological processes taking place in the soil and the soil's fertility;
- to prevent erosion damage;
- to prevent contamination of groundwater and bodies of surface water;
- to prevent adverse impacts on biotopes adjacent to agricultural land as a result of the introduction of substances or other consequences of cultivation measures;
- to preserve typical landscape features;
- to take account of the requirements of nature conservation and protection of species, particularly as regards preservation of ecologically valuable biotopes, within the scope of overall consideration of the environment;
- to make livestock husbandry an integral component of environmentally sound agriculture.

3. Notes on the analysis and evaluation of environmental impacts

In the plant production sector, the following assessment criteria lend themselves to direct or indirect measurement:

- changes in the biotope (diversity of species of flora and fauna)
- impacts on finite natural resources (minerals, ores, water, atmosphere)
- impacts on global ecological relationships (net energy production: energy audit comparing energy fixed by a crop plant/harvested product and energy used in its production)
- contamination levels (chemical products, salts, dusts, gases)

Limits varying from one country to another have been laid down for many substances occurring in agriculture. Although many countries have maximum-quantity regulations covering immissions in water, air and soil, these are generally concerned with the effect of pollutants on human health.

As the properties and sensitivity of tropical soils vary greatly, a site survey must always be conducted before project planning commences. Such a survey involves mapping the soil types with regard to their heat, water, air and nutrient balances as well as their susceptibility to erosion. The soil type can be determined in the field or by means of granulometric analysis in a laboratory; once this has been done it is possible to assess the risk of compaction. Measurement of the infiltration rate permits more accurate appraisal of the erosion risk. Tolerance limits for humus decomposition can be formulated only on the basis of the soil conditions and the land use situation. The humus content can be roughly ascertained in the field; precise determination can be carried out in the laboratory by means of ignition loss, wet incineration or gas chromatography.

Spade analysis can be used for simple assessment of soil structure and biological activity; rooting characteristics are of particular importance. The findings can be substantiated in the laboratory by means of wet screening (aggregate stability), analysis of the C/N ratio (nitrogen availability) etc. The presence of effective root symbionts (nitrogen-fixing organisms, mycorrhiza) can be detected only by way of infection tests.

The extent of the leaching risk (particularly for nitrate and pesticides) can be ascertained by determining the field capacity of the soil profile down to the effective rooting depth. This can be estimated in the field with the aid of a drilling stock; it is advisable to conduct a pore analysis of typical soil horizons in order to calibrate the response. However, excavation of a profile is essential in some cases, above all if waterlogging or crusting is suspected.

Deficiency or toxicity symptoms in crops may prompt determination of nutrient status or contamination level. Measurement of the pH value as a function of soil depth can often reduce the necessary scope of analysis and provides information about the lime requirement. Measurement of effective cation exchange capacity and base saturation yields pointers regarding nutrient imbalances and the degree of salinisation. In the case of trace elements and heavy metals, plant analysis is to be preferred. The results allow appropriate recommendations to be made regarding fertilising or - where necessary - rehabilitation.

A body of water can be characterised with relative ease by means of quality classification, which is carried out by determining the pH value, temperature, oxygen content and important indicator organisms. If such organisms are not present or are unknown, the water's ammonium and phosphate content can also yield information about the trophic level. Analysis of biochemical and chemical oxygen demand (BOD, COD) allows conclusions to be drawn regarding the degree of pollution with degradable organic substances. The requirements to be fulfilled in terms of water quality will vary depending on the planned use.

It is above all in semi-arid regions that hydrogeological investigations are necessary for assessing the groundwater reserves. Such investigations can yield information on subsoil conditions and the location of the catchment areas. Current annual evaporation and groundwater recharge rate can then be estimated on the basis of the land use and soil distribution determined in the course of the site survey. If the rate at which the groundwater is tapped (drinking water, irrigation) permanently exceeds the recharge rate, lowering of the groundwater may cause severe damage to land which is in a near-natural state or has undergone reforestation. In such cases the groundwater must also fulfil more stringent quality requirements, since its use as drinking water must not be restricted.

Areas used for plant production often serve to neutralise or reduce emissions emanating from other areas. Correctly designed intensive agroecosystems can in fact sometimes perform such functions more effectively than the potential natural vegetation, because it becomes profitable, from a certain yield level upwards, to neutralise immission-induced damage through appropriate use of inputs (e.g. liming to offset the introduction of acid). The same applies to climatic effects, which can be positively influenced if suitable land and the correct forms of cropping are selected.

Summarising assessments of energy flows and natural cycling systems, which also yield information about loading capacities, will be highly unreliable in the absence of adequate familiarity with the species involved and their interrelationships.

4. Interaction with other sectors

Plant production always has impacts on the environment, either directly or through its links with other areas. By virtue of its objectives and impacts it has particularly close links with the following areas featured in farming systems:

- Plant protection
- Forestry
- Livestock farming
- Aquaculture
- Agricultural engineering
- Irrigation

The objectives pursued in these sectors (see relevant environmental briefs) may be compatible with those of plant production, have no bearing on them or conflict with them. In the same way, impacts of plant production may be increased, reduced or offset by measures in these areas. When assessments are being carried out, attention must be paid to the possibility that impacts generated by activities in different areas could have a cumulative effect and thereby increase the amount of damage done. Such processes can be regulated with the aid of research and advisory work, backed up by instruments in fields such as legislation, poverty alleviation, self-help and advancement of women.

If plant production is on a scale extending beyond subsistence level, it also has links with agroindustry. Sinking of wells as part of schemes to provide rural water supplies can accelerate the desertification process, which has disastrous consequences for plant production.

As many countries require an increasing amount of land for settlement, transport systems, trade and industry and sometimes have to meet this need by developing areas formerly used for plant production, conflicts inevitably arise (spatial and regional planning, location planning, transport and traffic, large-scale hydraulic engineering). Although improvement of the transport system facilitates access to inputs (fertilisers, workshops) and sale of produce, land development within natural ecosystems can accelerate the destruction of such systems. The need for erosion control measures generally arises as a result of erosion caused by forms of cropping inappropriate to the site concerned. The availability of renewable energy sources and compostable domestic waste can also be of importance for plant production.

5. Summary assessment of environmental relevance

In order to prevent plant production from giving rise to unintentional developments, ascertainment of the initial situation and appraisal of potential consequences must be followed by regular assessment of forecast and actual changes in environmental conditions. The same applies to social conditions, as there is a close interrelationship between cultural and economic factors on the one hand and the natural environment on the other hand.

The impacts of plant production generally consist in reduction of the diversity of species, adverse effects on the nutrient balance as well as on the physical and chemical properties of the soil, and contamination of the environment with pollutants.

Appropriate planning techniques and technical measures have been developed and must be taken into consideration. It is essential to refute the opinion that plant production activities (including biological erosion protection measures) have little or no impact on the environment.

Resource-depleting impacts are generally unwanted side-effects which are not directly related to the production goals. It is precisely when these side-effects are ignored that the natural environment will suffer damage and adverse long-term consequences will arise in the economic and social spheres.

Careful planning and implementation will ensure that plant production has minimal environmental impacts, has no undesirable social consequences and is economically efficient.

6. References

ALKÄMPER, J. AND MOLL, W. (Eds.), 1983: Möglichkeiten und Probleme intensiver Bodennutzung in den Tropen und Subtropen. Gießener Beiträge zur Entwicklungsforschung, Reihe 1, Band 9, Gießen.

ARBEITSGRUPPE BODENKUNDE, 1982: Bodenkundliche Kartieranleitung. Hanover.

ASIAN DEVELOPMENT BANK, 1986: Environmental Planning and Management, Regional Symposium on environmental and natural planning, Manila, 19. - 21.02.1986.

BARBIER, E.B. and CONRAY, G.R., 1988: After the Green Revolution: Sustainable and equitable agricultural development. Futures, 651-670.

BAUMANN, W., BAYER, H., GEUPNER, P., KRAFT, H., LAUTERJUNG, E., LAUTERJUNG, H., MOLIEN, H., WOLKEWITZ, H. AND ZEUNER, G., 1984: Ökologische Auswirkungen von Staudammvorhaben, Erkenntnisse und Folgerungen für die entwicklungspolitische Zusammenarbeit. Forschungsberichte des BMZ, BAND 60, Weltforumverlag, Munich.

BEHRENS-EGGE, M., 1991: Möglichkeit und Grenzen der monetären Bewertung in der Umweltpolitik. Zeitschrift für Umweltpolitik 1, pp. 71-94.

BINSWANGER, H. C.; M. FABER AND R. MANSTETTEN, 1990; The dilemma of Modern Man and Nature: an Exploration of the Faustian Imperative. Ecological Economics 2, with case studies. In: BISWAS and GEPING, 1987, pp. 3-64.

BISWAS, A.K. AND GEPING, Q., 1987: Environmental impact assessment for Developing Countries. Tycooly Publishing, London.

BONUS, H., 1984: Marktwirtschaftliche Konzepte im Umweltschutz. In: (Eds.) Agrar- und Umweltforschung in Baden-Württemberg, Bd. 5, Stuttgart.

BRODBECK, U., FORTER, D., ISELIN, G. AND WYLER, M. (Eds.), 1987: Die Umsetzung der Umweltverträglichkeitsprüfung in der Praxis. Eine Herausforderung für die Wissenschaft. Verlag Paul Haupt, Berne.

CAESAR, K., 1986: Einführung in den tropischen und subtropischen Pflanzenbau. DLG-Verlag, Frankfurt/a.M.

CGIAR, 1990a: Sustainable Agricultural Production: Final Report of the committee on sustainable agriculture. Consultative Group Meeting, May 21-25, The Hague, The Netherlands.

CGIAR, 1990b: To Feed a Hungry World: The urgent role of development agencies. Committee on Agricultural Sustainability for Developing Countries.

CONWAY, G.R., 1985: Agroecosystem Analysis. Agricultural Administration 20, 31-55.

CONWAY, G.R., 1987: The properties of agroecosystems. Agricultural Systems 24, 95-117.

DEUTSCHER FORSTVEREIN, 1986: Erhaltung und nachhaltige Nutzung tropischer Regenwälder. Forschungsberichte des Bundesministeriums für wirtschaftliche Zusammenarbeit [BMZ - German Federal Ministry for Economic Cooperation and Development]. Weltforum-Verlag, Munich.

DEUTSCHES INSTITUT FÜR TROP. UND SUBTROP. LANDWIRTSCHAFT (DITSL), 1989: The extent of soil erosion - regional comparisons. Witzenhausen.

DIXON, J. A. AND M. M. HUFSCHMIDT, 1986: Economic Valuation Techniques for the Environment. A case study workbook. The John Hopkins University Press.

DIXON, J. A.; CARPENTER, R. A.; FALLON, L. A.; SHERMAN, P. B. AND MANIPOMOKE, S. 1988: Economic Evaluation of the Environmental Impacts of Development Projects. ADB.

DUMANSKI, J., 1987: Evaluating the Sustainability of Agricultural Systems. Africaland - Land Development and Management of Acid Soils in Africa II: IBSRAM Proceedings 2nd Regional Workshop, Lusaka and Kasama, Zambia, 9-16 April 1987, pp. 195-205.

DUMANSKI, J. et al. 1990: Guidelines for evaluating sustainability of land development projects. entwicklung + ländlicher raum, p. 3-6.

EHUI, S.K. and SPENCER, D. S. C., 1990: Indices for Measuring the Sustainability and Economic Viability of Farming Systems. Research Monograph No. 3. Resource and Crop Management Program, International Institute of Tropical Agriculture.

ENGELHARDT, T., 1989: Angewandte Projektökonomie, GTZ.

EWUSIE, J. Y., 1980: Elements of tropical ecology. Heinemann education books, London.

FOOD and Agriculture Organization (FAO), 1981: Agriculture: toward 2000. FAO, Rome.

FOOD and Agriculture Organization (FAO), 1984: Land, Food and People. FAO Economic and Social Development Series 30. Rome.

FOY, G. and DALY, H., 1989: Allocation, distribution and scale as determinants of environmental degradation: Case studies of Haiti, El Salvador and Costa Rica. WORLD BANK, Environmental Department Working Paper Nr. 19.

GÖLTENBOTH, F., 1989: Subsistence agriculture improvement - Manual for the humid tropics. Margraf-Verlag, Weikersheim.

HARTJE, V., 1990: Das UVP-Verfahren in der Entwicklungszusammenarbeit. Vortrag zum Symposium des Wissenschaftlichen Beirates beim BMZ "Umweltschutz in der Entwicklungszusammenarbeit", Bonn.

HARRISON, D. AND RUBINFELD, D. O., 1978: Hedonic Prices and the Demand for Clear Art. In: Journal of Environmental Economics and Management, Vol. 5, 81-102.

HAS, M., 1986: Großtechnologie - aber welche Alternative, in: STÜBEN, P.E. (Ed.) 1986: Nach uns die Sintflut. Staudämme, Entwicklungs"hilfe", Umweltzerstörung und Landraub. Focus Verlag, Gießen, pp. 194-213.

HESKE, H., (Ed.), 1987: Ernte-Dank? - Landwirtschaft zwischen Agro-Business, Gentechnik und traditionellem Landbau. Ökozid Nr. 3, Focus Verlag, Gießen.

HUFSCHMIDT, M. M.; JAMES, D. E.; MEISTER, A. D.; BLAIR, T. B. AND DIXON, J. A.: 1983: Environmental Natural Systems and Development. An Economic Evaluation Guide. The John Hopkins University Press.

INSTITUT FÜR UMWELTSCHUTZ DER UNIVERSITÄT DORTMUND, 1977: Umweltindikatoren als Planungsinstrumente (Beiträge zur Umweltgestaltung: B; H. 11) E. Schmidt-Verlag, Berlin.

INTERNATIONALE VEREINIGUNG BIOLOG. LANDBAUBEWEGUNGEN, (Ed.), 1989: Basisrichtlinien der IFOAM für den ökologischen Landbau. SÖL-Sonderausgabe Nr. 16, 7. Auflage, Kaiserslautern.

INTERNATIONAL LAND DEVELOPMENT CONSULTANTS (ILACO, B. V.), 1981: Agricultural compendium for rural development in the tropics and subtropics. Elsevier Scientific Publishing Company, Amsterdam (detailed standard works for site surveys).

INTERNATIONAL RICE RESEARCH INSTITUTE (IRRI), 1980: Soil-related constraints to food production in the tropics. Los Banos, Philippines.

KIRKBY, M. J. AND MORGAN, R. P. C., 1980: Soil erosion. Wiley and Sons, Chichester.

KOTSCHI, J. AND ADELHELM, R., 1984: Standortgerechte Landwirtschaft zur Entwicklung kleinbäuerlicher Betriebe in den Tropen und Subtropen. GTZ, Eschborn.

KOTSCHI, J.; WATERS-BAYER, A.; ADELHELM, R. AND HOESLE, U., 1989: Ecofarming in agricultural development. Margraf-Verlag, Weikersheim.

LAL, R.; ANDRUSSEL, E. W., 1981: Tropical agricultural hydrology. Wiley and Sons, Chichester.

LAUER, W. (Ed.), 1984: Natural environment and man in tropical mountain ecosystems. Steiner Verlag, Wiesbaden.

LYNAM, J. K. AND HERDT, R. W., 1989: Sense and Sustainability: Sustainability as an objective in international agricultural research. Agricultural Economics, Vol. 3, No. 4, pp. 381-398.

MÄCKEL, R. AND SICK, W. D., 1988: Natürliche Ressourcen und ländliche Entwicklungsprobleme der Tropen. Reihe Erdkundliches Wissen, Steiner Verlag, Wiesbaden.

MAGRATH, W. AND ARENS, P., 1989: The cost of soil erosion on Java: a natural resource accounting approach. WORLD BANK. Environment Department Working paper Nr. 18.

MARTEN, G. G., 1988: Productivity, Stability, Sustainability, Equitability and Autonomy as Properties for Agroecosystem Assessment. Agricultural Systems 26, 291-316.

MESSERLI, B.; BISAZ, A.; KIENHOLZ, A. AND WINIGER, M., 1987: Umweltprobleme und Entwicklungszusammenarbeit. Arbeitsgemeinschaft Geographica Bernesia, Berne.

MÜLLER-HOHENSTEIN, K.; GROSSER, L; AND RAPPENHÖHNER, D., 1988: Umweltverträglichkeitsstudie zum GTZ-Projekt "Zucker-rohrversuchsanbau", Marokko (PN 80.2116.4-01.100). Identifizierung und Gewichtung der Umweltbeeinflussungen, sowie Empfehlungen für zukünftige Maßnahmen und weitere Studien. GTZ, Eschborn.

MÜLLER-SÄMANN, K. M., 1986: Bodenfruchtbarkeit und standortgerechte Landbau-Maßnahmen und Methoden im tropischen Pflanzenbau. Schriftenreihe der GTZ Nr. 195, Eschborn.

NAIR, P. K. R., (Ed.) 1989: Agroforestry systems in the tropics. Kluwer Academic Publishers, Dordrecht.

PREUSCHEN, G., 1983: Die Kontrolle der Bodenfruchtbarkeit - eine Anleitung zur Spatendiagnose. IFOAM-Sonderausgabe Nr. 2, 2. Auflage, Kaiserslautern.

REHM, S. AND EPSIG, G., 1990: The cultivate plants of the tropics and subtropics. Margraf-Verlag, Weikersheim.

ROTTACH, P., (Ed.), 1984: Ökologischer Landbau in den Tropen. Alternative Konzepte, C. F. Müller Verlag, Karlsruhe.

1988: Ökologischer Landbau in den Tropen/Ecofarming in Theorie und Praxis. C. F. Müller Verlag, Karlsruhe.

RUTHENBERG, H., 1980: Farming systems in the tropics. Clarendon Press, Oxford.

SCHEFFER, F. AND SCHACHTSCHABEL, P., 1989: Lehrbuch der Bodenkunde. 12. Auflage, Enke-Verlag, Stuttgart.

SMIT, B. AND M. BRKLACICH, 1989: Sustainable development and the analysis of rural systems. Journal of Rural Studies, 5, (4), 405-414.

STOCKING, M., 1987: Measuring land degradation. In: P. BLAKIE and H. BROOKFIELD, (Eds.), Land degradation and society. London: Methuen, 49-63.

WHANTHONGTHAM, S., 1990: Economic and Environmental Implications of two alternative citrus production systems. MS thesis Asian Institute of Technology.

WEITSCHET, W., 1977: Die ökologische Benachteiligung der Tropen. Teubner Verlag, Stuttgart.

WÖHLCKE, M., 1987: Ökologische Aspekte der Unterentwicklung. Fakten, Tendenzen und Handlungsbedarf in Bezug auf den Umwelt- und Ressourcenschutz in der Dritten Welt. Stiftung Wissenschaft und Politik. Ebenhausen.

WÖHLKE, M., 1990: Umwelt und Ressourcenschutz in der Internationalen Entwicklungspolitik. AK. Materialien zur Internationalen Politik. Baden-Baden.

YOUNG, A., 1976: Tropical soils and soil survey. Cambridge University Press, Cambridge.

ZENTRALSTELLE FÜR ERNÄHRUNG UND LANDWIRTSCHAFT [German Food and Agriculture Development Centre], 1988: Agroforstwirtschaft in den Tropen und Subtropen - Aktualisierung und Orientierung der Forschungsaktivitäten in der Bundesrepublik Deutschland.

ZÖBISCH, M. A., (ed.), 1986: Probleme und Möglichkeiten der Landnutzung in den Tropen und Subtropen unter besonderer Berücksichtigung des Bodenschutzes. Der Tropenlandwirt, Beiheft Nr. 31, Witzenhausen.

Contents - Next