09 April 2019

Optimisation in Agriculture

Author/Compiled by
Stefanie Keller (seecon international gmbh)
Dorothee Spuhler (seecon international gmbh)

Introduction 

Factsheet Block Body

About 3% of the world water is fresh water only. But a large part is stored in polar ice caps, and only 0.5% are easily accessible freshwater  (see factsheet [1913-the water cycle). The 0.5% of world water reserves, which are available to maintain life, endure a steadily increasing pressure of human activity by agricultural food production, industry or a continuously growing urbanisation. The water use in agriculture is a key issue for the 21st century. Without improvements, will neither the consequences of climate change be manageable nor will the demand of two or three billion additional people for food be met (SCIENCE DAILY 2009).

 

The global signs for future water conflicts are (FARDOUS 2006):

  • Freshwater consumption enlarged twice as fast as population growth in the 20th century.
  • Approximately 70% of all water used by people is for irrigating crops.
  • Groundwater supplies in major agricultural regions are being overdrawn and depleted much faster than their regeneration by precipitation.
  • Drought prompts even greater tapping of stored supplies while dramatically reducing the rate of replacement. The incidence of drought may be increasing.
  • Furthermore, the increase in surface temperatures, and the prospect of further warming, will put extra stress on crops and further enhance demands for water. By 2025, 1.8 billion people will live in a situation of absolute water shortage. Full two-thirds of the world’s population will live in what FAO describes as a situation of water stress.

The Role of Agriculture within Future Water Uses

Factsheet Block Body

(Adapted from COMMITTEE ON AGRICULTURE 2007; CORCORAN et al. 2010)

The extent to which the agricultural sector contributes to water scarcity and the degrading some of the world’s highest quality surface and groundwater is not disputed and acknowledged by scientists. Agriculture is responsible for the largest water withdrawals and contributes to conditions of local absolute water scarcity and future water conflicts - yet of course the whole humanity depends on agriculture.
The way we produce our food uses 70–90% of the available fresh water, returning much of this water to the system with additional nutrients and contaminants. It is a domino effect, as downstream agricultural pollution is exacerbated by human and industrial waste. This wastewater and the way we currently deal with it contaminate freshwater and coastal ecosystems; threaten food security, access to safe drinking water and results in major health risks and environmental degradation.

Out of all sectoral water uses, agriculture, together with industrial water use, has the largest capacity to contribute to integrated water resources management through improved agricultural practices and methods. Furthermore, agriculture has to account for its water use in economic and environmental terms. Overall, managing the demand for agricultural water use must be focus on improving water use efficiency and agricultural productivity from the farms to the market. This includes an improved farm water management, better irrigation system performance and adjustments of national water and irrigation policies.

Typically, only 30 to 50 % of the water applied for irrigation is actually used by crops. Hence, there is still a large potential for improving management practices and technology for irrigated and rain-fed farming systems, increasing the productivity of the water used.

What is Optimisation/Efficiency of Water Use in Agriculture?

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Improving the water use efficiency in agriculture means to effectively increase the crop yield whilst minimising water use. Water saving agriculture implies the combination of agronomic, physiological, biotechnological/genetic and engineering approaches.

Agricultural water consumption can be optimised by improving existing irrigation systems, enhancing the water use efficiency of crops, and by properly maintaining the existing systems to avoid malfunctioning. Regarding crop irrigation, optimal water efficiency means to minimise water losses due to evaporation, evapotranspiration, runoff or subsurface drainage.Improving the water use efficiency of crops means selecting crops that are adapted to the respective climate, e.g. crops that are drought tolerant or adapted to dry climates.

The optimisation of water use in agriculture can sometimes be achieved by simple means and is also of economic importance (water savings). However, farmers need to be motivated by the right incentives and policies and may require technical assistance.

This factsheet will provide an overview of the technical options in order to use water more efficiently in agriculture. In the factsheets invalid link and invalid link you will find related information to capacity building tools, incentives and legislative frameworks.

Surface Irrigation

Factsheet Block Body

(Adapted from BURT 2000)

Surface irrigation stands for a large group of irrigation methods in which water is distributed by gravity over the surface of the field. Water is typically introduced at the highest point or along the edge of a field, which allows covering the field by overland flow. Historically, surface irrigation has been the most common method of irrigating agricultural land. The defining feature of surface irrigation methods is that the soil is used as the transport medium (as opposed to pipelines or through the air, as with sprinklers). The soil is also controlling the depth infiltrated over time.Surface irrigation methods contain two basic categories: ponding (surface water pooled in a puddle) and moving water. The moving water methods require some runoff or ponding to guarantee adequate infiltration at the lower end of the field. In order to avoid water loss due to evaporation, it is important not to irrigate the crops during the day but in the early morning or at night. The better the quality of the soil is, the less is the unnecessary runoff and the better the infiltration into the soil and therefore the use for the crops.

 

Method

Variations

Basin

Flat-Planted Basins

Bed

Fill and Drain

Border Strip

Sloping Strips and Runoff

Low-Gradient and Blocked End Strips

Contour Ditches (Wild Flood)

Guided

Continuous Flood and Ponding

 

 

Furrow

Traditional Sloping Furrows

Modern (Mechanised) Sloping Furrows

Level and Low-Gradient Furrows

Contour Furrows

Corrugations

 

Surface irrigation methods and variations. Source: BURT (2000)

Manual Irrigation (Buckets, Cans, etc.)

Factsheet Block Body

(Adapted from INFONET-BIOVISION 2010)


Small-scale bucket drip irrigation system. Source: INFONET-BIOVISION (2010)

Small-scale bucket drip irrigation system. Source: INFONET-BIOVISION (2010)

These irrigation technique systems have low requirements for infrastructure and technical equipment but need high labour inputs. Irrigation by using water cans is to be found for example in peri-urban agriculture around large cities in some African countries. Small-scale drip irrigation system with buckets is one of the very water-efficient manual irrigation methods. It consists of two drip lines, each 15 to 30 m long, and a 20-litre bucket for the water. Each of the drip lines is connected to a filter to remove any particles that may clog the drip nozzles. The bucket is supported on a bucket stand, with the bottom of the bucket at least 1 m above the planting surface. For example, a bucket system requiring 2 to 4 buckets of water per day can irrigate 100 to 200 plants with a spacing of 30 cm between the rows. For crops such as onions or carrots, the number of plants can be as many as the bed can accommodate.

Automatic, Non-electric Irrigation (Ropes, Buckets)

Factsheet Block Body

(Adapted from EIJKELKAMP n.y.)

In addition to the common manual watering by bucket, an automated, natural version of this technique also exists. Using plain polyester ropes combined with a prepared ground mixture can be used to water plants from a vessel filled with water. The ground mixture would need to be made depending on the plant itself, yet would mostly consist of black potting soil, vermiculite and perlite. This irrigation system is often used for tree establishment in dry climates.

Sprinkler Irrigation

Factsheet Block Body

(Adapted from FAO 1988)


Figure 4: Sprinkler irrigation. Source: product-image.tradeindia.com

Figure 4: Sprinkler irrigation. Source: product-image.tradeindia.com

Sprinkler Irrigation is a method of using irrigation water is similar to rainfall. Water is distributed through a system of pipes usually by pumping. The water is sprayed into the air and irrigates the entire soil surface through spray heads. Sprinklers provide efficient coverage for small to large areas and are suitable for all types of properties. Furthermore, it is adaptable to nearly all irrigable soils since sprinklers are available in a wide range of discharge capacity. Sprinkler irrigation is appropriate to any farmable slope, whether uniform or undulating. The lateral pipes supplying water to the sprinklers should always be laid out along the land contour whenever possible. This will minimise the pressure changes at the sprinklers and provide a uniform irrigation. Sprinklers are best suited to sandy soils with high infiltration rates although they are adaptable to most soils. The average application rate from the sprinklers (in mm/hour) is always chosen to be less than the basic infiltration rate of the soil so that surface ponding and runoff can be avoided. Evaporation is very high with this kind of irrigation technique but can be minimised when practiced during the night or early morning like in surface irrigation.

Drip Irrigation

Factsheet Block Body

(Adapted from INFONET-BIOVISION 2010; FAO 1988)


Drip irrigation. Source: image.absoluteastronomy.com

Drip irrigation. Source: image.absoluteastronomy.com

Drip irrigation is a technique in which water flows through a filter into special drip pipes, with emitters located at different spacing. Water is distributed through the emitters directly into the soil near the plants through a special slow-release device. If the drip irrigation system is properly designed, installed, and managed, drip irrigation may help achieve water conservation by reducing evaporation and deep drainage. Compared to other types of irrigation systems such as flood or overhead sprinklers, water can be more precisely applied to the plant roots. In addition, drip can eliminate many diseases that are spread through water contact with the foliage. Finally, in areas where water supplies are severely restricted, there may be no actual water savings, but rather simply an increase in production while using the same amount of water as before. In very arid regions or on sandy soils, the trick is to apply the irrigation water as slowly as possible. Irrigation scheduling can be managed precisely to meet crop demands, holding the promise of increased yield and quality.

Drip irrigation is adaptable to any farmable slope and is suitable for most soils. On clay soils water must be applied slowly to avoid surface water ponding and runoff. On sandy soils higher emitter discharge rates will be needed to ensure adequate lateral wetting of the soil.

Subsurface Irrigation

Factsheet Block Body

(Adapted from SAKELLARIOU-MAKRANTONAKI et al. 2002; NPSI 2005)


Subsurface drip irrigation. Source: uutsewer.com

Subsurface drip irrigation. Source: uutsewer.com

Subsurface drip irrigation is a variation of the conventional surface drip irrigation technique. It is using water more efficiently than traditional irrigation techniques like surface irrigation by minimising evaporation. The laterals (also used in conventional drip irrigation) are buried in a depth below the soil surface depending mostly on the tillage practices and the crop to be irrigated. Subsurface drip irrigation can be understood as the oldest modern irrigation method. Subsurface irrigation applies water directly to the plant’s root zone at a rate closely matching that required for optimum plant growth. The soil type and crops planted determine the instalment depth of subsurface drip irrigation systems. Subsurface drip irrigation has shown great potential for increasing crop yield and uniformity, while decreasing the use of water and the environmental impact.

Spate Irrigation

Factsheet Block Body

(Adapted from SPATE IRRIGATION NETWORK n.y.)


Spate irrigation in Yemen. unesco-ihe.org

Spate irrigation in Yemen. unesco-ihe.org

Spate irrigation is a water management system that is unique to semi-arid regions. It is found in the Middle East, North Africa, West Asia, East Africa and parts of Latin America. Floodwater from mountain catchments is distributed to riverbeds (so-called wadis, the Arabic term for valley, referring to a dry riverbed that contains water only during times of heavy rain) and spread over large areas. Spate irrigation systems contain a big risk and uncertainty. The uncertainty comes both from the unpredictable nature of the floods and the frequent changes of the riverbeds from which the water is diverted. It is often the poorest segments of the rural population whose livelihood and food security depends on spate irrigation systems. However, over time, considerable local wisdom has developed in organising spate systems and managing both the flood water and the heavy sediment loads that go along with it by constructing spurs and bunds. These spurs and bunds are generally made in such a way that the main diversion structures in the river break when floods are too big. Breaking of diversion structures also serves to maintain the floodwater entitlements of downstream landowners and therefore helps to reduce the upstream-downstream water conflicts. Some of the larger spate irrigation rank among the largest farmer-managed irrigation systems in the world. The structures are sometimes spectacular: earthen bunds, spanning the width of a river, or extensive spurs made of brushwood and stones. Spate systems are made in such a way that ideally the largest floods are kept away from the command area. Very large floods would create considerable damage as they would destroy flood diversion channels and cause rivers to shift.

Agricultural Reuse of Rainwater, Storm water and Reclaimed Water

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Rainwater and storm water harvesting can be defined as an irrigation method for inducing, collecting, storing and conserving local surface runoff for agriculture in arid and semi-arid regions.
Rainfall has four dimensions regarding irrigation. Rainfall induces surface flow on the runoff area. At the lower end of the slope, runoff is collected in the basin area, where a major portion infiltrates and is stored in the root zone. When infiltration has ceased, the stored soil water is conserved (HATIBU and MAHOO n.y.). In rain water harvesting for agriculture, three different groups of techniques can be distinguished:

 

  • Flood water harvesting from far away, large catchments (e.g. spate irrigation);
  • Rain water harvesting from macro-catchment systems utilising the runoff from a nearby slope for agricultural purposes
  • Rainwater harvesting from micro-catchment where the water from an adjacent, small catchment is used for cropping (e.g. roof rainwater harvesting which can also be used for drinking water. For further information, see also roof top rainwater harvesting in urban or rural areas.

 

It is evident that all three groups of rainwater harvesting for agriculture techniques need different geographic settings for an appropriate implementation. In addition to topography, the runoff properties of the surface and the infiltration rates are important natural parameters for the implementation of any water harvesting system. Furthermore, the soil types of the run-on areas and the depth of the soil layer in the cropping areas are important factors that influence the outcome. Additionally, socio-economic factors have to be taken into due consideration (PRINZ et al. 1998).
With a growing scarcity of freshwater resources in arid and semi-arid regions and the ever-increasing demand for more efficient food production for larger populations, the importance of wastewater for irrigation increases and is more widely acknowledged. Wastewater has long been used as a resource in agriculture. The use of contaminated water in agriculture, which may be intentional or accidental, can be managed through the implementation of various barriers, which reduce the risk to both crop viability and human health. Today, an estimated 20 million hectares (7%) of land is irrigated using wastewater worldwide, particularly in arid and semiarid regions and urban areas where unpolluted water is a scarce resource and the water and nutrient values of wastewater represent important, drought-resistant resources for farmers (CORCORAN et al. 2010). Wastewater is often the only source of water for irrigation in these areas. Even in regions where other water sources exist, small farmers often prefer wastewater due to its high nutrient content, which reduces or even eliminates the need for expensive chemical fertilisers. Wastewater reuse is likely to become more widely practised, and it is already becoming incorporated into some national water resources management plans. Reuse can take place at a local level (e.g. fertigation, greywater towers or vertical gardens) or at a centralised level (e.g. aquaculture). The wastewater used in irrigation can be taken from different sources. It can be completely untreated municipal, pre-treated municipal or industrial wastewater, or particularly or fully purified wastewater treated biologically (KRETSCHMER 2003). In 2006, the World Health Organisation has edited a large curriculum of guidelines for the save use of excreta and wastewater (WHO 2006) in agriculture (Vol. II), in aquaculture (Vol. III) as well as the save use of excreta and greywater (Vol. IV). Volume I of these guidelines gives an overview on policy and regulatory aspects (see Further Readings). In any case, the reuse of wastewater is not only beneficial for crop production but generally also implies an improvement of the water quality (e.g. nutrients are transferred to the plants, bacteria killed by the sun or predators, etc.). However, the institutionalisation of reuse of wastewaters is important in order to avoid health risk and negative environmental impacts.

Aquaculture is another alternative to improve the water use efficiency in agriculture. Aquaculture is the farming of freshwater and saltwater organisms such as fish, crustaceans and aquatic plants. Aquaculture can be combined with the reuse of wastewater (municipal, industrial or agricultural wastewater from feedstock). Nutrients contained in the wastewater are removed by feeding animals or plants, which can be harvested. Pathogens can also be removed by natural die-off, solar disinfection (in shallow ponds) or predation (even though the effluent is not pathogenically safe). Interactions between crops and livestock are considered crucial to the sustainable development of agriculture. The combination of aquaculture and wastewater reuse allows optimising the water use for farming of aquatic animals and plants for food production all by increasing the quality of the wastewater effluent. Typical Aquaculture systems can be used for plants (aquaculture plants) or animals such as fish or crustaceans (aquaculture animals).

Crop Selection

Factsheet Block Body

(Adapted from NSCA 2001)

Choosing the appropriate crop for production can reduce the water used for irrigation to a great extent. The better the crop is adapted to the existing climate, topography and soil condition, the less water is used for irrigation.
Growing a different crop each year (crop rotation) prevents organic matter loss, improves soil structure and reduces the incidence of weeds and pests. Generally, the longer the rotation, the better. Crop rotations can also lead to greater efficiency in soil water utilisation. For example, deep-rooted crops following shallow crops can take advantage of the extra reserve of deep moisture, which was unavailable to the shallow rooted crop. Crop rotation also improves the soil structure and thus its water retention capacity. Cover crop is important to protect the surface of the soil from evaporation, erosion and drying out. A cover crop should be established as soon as possible after harvesting short season vegetables. Annual or cereal rye is good cover crops for longer season vegetables because they grow well in cooler weather (such as in autumn and early spring), and are also good at taking up excess fertiliser.

Moisture Conservation

Factsheet Block Body

(Adapted from TNAU 2008; NSAC 2001)

Figure: Contour bund. Source: BARBER (2003), fao.org

Figure: Contour bund. Source: BARBER (2003), fao.org

The two major causes for loosing water from cropping systems include evaporation and transpiration. Evaporation losses occur directly from the soil, while transpiration losses are through plants. A plant can be pictured as a pump, drawing water from the soil and moving it to the leaves where it is lost to the atmosphere through tiny openings. The water losses of soils to the atmosphere by either evaporation or plant transpiration are usually described as evapotranspiration. Evapotranspiration values are highest when the soil is near field capacity and the air is warm, dry and moving. The potential evapotranspiration (PET) is the maximum amount of water that could evaporate and/or transpire when moisture is not limiting. When the PET is high, plants must draw heavily on soil water and transpiration can occur faster than the plants can draw water from the soil, which may eventually cause wilting.

Some typical in-situ moisture conservation techniques are micro catchments, broad beds and furrows or contour bunds. You can find more information in the factsheets on precipitation harvesting and in TNAU (2008).

The organic matter content of the soil has a considerable influence on many of the physical, biological and chemical properties of soil and thus also its structure and water retention and holding capacity, nutrient content, biological activity and aeration. Intensive crop production often returns little organic matter to the soil. However, there are several approaches to maintaining or improving organic matter content. These include spreading compost (e.g. garden compost, humanure, terra preta etc.) or animal manure, reducing tillage, green manuring and practicing good crop rotations. See also the factsheets use of urine agriculture at large or small scale and fertigation.

Microcatchments. Source: TNAU (2008)

Microcatchments. Source: TNAU (2008)


Library References

Improvement of Water Use Efficiency in Irrigated Agriculture: A Review

This document provides a good overview of the importance of improving water use efficiency in respect to irrigated agriculture. Furthermore, this paper contains many useful definitions, such as water use efficiency and deficit irrigation.

BOUTRAA, T. (2010): Improvement of Water Use Efficiency in Irrigated Agriculture: A Review. In: Journal of Agronomy: Volume 9 , 1-8.

Selection of irrigation methods for agriculture. Environmental and Water Research Institute

This report provides an overview of various agricultural irrigation methods. The variations of each general method (surface irrigation, drip/micro irrigation, sprinkler irrigation, and sub-irrigation) are described. The capabilities, limitations, institutional considerations, and economic factors of the methods and their variations are explained. These explanations will facilitate the proper selection of irrigation method for respective circumstances, depending upon crop, climate, economics, water quality, support infrastructure, energy availability, and numerous other factors.

BURT, C. M. (2000): Selection of irrigation methods for agriculture. Environmental and Water Research Institute. Virginia: ASCE Publications URL [Accessed: 29.07.2010]

Agriculture and Water Scarcity: a Programmatic Approach to Water Use Efficiency and Agricultural Productivity

This document describes the causes and effects of the global water scarcity and the instrumental role the agriculture plays to counteract this global concern.

COMMITTEE ON AGRICULTURE (2007): Agriculture and Water Scarcity: a Programmatic Approach to Water Use Efficiency and Agricultural Productivity. Rom: Food and Agriculture Organization of the United Nations (FAO)

Water for Irrigation

Infonet-biovision.org is a web-based information platform offering trainers, extension workers and farmers in East Africa a quick access to up-to-date and locally relevant information in order to optimise their livelihoods in a safe, effective, sustainable and ecologically sound way.

INFONET-BIOVISION (2010): Water for Irrigation. Zürich: Biovision URL [Accessed: 09.04.2019]

Sick Water? The central role of wastewater management in sustainable development

This book not only identifies the threats to human and ecological health that water pollution has and highlights the consequences of inaction, but also presents opportunities, where appropriate policy and management responses over the short and longer term can trigger employment, support livelihoods, boost public and ecosystem health and contribute to more intelligent water management.

CORCORAN, E. ; NELLEMANN, C. ; BAKER, E. ; BOS, R. ; OSBORN, D. ; SAVELLI, H. (2010): Sick Water? The central role of wastewater management in sustainable development. A Rapid Response Assessment. United Nations Environment Programme (UNEP), UN-HABITAT, GRID-Arendal URL [Accessed: 05.05.2010] PDF
Further Readings

Improvement of Water Use Efficiency in Irrigated Agriculture: A Review

This document provides a good overview of the importance of improving water use efficiency in respect to irrigated agriculture. Furthermore, this paper contains many useful definitions, such as water use efficiency and deficit irrigation.

BOUTRAA, T. (2010): Improvement of Water Use Efficiency in Irrigated Agriculture: A Review. In: Journal of Agronomy: Volume 9 , 1-8.

Selection of irrigation methods for agriculture. Environmental and Water Research Institute

This report provides an overview of various agricultural irrigation methods. The variations of each general method (surface irrigation, drip/micro irrigation, sprinkler irrigation, and sub-irrigation) are described. The capabilities, limitations, institutional considerations, and economic factors of the methods and their variations are explained. These explanations will facilitate the proper selection of irrigation method for respective circumstances, depending upon crop, climate, economics, water quality, support infrastructure, energy availability, and numerous other factors.

BURT, C. M. (2000): Selection of irrigation methods for agriculture. Environmental and Water Research Institute. Virginia: ASCE Publications URL [Accessed: 29.07.2010]

Agriculture and Water Scarcity: a Programmatic Approach to Water Use Efficiency and Agricultural Productivity

This document describes the causes and effects of the global water scarcity and the instrumental role the agriculture plays to counteract this global concern.

COMMITTEE ON AGRICULTURE (2007): Agriculture and Water Scarcity: a Programmatic Approach to Water Use Efficiency and Agricultural Productivity. Rom: Food and Agriculture Organization of the United Nations (FAO)

Sick Water? The central role of wastewater management in sustainable development

This book not only identifies the threats to human and ecological health that water pollution has and highlights the consequences of inaction, but also presents opportunities, where appropriate policy and management responses over the short and longer term can trigger employment, support livelihoods, boost public and ecosystem health and contribute to more intelligent water management.

CORCORAN, E. ; NELLEMANN, C. ; BAKER, E. ; BOS, R. ; OSBORN, D. ; SAVELLI, H. (2010): Sick Water? The central role of wastewater management in sustainable development. A Rapid Response Assessment. United Nations Environment Programme (UNEP), UN-HABITAT, GRID-Arendal URL [Accessed: 05.05.2010] PDF

Water Harvesting

Water harvesting has been practiced successfully for millennia in parts of the world – and some recent interventions have also had significant local impact. Yet water harvesting’s potential remains largely unknown, unacknowledged and unappreciated. These guidelines cover a wide span of technologies from large-scale floodwater spreading to practices that collect and store water from household compounds.

MEKDASCHI STUDER, R. LINIGER, H. (2013): Water Harvesting. Guidelines to Good Practice. Bern/Amsterdam/Wageningen/Rome: Centre for Development and Environment (CDE), Rainwater Harvesting Implementation Network (RAIN), MetaMeta, The International Fund for Agricultural Development (IFAD) URL [Accessed: 12.03.2019] PDF
Case Studies
Training Material

Guidelines for the safe use of wastewater excreta and greywater. Volume I. Policy and Regulatory Aspects

Volume I of the Guidelines for the Safe Use of Wastewater, Excreta and Greywater focuses on policy, regulation and institutional arrangements. Accordingly, its intended readership is made up of policy-makers and those with regulatory responsibilities. It provides guidance on policy formulation, harmonisation and mainstreaming, on regulatory mechanisms and on establishing institutional links between the various interested sectors and parties. It also presents a synthesis of the key issues from Volumes II, III, and IV and the index for all four volumes as well as a glossary of terms used in all four volumes is presented in Annex 1.

WHO (2006): Guidelines for the safe use of wastewater excreta and greywater. Volume I. Policy and Regulatory Aspects. Geneva: World Health Organisation URL [Accessed: 10.04.2019]

Guidelines for the safe use of wastewater excreta and greywater. Volume II. Wastewater Use in Agriculture

Volume II of the Guidelines for the safe use of wastewater, excreta and greywater provides information on the assessment and management of risks associated with microbial hazards and toxic chemicals. It explains requirements to promote the safe use of wastewater in agriculture, including minimum procedures and specific health-based targets, and how those requirements are intended to be used. It also describes the approaches used in deriving the guidelines, including health-based targets, and includes a substantive revision of approaches to ensuring microbial safety.

WHO (2006): Guidelines for the safe use of wastewater excreta and greywater. Volume II. Wastewater Use in Agriculture. Geneva: World Health Organisation URL [Accessed: 05.06.2019] PDF

Guidelines for the safe use of wastewater excreta and greywater. Volume III. Wastewater and Excreta Use in Aquaculture

Volume III of the Guidelines for the Safe Use of Wastewater, Excreta and Greywater deals with wastewater and excreta use in aquaculture and describes the present state of knowledge regarding the impact of wastewater-fed aquaculture on the health of producers, product consumers and local communities. It assesses the associated health risks and provides an integrated preventive management framework.

WHO (2006): Guidelines for the safe use of wastewater excreta and greywater. Volume III. Wastewater and Excreta Use in Aquaculture. Geneva: World Health Organisation URL [Accessed: 08.05.2019]

Guidelines for the safe use of wastewater excreta and greywater. Volume IV. Excreta and Greywater Use in Agriculture

Volume IV of the Guidelines for the Safe Use of Wastewater, Excreta and Greywater recognizes the reuse potential of wastewater and excreta (including urine) in agriculture and describes the present state of knowledge as regards potential health risks associated with the reuse as well as measures to manage these health risks following a multi-barrier approach.

WHO (2006): Guidelines for the safe use of wastewater excreta and greywater. Volume IV. Excreta and Greywater Use in Agriculture. Geneva: World Health Organisation (WHO) URL [Accessed: 09.05.2019] PDF
Awareness Raising Material

Water Facts and Trends

This presentation contains some essential graphs and information on the water cycle as such. It is based on the 2009 WBCSD publication “Water Facts and Trends” (see further above).

WBCSD (2009): Water Facts and Trends. (PPT Presentation). Geneva: World Business Council for Sustainable Development URL [Accessed: 20.04.2010]

Alternative Versions to