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Technologies
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The “Green Liver System”: eco-friendly water purification [Brazil]

Fitorremediação (Portuguese)

technologies_1710 - Brazil

Completeness: 76%

1. General information

1.2 Contact details of resource persons and institutions involved in the assessment and documentation of the Technology

Key resource person(s)

SLM specialist:
SLM specialist:
SLM specialist:
Name of project which facilitated the documentation/ evaluation of the Technology (if relevant)
Book project: Making sense of research for sustainable land management (GLUES)
Name of the institution(s) which facilitated the documentation/ evaluation of the Technology (if relevant)
Leibniz-Institut für Gewässerökologie und Binnenfischerei (IGB) - Germany
Name of the institution(s) which facilitated the documentation/ evaluation of the Technology (if relevant)
Potsdam-Institut für Klimaforschung (PIK) - Germany
Name of the institution(s) which facilitated the documentation/ evaluation of the Technology (if relevant)
Universität Hohenheim - Germany
Name of the institution(s) which facilitated the documentation/ evaluation of the Technology (if relevant)
Technische Universität Berlin (Technische Universität Berlin) - Germany
Name of the institution(s) which facilitated the documentation/ evaluation of the Technology (if relevant)
Hochschule für Technik und Wirtschaft Dresden (HTW Dresden) - Germany

1.3 Conditions regarding the use of data documented through WOCAT

The compiler and key resource person(s) accept the conditions regarding the use of data documented through WOCAT:

Yes

2. Description of the SLM Technology

2.1 Short description of the Technology

Definition of the Technology:

Water purification using macrophytes to treat effluent from fish farming.

2.2 Detailed description of the Technology

Description:

The “Green Liver System” uses aquatic plants, established in artificial wetlands, to remove, transfer, stabilize or eliminate pollutants in wastewater from fish farms. The use of large quantities of feed in aquaculture, along with the application of antibiotics, hormones and probiotics, has negative impacts on aquatic ecosystems due to the introduction of nitrogen, phosphorous and drug residues into the system. The Green Liver System is a form of phytoremediation (phyto = plant and remediate = correct) that uses a range of plants to decompose, extract, or hold contaminants present in soils and waters. This technology has been considered as an innovative alternative and a low cost option compared to others used in contaminated sites - like membrane bioreactors, upflow anaerobic sludge blanket (UASB), and others.

Purpose of the Technology: The plants selected for use in Green Liver System artificial wetlands depend on the pollutant to be removed. Research shows physiological differences between species, which need to be taken into account when planning wastewater treatments. Ideal plants for phytoremediation need: a) a fast growth rate; b) high biomass production; c) long rooting systems; d) easy maintenance/pruning; e) to be able to persists, and f) to have the ability to store trace metals within specific parts which can be later removed.

Establishment / maintenance activities and inputs: The Green Liver System uses aquatic macrophytes, which extract contaminants from the water, store them, or even metabolize them - transforming them into less toxic or harmless products. In the case of Eichhornia crassipes, most of the solids in suspension are removed by sedimentation or by adsorption in the root system. The dense coverage of these plants reduces the mixing effect of the wind, as well as minimizing thermal mixture. Shading by the plants restricts algal growth and the root system prevents horizontal movement of particulate material. In this way, particles are removed from the wastewater and microorganisms associated with the plants’ rhizosphere slowly decompose. Many organisms can be used in biodegradation: these include bacteria and fungi as well as plants, and the efficiency of one or the other depend, in many cases, on the molecule structure and of the presence of enzymes that are effective in degrading the pollutant.

Natural / human environment: The fish farm used as an example here is located on the margins of the Itaparica reservoir in Brazil. There are dozens of excavated tanks used to produce tilapia (Oreochromis niloticus) and “tambaqui” (Colossoma macropomum) fingerlings and juvenile fish. As well as these tanks, there are many net enclosures installed in the reservoir where the fishes are reared to maturity. Part of the wastewater from the excavated tanks is released into a stabilization lagoon, and the remainder goes to the Green Liver System. The effluent is enriched with spare feed, and excreta from the fish, which includes drug residues. If not treated, this may cause eutrophication because of its mineral richness. The Green Liver System consists of an excavated tank of 100m x 20m x 2m in size. The tank is subdivided into six parts: two planted to Eichhornia crassipes and four to Egeria densa. A mesh barrier stops fish from being flushed into the tank. Regular monitoring of the physical, chemical and biological parameters is required to control environmental fluctuations.

2.3 Photos of the Technology

2.5 Country/ region/ locations where the Technology has been applied and which are covered by this assessment

Country:

Brazil

Region/ State/ Province:

Pernambuco

Further specification of location:

Vila do Coité, Itacuruba

2.6 Date of implementation

If precise year is not known, indicate approximate date:
  • less than 10 years ago (recently)

2.7 Introduction of the Technology

Specify how the Technology was introduced:
  • during experiments/ research
Comments (type of project, etc.):

Construction took place in 2013, building on earlier experiences of the principal scientist, for instance in South Korea.

3. Classification of the SLM Technology

3.2 Current land use type(s) where the Technology is applied

Waterways, waterbodies, wetlands

Waterways, waterbodies, wetlands

Comments:

Major land use problems (compiler’s opinion): The Itaparica reservoir was completed in 1988 to generate hydropower. About 40,000 people were compulsorily relocated. The construction of the reservoir had interrupted fish movement, leading to a shortage of fish, making aquaculture a viable and profitable alternative, and current law allows this. However excess feed and excreta of fish, partly containing drug residues, add nutrients and pollute water. ECONOMIC ASPECTS: The agricultural economy of this semi-arid region is characterized by pastoral activities, as well as the cultivation of crop species resistant to drought, such as cotton, corn (maize), beans, and cassava in humid areas. Irrigation from the reservoir was potentially possible but investments in aquaculture proved more profitable. In general, the commercial companies involved do not treat effluent, leading to pollution. Even though monitoring is mandatory, almost nobody does it, nor do they make substantial efforts to purify the effluent.

Major land use problems (land users’ perception): There are several conflicts over water and related land use in the region. Some people say the water quality in the reservoir is good (and use it directly for drinking), others report ill-health especially during times of low water levels. Commercial aquaculture primarily produces tilapia. Invariably, some tilapia escape from their net cages and take over from other local species. The hydroelectric company manages the reservoir according to national needs in electricity – thus sudden water level fluctuations are frequent. Commercial aquaculture and associated land use dominate the shoreline, preventing access for artisanal fishermen to their traditional fishing grounds.

Future (final) land use (after implementation of SLM Technology): Other: Ow: Waterways, drainage lines, ponds, dams

Constraints of transition land, fallow or sporadicall used by roaming livestock (mainly goats) (area in between the land-based aquaculture and the lake)

If land use has changed due to the implementation of the Technology, indicate land use before implementation of the Technology:

Grazing land: Ge: Extensive grazing land

3.3 Further information about land use

Water supply for the land on which the Technology is applied:
  • mixed rainfed-irrigated
Number of growing seasons per year:
  • 1
Specify:

Longest growing period from month to month: all year due to tropical climate

3.4 SLM group to which the Technology belongs

  • surface water management (spring, river, lakes, sea)
  • wetland protection/ management
  • Water purification

3.5 Spread of the Technology

Comments:

Total area covered by the SLM Technology is 2 m2.

The reservoir is 100m long and 20 m wide, with a depth of 1.7 m, but the area may be larger depending on the volume of effluent to be treated. The whole area comprises the fish ponds.

3.6 SLM measures comprising the Technology

vegetative measures

vegetative measures

  • V5: Others
structural measures

structural measures

  • S5: Dams, pans, ponds
Comments:

Main measures: vegetative measures

Secondary measures: structural measures

Specification of other vegetative measures: macrophytes, different species

Type of vegetative measures: in blocks

3.7 Main types of land degradation addressed by the Technology

water degradation

water degradation

  • Hp: decline of surface water quality
Comments:

Main type of degradation addressed: Hp: decline of surface water quality

Main causes of degradation: deforestation / removal of natural vegetation (incl. forest fires) (slash-and-burn practices), over-exploitation of vegetation for domestic use (firewood and charcoal making), overgrazing (free roaming run-wild donkeys, and small ruminants), urbanisation and infrastructure development (construction works near to body bodies (not respecting conservation areas)), discharges (point contamination of water) (indiscriminate disposal of effluents; excrements, drugs and surplus feed from fishes in net-cages), over abstraction / excessive withdrawal of water (for irrigation, industry, etc.) (abstraction of water from the reservoir without prior registration, not holding water use permits), change in temperature (supposed to be climate change induced), change of seasonal rainfall (high variability in semi-arid regions rather normal; though rainfall appears to fall in shorter periods), droughts (recurrent droughts are "normal", they appear to last for longer periods), poverty / wealth (limited livelihood sources in the rather remote municipality), inputs and infrastructure: (roads, markets, distribution of water points, other, …) (spoilage and low quality), education, access to knowledge and support services (often little value attached to natural resources), war and conflicts (conflicts among two families; conflicts among indigenous and commercial users), governance / institutional (restricted enforcement of existing rules; clientelism)

Secondary causes of degradation: soil management, crop management (annual, perennial, tree/shrub), industrial activities and mining, release of airborne pollutants (urban/industry…), disturbance of water cycle (infiltration / runoff), Heavy / extreme rainfall (intensity/amounts), wind storms / dust storms, floods, other natural causes (avalanches, volcanic eruptions, mud flows, highly susceptible natural resources, extreme topography, etc.) specify, population pressure, land tenure, labour availability

3.8 Prevention, reduction, or restoration of land degradation

Specify the goal of the Technology with regard to land degradation:
  • reduce land degradation
Comments:

Main goals: mitigation / reduction of land degradation

4. Technical specifications, implementation activities, inputs, and costs

4.1 Technical drawing of the Technology

Author:

Stephan Pflugmacher-Lima, TUB, Faculty VI Planning Building Environment; Sekr. A1; Str des 17. Juni 152; 10623 Berlin; Germany

4.2 Technical specifications/ explanations of technical drawing

The constructed wetland termed a “Green Liver System” is 100m x 25m x 2.0m in size. It is divided into six parts (one third of the tank planted with Eichhornia crassipes the remainder with Egeria densa). The average outflow during the period was 1,800 m³/h. Point P1 is the catchment from the reservoir. Point P2 is the inlet that receives the discharge of effluent from 10 ponds with juvenile tilapia (Oreochromis niloticus). Point P3 is the stage after the treatment with Eichhornia crassipes. Point P4 is the stage of the treatment with Egeria densa. Point P5 is the outlet into a containment basin.

Location: Itacuruba. Pernambuco

Date: 2013

Technical knowledge required for field staff / advisors: high (It is a sophisticated system which requires close observation and monitoring. Site-specific adaptation might be necessary (for instance fencing to avoid goats entering the area).)

Technical knowledge required for land users: high (It is a sophisticated system which requires close observation and monitoring. It will be easier with some experience.)

Main technical functions: improvement of water quality, buffering / filtering water

In blocks
Vegetative material: O : other
Number of plants per (ha): 250000

Other species: Egeria densa; Eichhornia crassipes

Dam/ pan/ pond
Depth of ditches/pits/dams (m): 1.7
Width of ditches/pits/dams (m): 20
Length of ditches/pits/dams (m): 100

Wall/ barrier
Depth of ditches/pits/dams (m): 1.7
Width of ditches/pits/dams (m): ca 0.3
Length of ditches/pits/dams (m): ca 15

Construction material (other): tubes, valves

Specification of dams/ pans/ ponds: Capacity 3400m3

Dimensions of spillways: ca 100m

4.3 General information regarding the calculation of inputs and costs

Specify currency used for cost calculations:
  • US Dollars
Indicate exchange rate from USD to local currency (if relevant): 1 USD =:

3.17

Indicate average wage cost of hired labour per day:

25.00

4.4 Establishment activities

Activity Type of measure Timing
1. Digging the pit, stabilizing the walls Vegetative
2. Fencing Vegetative
3. Building separation walls Vegetative
4. Planting macrophytes in place Vegetative

4.5 Costs and inputs needed for establishment

Specify input Unit Quantity Costs per Unit Total costs per input % of costs borne by land users
Labour Construction 1.0 3000.0 3000.0
Labour Macrophyte installation 1.0 1900.0 1900.0
Equipment Truck for removal of soil 1.0 125.0 125.0
Plant material Macrophytes 100.0
Plant material Wooden fence posts 100.0
Construction material Walls/baffles (cement) 1.0 475.0 475.0
Construction material Barbed wire 1.0 315.0 315.0
Construction material Earthwork 1.0 250.0 250.0
Construction material Tubular elements 1.0 30.0 30.0
Other Labour: Cutting fence posts 1.0 160.0 160.0
Other Labour: SUpervision 1.0 1000.0 1000.0
Total costs for establishment of the Technology 7255.0

4.6 Maintenance/ recurrent activities

Activity Type of measure Timing/ frequency
1. Exchange macrophytes Vegetative

4.7 Costs and inputs needed for maintenance/ recurrent activities (per year)

Specify input Unit Quantity Costs per Unit Total costs per input % of costs borne by land users
Labour Labour 1.0 3000.0 3000.0
Equipment Nylon fabric 1.0 15.0 15.0
Plant material Macrophytes 1.0 100.0
Total costs for maintenance of the Technology 3015.0
Comments:

Because of the tropical climate of Brazilian northeast there is a need to remove Eichhornia crassipes periodically because it grows very quickly as there is plenty nutrients and warm temperatures during all year. The cost of removal of the macrophytes is permanent and must be made monthly as the plant reaches adulthood it loses its capability in removing nutrients and gives it back to the water.

5. Natural and human environment

5.1 Climate

Annual rainfall
  • < 250 mm
  • 251-500 mm
  • 501-750 mm
  • 751-1,000 mm
  • 1,001-1,500 mm
  • 1,501-2,000 mm
  • 2,001-3,000 mm
  • 3,001-4,000 mm
  • > 4,000 mm
Specifications/ comments on rainfall:

It happened to be less than 100mm in 2013. Very unreliable rainfall pattern. Rainfall from Dezember to May, most rain often in March

Agro-climatic zone
  • semi-arid

Thermal climate class: tropics. Bsh according to Köppen classification

5.2 Topography

Slopes on average:
  • flat (0-2%)
  • gentle (3-5%)
  • moderate (6-10%)
  • rolling (11-15%)
  • hilly (16-30%)
  • steep (31-60%)
  • very steep (>60%)
Landforms:
  • plateau/plains
  • ridges
  • mountain slopes
  • hill slopes
  • footslopes
  • valley floors
Altitudinal zone:
  • 0-100 m a.s.l.
  • 101-500 m a.s.l.
  • 501-1,000 m a.s.l.
  • 1,001-1,500 m a.s.l.
  • 1,501-2,000 m a.s.l.
  • 2,001-2,500 m a.s.l.
  • 2,501-3,000 m a.s.l.
  • 3,001-4,000 m a.s.l.
  • > 4,000 m a.s.l.

5.3 Soils

Soil depth on average:
  • very shallow (0-20 cm)
  • shallow (21-50 cm)
  • moderately deep (51-80 cm)
  • deep (81-120 cm)
  • very deep (> 120 cm)
Soil texture (topsoil):
  • medium (loamy, silty)
Topsoil organic matter:
  • low (<1%)
If available, attach full soil description or specify the available information, e.g. soil type, soil PH/ acidity, Cation Exchange Capacity, nitrogen, salinity etc.

Soil fertility is low
Soil drainage/infiltration is poor
Soil water storage capacity is very low

5.4 Water availability and quality

Ground water table:

< 5 m

Availability of surface water:

poor/ none

Water quality (untreated):

poor drinking water (treatment required)

5.5 Biodiversity

Species diversity:
  • medium

5.6 Characteristics of land users applying the Technology

Off-farm income:
  • > 50% of all income
Relative level of wealth:
  • average
  • rich
Individuals or groups:
  • individual/ household
Gender:
  • men
Indicate other relevant characteristics of the land users:

Land users applying the Technology are mainly common / average land users

Population density: < 10 persons/km2

Annual population growth: 1% - 2%

5.7 Average area of land owned or leased by land users applying the Technology

  • < 0.5 ha
  • 0.5-1 ha
  • 1-2 ha
  • 2-5 ha
  • 5-15 ha
  • 15-50 ha
  • 50-100 ha
  • 100-500 ha
  • 500-1,000 ha
  • 1,000-10,000 ha
  • > 10,000 ha
Is this considered small-, medium- or large-scale (referring to local context)?
  • small-scale

5.8 Land ownership, land use rights, and water use rights

Land ownership:
  • individual, not titled
  • individual, titled
Land use rights:
  • individual
  • needs official registration and permission; heavy water use has a price
  • needs official registration and permission; heavy water use has a price

5.9 Access to services and infrastructure

health:
  • poor
  • moderate
  • good
education:
  • poor
  • moderate
  • good
technical assistance:
  • poor
  • moderate
  • good
employment (e.g. off-farm):
  • poor
  • moderate
  • good
markets:
  • poor
  • moderate
  • good
energy:
  • poor
  • moderate
  • good
roads and transport:
  • poor
  • moderate
  • good
drinking water and sanitation:
  • poor
  • moderate
  • good
financial services:
  • poor
  • moderate
  • good
extension service:
  • poor
  • moderate
  • good

6. Impacts and concluding statements

6.1 On-site impacts the Technology has shown

Socio-economic impacts

Water availability and quality

drinking water availability

decreased
increased

water availability for livestock

decreased
increased

irrigation water availability

decreased
increased
Income and costs

diversity of income sources

decreased
increased
Comments/ specify:

Biomass of macrophytes for potential ethanol production.

Other socio-economic impacts

Labour cost

decreased
increased
Comments/ specify:

Increase of maintenance costs as manual labor is required for management of macrophytes.

Socio-cultural impacts

SLM/ land degradation knowledge

reduced
improved
Comments/ specify:

Better water management in a setting of decreasing seasonal rainfall.

Improved livelihoods and human well-being

decreased
increased
Comments/ specify:

The technology contributed to improved water quality, which is directly related to people's health.

Ecological impacts

Water cycle/ runoff

water quality

decreased
increased

evaporation

increased
decreased
Comments/ specify:

Any open water body is subjected to the very high potential evaporation in the region. Though, the surface of the system is very small as compared to the adjacent reservoir.

Soil

soil cover

reduced
improved
Comments/ specify:

The vegetation had to be removed in order to construct the artificial wetland.

Other ecological impacts

Vulnerability

decreased
increased
Comments/ specify:

A nylon grid prevents the macrophytes from occasionally breaking loose into the reservoir.
The ecology of the system is sort of fragile. If the macrophytes float too much, the system can break down.

6.4 Cost-benefit analysis

How do the benefits compare with the establishment costs (from land users’ perspective)?
Short-term returns:

positive

Long-term returns:

positive

How do the benefits compare with the maintenance/ recurrent costs (from land users' perspective)?
Short-term returns:

positive

Long-term returns:

positive

6.5 Adoption of the Technology

Comments:

There is a little trend towards spontaneous adoption of the Technology

Comments on adoption trend: A broad adoption is not yet expectable at this stage of experimental analysis and testing. Few people did already express their interest.

6.7 Strengths/ advantages/ opportunities of the Technology

Strengths/ advantages/ opportunities in the land user’s view
If the environmental authority increases controls of how effluent from aquaculture ponds is handled (checking pollution and nutrient loads in the effluent which is usually returned to the reservoir without any treatment), the technology would help compliance with existing rules.

How can they be sustained / enhanced? Enhancing control and penalties would favour the adoption of such a green technology. Currently controls are rare or non-existent.
The technology can be constructed using locally available material.

How can they be sustained / enhanced? As long as cheap labour is available and rural shops exist, the availability of inputs is adequate.
Strengths/ advantages/ opportunities in the compiler’s or other key resource person’s view
Water purification is realized by using natural processes.

How can they be sustained / enhanced? If the related tilapia production unit could gain a green or ecological stamp, this would be beneficial and maybe trigger the adoption of the technology.
Among the advantages of adopting the Green Liver technology are the low costs, the speed of construction and it's relatively easy operation.

How can they be sustained / enhanced? Easily accessible and comprehensive information is needed, as well as the possibility to exchange experience among users or future users.

6.8 Weaknesses/ disadvantages/ risks of the Technology and ways of overcoming them

Weaknesses/ disadvantages/ risks in the land user’s view How can they be overcome?
Additional manual labour increases costs (and hinders adoption) The more people use such techniques, for instance due to improved environmental monitoring and fines imposed, the more such extra expenditure will be accepted as regular running costs.
The management of the system is not simple. Many different and unexpected disturbances can occur. Experience and close, constant watch out is needed. Exchange of experience among users would facilitate its management. An updated list of threats could be helpful.
Weaknesses/ disadvantages/ risks in the compiler’s or other key resource person’s view How can they be overcome?
From time to time the macrophytes have to be removed, tubes may need cleaning and the system needs to be set up again. Sometimes, the removal of almost all water may be indicated. Major maintenance can cause peak labour needs. Manual labour required to monitor the system on a regular basis, and perform maintenance according to needs. Depending on the number and size of Green Liver Systems in action, caring for them can be a full-time job. The maintenance costs have to be well budgeted in the overall planning of costs and benefits of the related productive units.
The disposal of the removed macrophytes is still a problem to be solved. If the macrophytes have accumulated high levels of toxins, the biomass cannot be used for compost making or livestock feeding. The removed macrophytes should be analysed for their pollutant content. A biodigester could be the solution to the disposal of contaminated biomass, generating energy for the productive unit and possibly for the local population too.

7. References and links

7.2 References to available publications

Title, author, year, ISBN:

Pflugmacher, S., Kühn, S., Lee, S.-H., Choi, J.-W., Baik, S., Kwon, K.-S., Contardo-Jara, V., 2015. Green Liver Systems® for water purification: Using the phytoremediation potential of aquatic macrophytes for the removal of different cyanobacterial toxins from water.

Available from where? Costs?

AJPS 06 (09), 1607–1618. doi:10.4236/ajps.2015.69161.

Title, author, year, ISBN:

Nimptsch, J., Wiegand, C., Pflugmacher, S., 2008. Cyanobacterial toxin elimination via bioaccumulation of MC-LR in aquatic macrophytes: An application of the “Green Liver Concept”

Available from where? Costs?

Environ. Sci. Technol. 42 (22), 8552–8557. doi:10.1021/es8010404.

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