1.2 Detalhes do contato das pessoas capacitadas e instituições envolvidas na avaliação e documentação da tecnologia

Nome do projeto que facilitou a documentação/avaliação da Tecnologia (se relevante)

OPtimal strategies to retAIN and re-use water and nutrients in small agricultural catchments across different soil-climatic regions in Europe (OPTAIN)

Nome da(s) instituição(ões) que facilitou(ram) a documentação/ avaliação da Tecnologia (se relevante)

Chamber of Agriculture and Forestry of Slovenia – Institute of Agriculture and Forestry Maribor (KGZS) - Eslovênia

Nome da(s) instituição(ões) que facilitou(ram) a documentação/ avaliação da Tecnologia (se relevante)

University of Ljubljana (UL) - Eslovênia

1.3 Condições em relação ao uso da informação documentada através de WOCAT

O/a compilador/a e a(s) pessoa(s) capacitada(s) aceitam as condições relativas ao uso de dados documentados através da WOCAT:

Sim

1.4 Declaração de sustentabilidade da tecnologia descrita

A tecnologia descrita aqui é problemática em relação a degradação da terra de forma que não pode ser declarada uma tecnologia de gestão sustentável de terra?

Não

Comentários:

With improper implementation and intended use, it can have a negative effect on sustainability in the environment. It can be sustainable if properly anticipated/planned. The construction of the pond is usually subject to an environmental impact assessment where these matters are resolved as to whether it is sustainable or not.

2.1 Descrição curta da tecnologia

Definição da tecnologia:

Retention ponds (e.g. flood storage reservoirs, shallow impoundments) are water bodies, storing water to attenuate surface runoff during rainfall events. They provide storage as well as improving water quality. Retention ponds may also be used for irrigation of farmland.

2.2 Descrição detalhada da tecnologia

Descrição:

“Retention ponds” comprise both simple, small ponds (up to 2000 m3, up to 4 m deep) and larger, more complex reservoirs (greater than 2000 m3). Retention ponds are designed to provide storage capacity to attenuate surface runoff during rainfall events. Each consists of a permanent ponded area with landscaped banks. Retention ponds achieve both storm water attenuation and water quality treatment through supplementary storage capacity of runoff. Water is then released at a controlled rate once the risk of flooding has passed. The technology can be applied in a natural or human environment. Before construction of a pond it is essential to follow legislation, which covers conditions and restrictions for the given location. Once a site is selected, technical documentation is prepared: first the conceptual design, then documentation for obtaining opinion, consent and a building permit. Later there is also project documentation for implementation. If the water is to be used for other purposes as well (e.g. for irrigation), it is necessary to plan for usage and environmental impact. Retention and still water promotes pollutant removal through sedimentation, while aquatic vegetation and biological uptake mechanisms offer additional treatment. Retention ponds are effective in removing urban pollutants and improving water quality.
They are created either by using an existing natural depression, or by excavating a new depression, or by constructing embankments. Existing natural water bodies should not be used however, due to the risk that pollution events and poorer water quality might disturb/damage the natural ecology of the system. A great benefit of retention ponds is that they hold water when there is an excess of it, which can be used later when water is not available (e.g. for irrigation). Irrigation users are farmers, so they see the advantage of using a retention system. In addition to irrigation, water has also been needed in recent years for anti-frost systems (sprinkling a consistent layer of water on the crop during an entire frost event until temperatures are back to safe levels). Disadvantages are mainly restrictions in some areas (e.g. protected areas), preparation of demanding documentation and bureaucracy, and lengthy procedures for obtaining permits.

2.3 Fotos da tecnologia

2.5 País/região/locais onde a tecnologia foi aplicada e que estão cobertos nesta avaliação

2.6 Data da implementação

Caso o ano exato seja desconhecido, indique a data aproximada:

• 10-50 anos atrás

2.7 Introdução da tecnologia

Especifique como a tecnologia foi introduzida:

• Como parte do sistema tradicional (>50 anos)
• através de projetos/intervenções externas

Comentários (tipos de projeto, etc.):

In the 1990s, the state financed the construction of several water reservoirs in the area.

3.1 Principal/principais finalidade(s) da tecnologia

• Melhora a produção
• Protege uma bacia/zonas a jusante – em combinação com outra tecnologia
• Reduzir riscos de desastre
• Adaptar a mudanças climáticas/extremos e seus impactos
• Criar impacto econômico benéfico

3.2 Tipo(s) atualizado(s) de uso da terra onde a tecnologia foi aplicada

Uso do solo misturado dentro da mesma unidade de terra:

Não

3.3 O uso do solo mudou devido à implementação da Tecnologia?

O uso do solo mudou devido à implementação da Tecnologia?

• Sim (Por favor, preencha as perguntas abaixo com relação ao uso do solo antes da implementação da Tecnologia)

Uso do solo misturado dentro da mesma unidade de terra:

Não

3.4 Abastecimento de água

Abastecimento de água para a terra na qual a tecnologia é aplicada:

• Precipitação natural

3.5 Grupo de GST ao qual pertence a tecnologia

• Coleta de água
• Gestão de irrigação (inclusive abastecimento de água, drenagem)
• Gestão de água de superfície (nascente, rio, lagos, mar)

3.6 Medidas de GST contendo a tecnologia

3.7 Principais tipos de degradação da terra abordados pela tecnologia

3.8 Redução, prevenção ou recuperação da degradação do solo

Especifique o objetivo da tecnologia em relação a degradação da terra:

• Prevenir degradação do solo

Comentários:

To prevent erosion.

4.1 Desenho técnico da tecnologia

4.2 Informação geral em relação ao cálculo de entradas e custos

Especifique como custos e entradas foram calculados:

• Por unidade de tecnologia

Outro/moeda nacional (especifique):

EUR

Se for relevante, indique a taxa de câmbio do USD para moeda local (por exemplo, 1 USD = 79,9 Real): 1 USD =:

0,97

4.3 Atividades de implantação

	Atividade	Periodicidade (estação do ano)
1.	Costs of obtaining construction, technical and project documentation	1-2 years before before starting construction
2.	Construction of a pond	1st year
3.	Costs of supervision of construction and craftsmanship	1st year

4.4 Custos e entradas necessárias para a implantação

Se você não conseguir discriminar os custos na tabela acima, forneça uma estimativa dos custos totais para estabelecer a Tecnologia:

73600,0

Se o usuário da terra arca com menos que 100% dos custos, indique quem cobre os custos remanescentes:

The construction of a water reservoir can be subsidized from various sources (EU, state, municipalities, etc.). The largest share of support can be obtained through the Rural Development Program, where an investment can receive support ranging from 30% to 50% of eligible project cost (establishment cost).

Comentários:

The costs include excavation costs and bottom waterproofing costs. Determining the exact establishment costs for the entire project was challenging due to variations in location, topography, size, shape, dimensions, materials, soil permeability, and other factors. The specific establishment cost for the retention pond at the case study location is not available or relevant, as it would be significantly lower than the cost of constructing such a pond today (due to inflation). Therefore, we decided to use projected values based on the maximum eligible costs set by the Ministry of Agriculture for grant applications, which amount to 13.38 €/m3 (2016). This value represents the justified project cost for constructing the retention pond. In this scenario, the estimated establishment cost for a typical 5000 m3 pond would be 66,900.00 €.

4.5 Atividades recorrentes/manutenção

	Atividade	Periodicidade/frequência
1.	Energy for pumping	annually
2.	water fee	annually
3.	Maintenance costs (vegetation management, inspections, infrastructure maintenance, mulching, invasive species removal, pumping the entire pond for cleaning and sediment removal, sludge cleaning, monitoring, bank stabilization, replacement of damaged parts, and sealing, etc.)	annually

4.6 Custos e entradas necessárias pata a manutenção/atividades recorrentes (por ano)

Se você não conseguir discriminar os custos na tabela acima, forneça uma estimativa dos custos totais de manutenção da Tecnologia:

3000,0

Comentários:

Obtaining precise costs for maintaining the pond and its surroundings is challenging, as it involves various factors. The costs can include anything from labor hours and manual mowing around the pond to considering professionals for inspections, infrastructure maintenance, mulching, invasive species removal, pumping the entire reservoir for cleaning and sediment removal, sludge cleaning, monitoring, bank stabilization, replacement of damaged parts, sealing, and more. The exact costs are difficult to determine due to the highly diverse infrastructure present in different locations. We have estimated the costs per square meter of the area under maintenance, which includes both the surrounding land and the water surface. If it's only about cleaning the surroundings of the reservoir, we consider only the land area. However, if it involves cleaning within the reservoir, we also take into account the water surface area. The best rough estimates we have range from 1 to 5 € per square meter.

4.7 Fatores mais importantes que afetam os custos

Descreva os fatores mais determinantes que afetam os custos:

Construction costs are affected by the shape, size, depth and microlocation of the pond layout. In addition, the cost is also influenced by the purpose of use (e.g. if pool is intended only to contain high water, sediment or debris laoding, will it be inhabited by aquatic animals, will water be used for irrigation, drinking, etc.). Geomechanically conditions are also important, because ponds and reservoirs can affect slope stability and induce landslides. The value of the investment can vary greatly depending on the design of the pond, location, water content of the area, soil structure, climate conditions,... so it is impossible to determine the exact values for pond construction, but we can only give an estimation.

5.1 Clima

5.2 Topografia

Indique se a tecnologia é aplicada especificamente em:

• Posições côncavas

Comentários e outras especificações sobre a topografia:

There are depressions, settlements are in the valley, concave type.

5.3 Solos

5.4 Disponibilidade e qualidade de água

A salinidade da água é um problema?

Não

Ocorre inundação da área?

Sim

Regularidade:

Esporadicamente

Comentários e outras especificações sobre a qualidade e a quantidade da água:

Hydro melioration was carried out in the area, a drainage system and water retention systems (e.g. ponds and basins) were arranged.

5.5 Biodiversidade

5.6 Características dos usuários da terra que utilizam a tecnologia

Indique outras características relevantes dos usuários da terra:

Manager of an agricultural company - fruit center - poblic demonstration plantation.

5.7 Área média de terrenos utilizados pelos usuários de terrenos que aplicam a Tecnologia

5.8 Propriedade de terra, direitos de uso da terra e de uso da água

Propriedade da terra:

• Empresa

Direitos do uso da terra:

• Indivíduo

Direitos do uso da água:

• Comunitário (organizado)

Os direitos de uso da terra são baseados em um sistema jurídico tradicional?

Não

Especifique:

They are based on national legal system

5.9 Acesso a serviços e infraestrutura

6.1 Impactos no local mostrados pela tecnologia

Impactos socioeconômicos

Produção

Disponibilidade e qualidade de água

Renda e custos

Impactos socioculturais

Impactos ecológicos

Ciclo hídrico/escoamento

Solo

Biodiversidade: vegetação, animais

Clima e redução de riscos de desastre

6.2 Impactos externos mostrados pela tecnologia

6.3 Exposição e sensibilidade da tecnologia às mudanças climáticas graduais e extremos/desastres relacionados ao clima (conforme o ponto de vista dos usuários da terra)

Mudança climática gradual

Mudança climática gradual

	Estação do ano	aumento ou diminuição	Como a tecnologia lida com isso?
Temperatura sazonal	verão	aumento	bem
Precipitação pluviométrica anual		redução/diminuição	muito bem
Precipitação pluviométrica sazonal	primavera	aumento	muito bem

Extremos (desastres) relacionados ao clima

Desastres meteorológicos

	Como a tecnologia lida com isso?
Temporal local	bem

Desastres climatológicos

	Como a tecnologia lida com isso?
Onde de calor	não bem
Seca	muito bem

Desastres hidrológicos

	Como a tecnologia lida com isso?
Inundação geral (rio)	bem

Outras consequências relacionadas ao clima

Outras consequências relacionadas ao clima

	Como a tecnologia lida com isso?
Período de crescimento alogado	bem

6.4 Análise do custo-benefício

Como os benefícios se comparam aos custos de implantação (do ponto de vista dos usuários da terra)?

Como os benefícios se comparam aos custos recorrentes/de manutenção(do ponto de vista dos usuários da terra)?

Comentários:

The costs of establishing a retention pond are indeed very high, and it is a substantial investment. However, especially in the case of agricultural land irrigation, the benefits can be quite favorable, particularly in terms of drought protection or frost prevention. In the long run, the investment yields significant advantages, as it enables resilience to climate change. Farmers can also receive support through rural development programs, which provide 30-50% project funding. Although the maintenance costs can be considerable, they are necessary and offer substantial benefits to farmers who irrigate their crops or protect them from frost. From land users' perspective it's positive, if they have improved production results.

6.5 Adoção da tecnologia

• 1-10%

De todos aqueles que adotaram a Tecnologia, quantos o fizeram espontaneamente, ou seja, sem receber nenhum incentivo/ pagamento material?

• 0-10%

Comentários:

It is worth noting that the availability and extent of government subsidies can vary depending on the location, specific program, and eligibility criteria. In this research area, the majority of projects received partial funding from the government.

6.6 Adaptação

A tecnologia foi recentemente modificada para adaptar-se as condições variáveis?

Não

6.7 Pontos fortes/vantagens/oportunidades da tecnologia

Pontos fortes/vantagens/oportunidades na visão do usuário da terra
Retention ponds are simple if space is provided.
They collect water for use in drought conditions.
Retention ponds manage storm water quantity and quality, lessening the transfer of pollutants and chemicals into nearby water bodies.
Improved storm water collection and flood control.
Retention ponds provide habitats for animals, organisms, and insects (biodiversity).

Pontos fortes/vantagens/oportunidades na visão do/a compilador/a ou de outra pessoa capacitada
Local farm water retention systems allow for the detainment of water captured during spring runoff as well as during precipitation events, either directly or due to transport by surface runoff. This provides water storage that can be drawn on when groundwater supplies become depleted.
Retention ponds are designed to hold excess storm water runoff and release it slowly to avoid flooding downstream areas. They also serve to reduce downstream peak flow and aid in retaining flood waters which reduces associated flood risks downstream. If water is released from the reservoir, they serve to replenish groundwater stores downstream.
Surface water retention systems have shown success in reducing nutrient and sediment loading in various locations worldwide.
Under drought conditions these systems enable farmers to draw water from the reservoirs to support crop irrigation. The main value of water retention ponds is related to agricultural water demand in the dry season. They are considered the only effective way to preserve agricultural productivity. The ponds can increase the monetary value of agricultural land that can cope with water needs.
In addition to the primary function of retaining high waters, they often also serve a multipurpose use, such as: supply of drinking water, irrigation of agricultural land, protection against erosion, aquaculture, fishing, energy source, preservation of landscape and biodiversity, tourism, recreation and others.
Biomass production is another benefit of multi-purpose surface water retention system – cattails bioproduction and nutrient management.
In the case of construction of the so-called of a "green" water reservoir, green infrastructure solutions can provide protection for various species of animals and plants, which promotes biodiversity.

6.8 Pontos fracos, desvantagens/riscos da tecnologia e formas de superá-los

Pontos fracos/desvantagens/riscos na visão do usuário da terra	Como eles podem ser superados?
Anaerobic conditions can occur without regular inflow.	Proper planning and dimensioning of the pond, location and water level are necessary. It is necessary to ensure adequate flow and depth of the pond.
May not be suitable for steep sites, due to requirement for high embankments.	The construction of the pond is planned at a suitable location.
Colonisation by invasive species could increase maintenance and pose a danger to cultivated areas.	Regular maintenance and cleaning of the pond bank is necessary.
Safety risk in case of slipping and falling into the pond.	It is necessary to fence and isolate the access to the pond.

Pontos fracos/vantagens/riscos na visão do/a compilador/a ou de outra pessoa capacitada	Como eles podem ser superados?
Large investments in the irrigation system and access to funds for irrigation infrastructure can be difficult to attain.	The size and holding capacity of retention systems also need to be considered to maximize benefits while limiting the initial costs of building a surface water retention system.
The construction requires a lot of technical preparation, planning, documentation and there are many bureaucratic obstacles to comply with the spatial acts of the municipality and to fulfil the requirements of the spatial planning authorities, which also includes large initial costs.	The preparation and management of the project should be entrusted to a professional service. Check the conditions ahead of time and plan strategically several years ahead.
While irrigation provides an economic gain during drought years, it also increases operational costs for water supplies.	Strategies need to provide drought proofing of crops as well as limiting damages caused by floods in non-drought years to reduce risk to farmers and the region.
Experts identified some barriers for greener pond implementation, especially related to reduced efficiency. The higher surface required can cause loss of water stored during summer from the higher rate of evaporation. Another risk is associated with vegetation close to the pond banks which can reduce impermeabilization and increase water infiltration due to root growth in the soil.	Good technical plan with solutions and compromises for best results with natural (green) benefits. Considering the benefits brought by green systems.
Unregulated relations between active/potential users, both in the delimitation of water rights, especially in times of water shortage, and in cases of regulating obligations for the proper operation and maintenance.	Collective investments with a good long-term plan for operation and maintenance. Organized management of users from the organization (e.g. municipality, etc.).

7.1 Métodos/fontes de informação

7.2 Referências às publicações disponíveis

Título, autor, ano, ISBN:

An economic assessment of local farm multi-purpose surface water retention systems in a Canadian Prairie setting; Pamela Berry, Fuad Yassin, Kenneth Belcher, Karl-Erich Lindenschmidt, Appl Water Sci (2017) 7:4461–4478.

Disponível de onde? Custos?

Web

Título, autor, ano, ISBN:

Natural water retention ponds for water management in agriculture: A potential scenario in Northern Italy; Andrea Staccione, Davide Broccoli, Paolo Mazzoli, Stefano Bagli, Jaroslav Mysiak; Journal of Environmental Management 292 (2021) 112849.

Disponível de onde? Custos?

Web

Título, autor, ano, ISBN:

Natural Water Retention Measures; Report: Individual NWRM - Retention ponds.

Disponível de onde? Custos?

Web

Título, autor, ano, ISBN:

Vodnogospodarske podlage za nadzor obratovanja in vzdrževanja manjših zadrževalnikov. Miljenko Hočuršćak. Aktualni projekti s področja upravljanja z vodami in urejanje voda. 28. Mišičev vodarski dan 2017.

Disponível de onde? Custos?

Web