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Cultivos Tropicales

versión On-line ISSN 1819-4087

cultrop vol.41 no.4 La Habana oct.-dic. 2020  Epub 01-Dic-2020

 

Bibliographic review

The impact of vegetation filters on the emission greenhouse emissions

0000-0002-2105-7263Carla Fernanda Silva-Padilla1  2  *  , 0000-0002-1545-7439Diego Armando Damián-Carrión2  3  , 0000-0003-0743-9107Guido Patricio Santillán-Lima4  , 0000-0002-1642-3134Carlos Hugo Bonilla-Vega2  3  , 0000-0002-0269-4267Magdy Guadalupe Echeverría-Guadalupe2  3  , 0000-0003-4487-9208Franklin Enrique Cargua-Catagña2  3 

1Departamento de Química Analítica, Universidad de Alcalá, Madrid, España

2Facultad de Ciencias/Biotecnología Ambiental, Escuela Superior Politécnica de Chimborazo, Riobamba, Ecuador

3Grupo de Investigación y Desarrollo para el Ambiente y Cambio Climático (GIDAC), Escuela Superior Politécnica de Chimborazo, Riobamba, Ecuador

4Facultad de Ingeniería/Ingeniería Ambiental, Universidad Nacional de Chimborazo, Ecuador

ABSTRACT

The present investigation began its study wondering in what way the implementation of green filters influences the quality of wastewater, where the main objective is to study the impact of green filters as an unconventional strategy for wastewater treatment. All this in relation to the release of greenhouse gases, analyzing their emission or retention during the purification process; in addition to demonstrating that it is an appropriate technology for small communities. However, during the purification process, greenhouse gases (GHGs) can be generated as anaerobic degradation of organic matter takes place, which can be emitted into the atmosphere and thus contribute to global warming. The species commonly used in the purification process are willow (Salix spp.) Poplar (Populus spp.) and eucalyptus (Eucalyptus spp.), since they have a high purification capacity, assimilation of nutrients and rapid growth. This is how agroforestry systems have great potential for carbon sequestration due to their greater capacity to capture and use growth resources, considering them as a mitigation measure to reduce GHG emissions.

Key words: wastewater; agroforestry systems; mitigation; carbon; plantation

INTRODUCTION

The growth of the population worldwide is increasing at an accelerated rate and for its development it requires surface and underground waters, which are increasingly scarce and of poor quality, demanding the search for appropriate management to optimize the supply of drinking water and wastewater purification. Concerns arise about how to find new resources capable of helping to achieve a balance within demand and supply 1. By 2025, it is estimated that 80 % of the Earth's population lives under conditions of high hydric resource scarcity. Wastewater production is responsible for generating 5 % of global carbon dioxide (CO2) emissions in 2005, and these emissions are projected to increase by 27 % by 2030 2.

Wastewater treatment has evolved at different rates throughout history; for millennia, they were poured into water sources and, alternatively, they were poured over fields to increase soil fertility. The application, with or without crops, remained active until well into the 20th century and is currently practiced in developing countries or where water is scarce and the management of sanitation systems is poorly developed, with Mexico being one of the main Latin American countries to use wastewater for forest irrigation 3.

The European Union (EU) Regulation 525/2013 of the United Nations Framework Convention on Climate Change and its Kyoto Protocol establish obligations to reduce GHG emissions, as well as information on anthropogenic emissions and sinks of these gases. This global framework aims to mitigate the effects of global warming 2.

Within this context, and as a result of the purification process, the emission of greenhouse gases (GHGs), especially methane (CH4), (CO2) and nitrous oxide (N2O), could occur. Therefore, the main objective is to study the impact of green filters in relation to the release of greenhouse gases, analyzing their emission or retention during the wastewater treatment process.

Green filters in the treatment of wastewater to the ground

In green filters, purification occurs naturally, based on ecological and biological principles that complement or replace current civil works. It consists of a forest plantation area (mainly poplars, willows or eucalyptus) on which a controlled flow is applied of residual water, where the physical filtration, the absorption in the soil, the biodegradation and the absorption of the plant are the main physical, chemical and biological processes. With the joint action between the soil the microorganisms and the plants are responsible for the attenuation of pollutants 4, optimal and recommended for populations of less than 25,000 inhabitants 5.

In this type of treatment, the soil acts as a receiving medium for wastewater and as an active agent in the purification process, mainly eliminating nutrients, organic matter (OM), microorganisms and other components, such as heavy metals or organic micro-contaminants. In the green filters, (FVs) arboreal vegetation is installed (poplars, willows or eucalyptus) and a controlled flow of pre-treated residual water is applied as irrigation water. The water evaporates partially and the rest is captured by the roots of the trees and filtered (to a greater or lesser extent depending on the design criteria), through the soil 6.

Plants, microorganisms and soil interrelate to carry out purification processes, where physical processes, such as filtration, occur; chemical, such as precipitation or ion exchange and biological, such as the degradation of OM found in water (7.

Pollutant removal mechanism

Next, the mechanisms of elimination of the pollutants present in the wastewater are described, detailing which are the physical, chemical and biological processes that will lead to the formation of the different GHGs.

Suspended solids. In water treatment systems, by applying residual water to the ground, the removal of suspended solids (SS), organic and inorganic, occurs mainly by filtration, through the whole that forms the soil with the rhizomes and roots depending on the grain size and texture of the soil 8. Since most of the SS is removed on the ground surface, treatment systems need to be designed in a way that minimizes loss in filtration capacity.

Organic Matter. The transformation of OM occurs by bacterial degradation, developing mainly on the ground surface in aerobic conditions. Plants assimilate the nutrients from OM (phytoextraction), carrying out two main transformation processes: photosynthesis and aerobic respiration carried out by aerobic bacteria in the so-called aerobic horizons (soil), where degradation occurs up to 5 cm deep in the areas near the roots 9. As water percolates in the soil, the amounts of O2 are reduced, producing anaerobic conditions, where anaerobic heterotrophic bacteria can degrade OM by anoxic route, using nitrate (NO3 -) as electron acceptor (denitrification process) 8. Anaerobic degradation of OM follows the processes of hydrolysis, acidogenesis, acetogenesis and methanogenesis 10, to obtain mainly CO2 and CH4 as final products (Scheme 1) 11.

Organic matter+H2O anaerobiosisCH4+CO2 (Sch.1)

The process begins with the hydrolysis of complex organic biopolymers (proteins, carbohydrates and lipids) into monomers (amino acids, sugars, long-chain fatty acids), by the action of hydrolytic bacteria. It is important to note that, in acidogenesis and acetogenesis, the products of hydrolysis are transformed into short-chain organic acids, H2 and CO28. Finally, CH4 is produced in the methanogenesis by action of the methanogenic bacteria.

Nitrogen. Urban wastewater is characterized by containing N mainly in the form of NH4 +, NO3 - and organic N 12. The mechanisms involved in the elimination of N vary depending on the way in which this nutrient is present:

  • Organic nitrogen: the fraction that is associated with the SS and OM present in the wastewater, it is removed by filtration, and can be incorporated directly into the soil. In the case of OM that is not easily degraded, the soluble part in amino acids is hydrolyzed to then have NH4 + as a product 8.

  • Ammoniacal nitrogen: NH4 + in soluble form can be removed by direct volatilization into the atmosphere as gaseous NH3 (10 %), but most of NH4 + (and the converted) is reversibly adsorbed, through exchange reactions ionic to soil particles (clays and electrically charged organic molecules) 8. The adsorbed NH4 + can be captured by the vegetation and by the microorganisms present in the soil and can be transformed into NO3 - by means of biological nitrification reactions. Vegetation can assimilate NO3 -, but this only occurs near its roots and during growth periods 8.

  • Nitrate: NO3 - can be removed by biological denitrification and release of N2 gas and N2O into the atmosphere. This mechanism constitutes the main route of elimination of N in the systems of application to the terrain. Denitrification is carried out by facultative bacteria under anoxic conditions, it is not necessary that the entire system be anoxic, taking into account that the C/N ratio is sufficiently high, at least 2:1, since NO3 is taken during the process as electron acceptors for the degradation of MO 9. In this case, denitrification in the root zone (rhizosphere) can also contribute to a decrease in the concentration of N in the system. N2O and NO are produced in the soil mainly during two microbial processes: nitrification (from NH4 + to NO2- and from this to NO3 -) and denitrification (from NO3 - to N2O and finally to N2) 13.

Impact of green filters on the emission of GHGs

In the treatment of residual waters with FVs, the nutrients (N, P) are captured and retained by the plant to be later expelled through the leaves and roots into the atmosphere. Organic pumping through the root nodules, which has a high water absorption capacity, will carry out decontamination. This action of water absorption decreases the leaching of pollutants into deep layers of the soil 7. It has been reported that there is an exact coupling of gas transport at the biochemical level that is necessary, because CH4 and N2O can be produced and consumed in the soil, and the eventual flow to the atmosphere depends on the reaction sites and the escape routes of these gases 14.

Influential factors in the emission of GHGs

Microbial activity, chemical decomposition processes, as well as the heterotrophic respiration of microorganisms, produce GHG in soils. During the purification process with VFs, anaerobic, aerobic respiration and reactions such as methanogenesis and denitrification are affected by external factors; as the organic load contained in the waste water, which implies greater production of gases, especially CH415.

Temperature. Soil temperature can explain 74 and 86 % of the variations in NO and N2O emissions, respectively. An increase in soil temperature leads to higher emissions and higher soil respiration rates as a positive feedback response to increased microbial metabolism. CH4 and N2O emissions are also by increasing soil respiration rates forced with increasing soil temperatures 16.

Exposure and air pressure. Exposure of the site (elevation, morphological position, vegetation cover) influences soil temperature and humidity. N2O emissions are higher on troughs than on slopes and ridges due to higher soil moisture. Lower air pressure supports higher soil emissions due to reduced backpressure in the ground 16.

Organic matter. The OM of the soil is a diverse mixture composed of microbial biomass, dead roots, plant residues in various stages of decomposition and soil humus 17, being the humus the result of microbial activity that comprises 60-80 % of the total OM of the soil.

The decomposition of OM constitutes a basic biological process in which C is recirculated into the atmosphere, as CO2; N is available, as NH4 + and NO3 - appear as required by higher plants. In this process, part of the C is assimilated into the microbial tissue (soil biomass) and another part is converted into humus 18. In the process of mineralization and decomposition of OM, CO2 is emitted into the atmosphere; while, during the time that C is forming part of the plant structures, considering C as retained (C sink). The same occurs with C, which is part of non-bioavailable biodegradable materials (humus) 18.

The higher the content of C retained in plants or soil and for a longer time, then the less is the amount that will exist in the atmosphere. The application of wastewater to the soil significantly increases the content of organic C in all forms of C, both labile forms and recalcitrant fraction 19. The amendment of the soil with charcoal obtained from plant remains and biomass residues (biochar) is evaluated worldwide, as a means to improve soil fertility, mitigate climate change 20,21 and decrease GHG emissions from the ground, such as N2O or CH4.

Sustainable biochar production (used as a soil amendment) has been shown to have the mitigation potential due to its highly recalcitrant nature, slowing down the rate at which photosynthetically bound C returns to the atmosphere 22. It is possible that CO2 precipitates as CO3 2- on biochar surfaces, which have high pH and abundant alkali metals, which would explain the reduced detection of CO2, despite the increases measured in microbial biomass 23.

Microbial activity. The microorganisms in the soil represent the living fraction of the OM, and the obtaining of recalcitrant materials will largely depend on them but microorganisms to become recalcitrant OM 24 transform another large part of OM.

The MO content and the amount of N in the soil control microbial activity. The soil is a favorable habitat for the proliferation of microorganisms and microcolonies develop in the particles that form it. Microorganisms isolated from the soil include viruses, bacteria, fungi, algae and protozoa. OM concentrations are relatively high in such environments, which favor the development of heterotrophic microorganisms. Large contributions of OM and nutrients can improve the growth of microbial organisms and, therefore, the nitrification and denitrification processes provide a greater amount of dissolved organic C (COD) 25.

Vegetation. The selection of the vegetation to be implanted in the FVs will depend on the function of the cultivation type and the age. Being optimal those that present a high capacity of assimilation of nutrients, rapid growth, great consumption of water by transpiration, tolerance to humid soils, low sensitivity to the components of the wastewater and minimal operating requirements 26.

Among the crops that meet all, or most, of these conditions are different herbaceous species (couch grass) (Cynodon dactylon), ryegrass (Lolium), Italian ryegrass (Lolium multiflorum), and certain tree species such as willow (Salix poplar) or poplar (Populus spp.) and eucalyptus (Eucalyptus spp). The use of tree species with a high rate of evapotranspiration, and the fact that their root systems show excellent tolerance to anaerobic conditions, allows the application of considerable amounts of wastewater. Generally tree species such as willows (Salix spp.) Poplars (Populus spp.) and eucalyptus (Eucalyptus spp.) 25.

C retention in agroforestry systems as a mitigation measure

Agroforestry systems (AFS) have received increased attention due to their ability to sequester CO2 from the atmosphere in aerial biomass, stems, branches and foliage, and in underground biomass, i.e. roots and on the ground. AFS are to have great potential for C sequestration believed due to their ability to capture and use growth resources (light, nutrients and water) than monoculture or pasture systems 27.

The volume of aboveground biomass and deep tree root systems in the AFS have received increased attention for adaptation and mitigation of climate change. In agroforestry systems up to 1m deep in the ground, global estimates of C sequestration potential over a 50-year period range from 1.1 to 2.2 mg C year-1 but in particular, land area estimates are very uncertain 28.

Willow (Salix spp.), Poplar (Populus spp.) and eucalyptus (Eucalyptus spp.) are the main types of tree vegetation used in PV. In particular, the presence of willows and poplars positively influences the GHG treatment process 29. In the same way, they studied the performance of the poplar, since the photosynthesis process is among the highest due to its great capacity for growth, and for fixing CO2 from the atmosphere 25.

In countries such as Sweden, Poland, Denmark and Estonia, the efficiency of willow as a green filter in wastewater purification has been proven where the roots have the capacity to absorb 75-95 % of nitrogen (N) and phosphorus (P) in wastewater (30). When willow is used for energy purposes, that is, for the conversion of electricity from heat, this energy source can be considered as CO2 neutral, because it does not affect the amount of so-called greenhouse gases in the atmosphere.

During growth, willow recovers the same amount of CO2 as it is released during combustion, and the delay time is a matter of months rather than years 30.

CONCLUSIONS

  • Green filters are highly efficient, as technologies applied to the soil for the treatment and reuse of pretreated wastewater. Thanks to the joint action of soil, microorganisms and vegetation, they turn out to be an efficient method of reducing the emission of pollutants the higher the C content retained in the plants and soil; the amount of GHGs in the atmosphere will be less.

  • The efficiency of the FVs in relation to the GHGs will depend on various factors including temperature, the amount of organic matter contained in the wastewater, and mainly type of vegetation. The poplar (Populus spp) and the willow (Salix spp) are the tree species commonly used, not only for their rapid growth, resistance to pests and climate changes, but also for the great capacity for absorption and accumulation of CO2 and C fixation. That is why, the practice of AFS is a mitigation measure that helps C sequestration to help reduce GHG emissions, and demonstrate that it is an appropriate technology for small communities both economically and environmentally.

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Received: September 30, 2019; Accepted: June 07, 2020

*Author for correspondence: nandala_18@hotmail.com

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