Lysimeter Study Research Articles

Aeration Optimization for the Biodrying of Market Waste Using Negative Ventilation: A Lysimeter Study

This study investigates the optimization of aeration rates for the biodrying of market waste using negative-pressure ventilation. Market waste, characterized by a high moisture content (MC) and rapid decomposition, presents challenges in waste management. Over 12 days, three aeration rates (ARs) of 0.2, 0.4, and 0.6 m3/kg/day were examined, and the most effective continuous ventilation configuration was identified in terms of heat generation, moisture reduction, and biodrying efficiency. The results indicate that the most effective AR for heat retention and moisture removal was 0.2 m3/kg/day, achieving a 6.63% MC reduction and a 9.12% low heating value (LHV) increase. Gas analysis showed that, while AR 0.2 supported high microbial activity during the initial 7 days, AR 0.6 sustained higher overall CO2 production due to its greater aeration rate. The findings also suggest that the biodrying of market waste with a high initial MC can achieve significant weight loss and leachate generation when paired with a high aeration rate of 0.6 m3/kg/day, with a 69.8% weight loss and increased waste compaction being recorded. The study suggests that variable ARs can optimize biodrying, making market waste more suitable for conversion to refuse-derived fuel or landfill pre-treatment and improving waste-to-energy processes and sustainability.

Risk for nitrogen leaching after application of solid manure in autumn differs between manure types

Manure application performed in autumn requires regulation due to the risk of nitrogen (N) leaching during winter. On the other hand, application of manure in spring can pose some practical problems depending on the risk for N immobilization and the difficulty in ploughing heavy clay soils during this time of year. The risk for leaching is likely to differ between different soil texture and manure characteristics. In this study, we sought to estimate the risk for nitrogen leaching depending on the carbon/nitrogen ratio (C/N) of the manure, time for manure application, and soil type. We combined 3-year lysimeter experiments with 2-year field plot experiments and laboratory soil incubations and compared results with those from an empirical model. We compared effects of manure application on two soils (silty clay and loamy sand) and solid manures with different representing C/N ratios. In incubations, only manure with a C/N-ratio below 14 contributed with significant amounts of leachable N during the first months after application. In the lysimeter study, N leaching was unaffected by the timing of the application of the manure with C/N-ratio 18. However, regarding manure with C/N-ratio 10, N leaching was elevated with 10–15 kg N per ha after manure application in October compared to November and March on both soil types. The mineral N analyses from soil profiles in the field experiments showed a similar pattern, however, the increase was higher on the loamy sand compared to the silty clay. The ammonia emissions did not differ between manure types, but were on average 24% of applied NH4-N after application in October when air temperature was on average 12°C compared to only 3% of applied NH4-N in November and March when air temperature was on average 5°C. Similar to lysimeter results, the modelled N leaching was higher the earlier the manure application occurred in autumn. However, the model also predicted increased leaching for the manure with a high C/N-ratio, and a smaller effect on leaching on clay soil. Considering this, the model calculations overestimated the leaching effects from manure with a high C/N-ratio and underestimated the leaching effects on clay soil.

Analysis of Precipitation and Runoff Against Quality Characteristics of Surface Water in Carpathian Areas (Based On Lysimetric Studies)

Analysis of Precipitation and Runoff Against Quality Characteristics of Surface Water in Carpathian Areas (Based On Lysimetric Studies)

Distribution and redistribution of salt ions in saline soils with shallow groundwater table

Saline water resources are more abundant than freshwater. Bringing these resources into sustainable, productive use will offer opportunities to reduce competition for freshwater resources, especially in arid and semi-arid areas where freshwater is scarce. Hence, the primary objective of this study was to elucidate the dynamics of salt ions in saline profiles of various soil types (sandy Clovelly and sandy loam Bainsvlei) under malt barley cultivation across 2 seasons where no leaching between the seasons took place. Results of this lysimeter study investigating increasing irrigation salinity (ECi) set at 1.5, 4.5, 6, 9, and 12 dSꞏm−1 over 2 seasons were used to explore ion dynamics of a saline environment. The lysimeter set-up included a saline constant (1.2 m) groundwater table with its salinity corresponding to ECi. Findings showed that ion concentrations are higher closer to the water source only in the Bainsvlei soil and remain variable in the Clovelly soil. Salt dynamics were more predictable in sandy loam soil than in sandy soil, making management of saline sandy soils far more challenging when leaching is not possible. Therefore, our hypothesis that the absence of leaching between seasons will lead to a differentiated progressive accumulation of salt ions in the soil profile, with variable effects on the soil depending on soil texture, was true. We conclude that the desalinized zone, which we determined to be at a depth of 600 mm, should be used to guide crop selection. Furthermore, in addition to the apparent provision for leaching of saline profiles, fertilization should target restoring ion balances, especially provisioning for calcium deficiencies. Both soils were prone to nutritional disorders, most especially calcium deficiency. Therefore, in addition to provision for leaching saline profiles, fertilization should target calcium provisioning for crop production in arid saline environments.

Irrigation of rangeland soils with coal seam water - A lysimeter study on soil physico-chemical properties

Groundwater extracted from coal seams may be a resource for irrigation of land in areas with low rainfall, but the effect of this water on soil properties needs to be established. A lysimeter study was conducted using intact soil cores (0.75 m diameter, 1.4 m deep) of four different soil types (Sodic Vertisol, Calcic Solonetz, Haplic Solonetz and Xanthic Lixisol) from southern Queensland, Australia, to study changes in soil physical and chemical properties under accelerated rates of irrigation with coal seam (CS) water (electrical conductivity (ECw) of 3 dS/m, pH of 8.8, and a sodium adsorption ratio (SAR) of 100). Cores were also alternately irrigated with deionised water to simulate rainfall, and either lucerne (Medicago sativa L) or Rhodes grass (Chloris gayana Kunth.) where grown in the lysimeters. The soil surface was treated with stoichiometric rates of elemental sulfur (1.4 t/ha) and gypsum (2.5 t/ha) prior to every 450 mm CS water irrigation to minimise changes in SAR and pH. Three of the soils (Vertisol, both Solonetz) had low leaching fractions (≤ 0.1 %) due to their clay texture and were initially saline in the subsoil (ECse 1.4–4.4 dS/m). Irrigation with CS water resulted in a gradual increase in salt content (EC) and SAR throughout the soil profile, but pH was not increased due to surface-applied elemental sulfur. The Lixisol had a higher hydraulic conductivity and leaching fraction (6.7 %) due to is loamy texture – in this soil, accumulated salts could be leached and no increase in salinity or pH were measured. Despite an increase in SAR for this loamy soil, no structural degradation was observed, and it could be sustainably irrigated with up to 3200 mm CS water (with cumulative irrigation volume of 5400 mm). Hence, leaching fractions rather than soil chemistry are good indicators to identify soils suitable for irrigation with CS water that is saline, alkaline, and sodic.

Biochar from paddy field - A solution to reduce PFAS pollution in the environment

Generally, activated carbons demonstrated a notable ability to capture long-chain PFAS, but exhibited relatively lower effectiveness for short-chain PFAS. Thirteen commercially available activated carbons in Japan underwent testing for their adsorption capacity of PFAS in water. The activated carbon derived from rice husk, Triporous™-PFAS, exhibited the highest adsorption capacity (over 95%) for PFAS from ultrashort-chain (perfluorocarbon chain: C1 for perfluorocarboxylic acid (PFCA) and C2 for perfluoroalkane sulfonic acid (PFSA)) to long-chain PFAS (C13 for PFCA and C10 for PFSA). An earlier lysimeter study highlighted Andosol, representative soil in Japan, as a potential medium for removing PFAS from irrigation water. Considering cultivating rice on Andosol fields and producing biochar from rice husks and rice straw, a new rice cultivation system is proposed. This system aims to facilitate continuous removal of PFAS from the environment in Asia. Japanese rice cultivation system produces not only rice but also biochar to remove PFAS from water circulation system. The total fluorine content in the tested activated carbon materials ranged from 0.18 to 38 μg g−1 F. Based on the results from background F blank and adsorption capacity, TriporousTM-PFAS-F was shown to be an option to lower the method detection limit for a proposed international standard method for measuring total PFAS.

Evaluating MONICA's capability to simulate water, carbon and nitrogen fluxes in a wet grassland at contrasting water tables

Wet grasslands, which are vital for water and nutrient regulation, are characterised by distinct water, carbon (C) and nitrogen (N) dynamics, and their interactions. Due to their shallow groundwater table, wet grasslands promote a strong interconnection between diverse vegetation and soil water. Researchers have investigated how wet grasslands respond to environmental changes, using various simulation models to understand how these sites contribute to water, C and N dynamics. However, a comprehensive, simultaneous study of all three of these dynamics is still lacking. This study makes use of a grassland lysimeter study with differently managed groundwater levels and employs the process-based MOdel for NItrogen and Carbon dynamics in Agroecosystems (MONICA) to simulate these dynamics. By using SPOTPY (Statistical Parameter Optimization Tool) to optimise the relevant parameters, we find that MONICA performs well in simulating vegetation growth (aboveground biomass), and elements of the water (evapotranspiration), C (gross primary productivity, ecosystem respiration) and N (N in aboveground biomass, nitrate in soil solution, Nitrous oxide emissions) balance, with Willmott's Refined Index of Agreement always larger than 0.35. This level of accuracy demonstrates that MONICA is ready to be applied for scenario simulations of groundwater management and climate change to evaluate their impact on greenhouse gas emissions and long-term carbon storage, as well as water and nitrogen losses in wet grasslands.

Изучение закономерностей передвижения, накопления влаги и химических веществ в агроэкосистемах по результатам лизиметрических исследований ФНЦ «ВИК им. В.Р. Вильямса»

Lysimetric studies were carried out at the lysimetric station of the Institute in different years in the agroecosystem "surface layer of air — plant — soil — infiltration runoff". These studies are highly appreciated in our country and in the world. They attract the attention of domestic and foreign researchers. With the help of lysimetric studies, it is possible to monitor the condition and development of plants, the dynamics of soil condition, the rate of deterioration of soil fertility, to anticipate and prevent possible waterlogging of irrigated lands in the shortest possible time. Lysimetric studies make it possible to determine the quality of irrigation water, establish the optimal irrigation period and rate, taking into account plant biology and hydrology of the site. Irrigation norms justified by lysimeters increase the efficiency of fertilizers, while maximally involving in the cycle the contained nutrients not only of the applied fertilizers, but also of the soil. Mobilization of plants' assimilation of basic nutrients (N, P, K, Ca) also allows to reduce losses due to leaching. The results obtained allow us to calculate the balance of nutrients in the soil and choose the best crops and fertilizer systems that ensure optimal productivity of agricultural land and reproduction of soil fertility.

Лизиметрическим исследованиям в Федеральном научном центре кормопроизводства и агроэкологии имени В.Р. Вильямса исполнилось 50 лет

The study of ecosystems, biological and ecological features of perennial grasses, soils, groundwater and monitoring of their dynamics are impossible without lysimetric studies. Lysimeters serve as a reliable means of studying and managing agroecosystems and the entire complex of plant development factors. At the All-Union Williams feed research Institute, lysimetric studies on the study, regulation and forecasting of water, food and thermal regimes of reclaimed natural forage lands in the agroecosystem "soil — plant — infiltration runoff" on irrigated pastures in the conditions of the Central District of the Non-Chernozem zone (Moscow region) were started at the Lysimetric Station built in 1972. The station includes a laboratory building, a tunnel room with a depth of about 3 m and a length of more than 40 m, a hardware room, lysimetric devices and installations of a special design. The lysimetric installation allows you to jointly study the water balance, the balance of chemicals and automate the observation processes. The developed design of the measuring equipment increased the accuracy of the experiment, and due to its small dimensions, it allowed experiments to significantly expand the range of studied groundwater depths (from 0.75 m to 2 m). Lysimeters of 2 types (for water balance and agrochemical studies) are designed for year-round observations. The results of lysimetric studies are extrapolated to areas with similar environmental conditions.

The influence of increasing mineral fertilizer application on nitrogen leaching of arable land and grassland—results of a long-term lysimeter study

IntroductionDespite various efforts to reduce nitrogen leaching from agricultural land, the permissible nitrate concentrations in groundwater have often been exceeded in the past. Intensive farming is often seen as the cause of the deterioration in water quality. Therefore, the present lysimeter study aimed to quantify nitrogen (N) leaching at different N fertilization levels for the agricultural land use systems of arable land and grassland to derive suitable management measures for improving groundwater quality.MethodsThe effects of three different of mineral fertilization treatments (50%, 100%, and 150%) in arable land and grassland use on four distinct soil types (loamy sand, sand, loam, loess) concerning seepage formation, nitrogen concentrations, nitrogen loads, dry matter yields and nitrogen balances were tested. The study was conducted at the lysimeter facility of the Helmholtz Centre of Environmental Research – UFZ at Falkenberg (northeast Germany). Twenty-four non-weighable lysimeters with a surface area of 1 m² and a depth of 1.25 m were managed as grassland and arable land with three different fertilization treatments since 1985.Results and DiscussionFor arable land use, N leaching differed between the studied soil types, with the highest N loads from the sand (36.6 kg ha–1 yr–1 ) and loamy sand (30.7 kg ha–1 yr–1 ) and the lowest N loads from loess (12.1 kg ha–1 yr–1) and loam soil (13.1 kg ha–1 yr–1). In contrast to grassland use, a reduction of N fertilization level by 50 % did not result in reduced N leaching for arable land, whereas a maximal 29% reduced dry matter yields was observed. An increase of N fertilization by 50 % did not cause significant enhanced N leaching at arable land use. Soil-and management-related factors (soil type, texture, soil tillage, crop rotation, and others) mask the effect of increased N fertilization rates in arable land using lysimeters. For arable land use, a reduction of N fertilizer levels as the only measure was insufficient to reduce NO3– leaching, and other strategies besides N fertilization levels are required to improve groundwater quality. Measures should be targeted to reduce N losses by mineralization processes.

Potential and risks of water reuse in Brandenburg (Germany) – an interdisciplinary case study

Abstract For Brandenburg, a region in Germany with increasing water shortage and drought events, water reuse can counteract competition scenarios between drinking water supply, agricultural irrigation, and industrial use. Centralized and decentralized sources for reclaimed water are found to potentially substitute 245 or 28% of irrigation water, respectively, in agriculture production in Brandenburg. For such a reuse scenario, the fate of organic micro-pollutants is examined for diatrizoate (DZA) and carbamazepine (CBZ). Retention in local sandy soil and transfer into roots and leaves of arugula are analyzed in lysimeter studies and greenhouse pot experiments. Vertical transport was found for DZA and accumulation in or on arugula roots with a root concentration factor of 1,925 ± 34% but a low bioconcentration factor due to intrinsic molecule properties. CBZ was not found to be mobile in the sandy soil but accumulates in arugula roots and leaves by factors of 70 ± 7% and 155 ± 12%, respectively. Further research on potential plant uptake and groundwater enrichment for more substances is highly recommended as well as tertiary wastewater treatment prior to water reuse.

Maize yield response to nitrate leaching at early growth stage under crop and site-specific biosolid application

Biosolid applications based on crop nitrogen (N) demand have been widely adopted to attenuate nitrate leaching. However, due to the dependence of N supply on the mineralization rate and the early release of the majority of the mineralizable N, there are concerns about a compromise in crop yield and groundwater. A two-year field lysimeter study was conducted to verify whether higher nitrate leaching from biosolid at the early growth stage would compromise maize yield compared to a two-split inorganic N fertilizer application. Four treatments (biosolid + humid rainfall, inorganic fertilizer + humid rainfall, biosolid + subhumid rainfall, inorganic fertilizer + subhumid rainfall) replicated three times were randomly allocated to 12 lysimeters. Overall, the cumulative nitrate leaching from biosolid application was comparable to inorganic fertilization. Nitrate leaching at the early (V0–V14) growth stage of maize from biosolid was lower than inorganic fertilizer, except in the second year under humid rainfall. However, nitrate leaching did not compromise maize yield. Thus, biosolid application based on crop and site specificity can replace inorganic fertilizer in maize cultivation. Further studies may need to ascertain the findings in the humid agro-ecological zone because of the high soil N residue observed under biosolid-humid rainfall treatment.

Nutrient Balance during Crop (Forage Barley) Cultivation in Winter Season: A Weighing Lysimeter Study

Nutrient Balance during Crop (Forage Barley) Cultivation in Winter Season: A Weighing Lysimeter Study

Water footprint of paddy cultivation under controlled runoff conditions: A case study in Kurunagala district, Sri Lanka

Paddy cultivation is the largest global consumer of water, and it also significantly contributes to water pollution. Investigating the water footprint of paddy agriculture can provide insights into how pollutants affect the ecosystem. This study aimed to quantify the total water footprint for paddy grown in Sri Lanka's Low Country Intermediate Zone under supplementary irrigation. A lysimeter study was carried out to determine the amount of leached nutrients below the root zone. The experimental design was a Complete Randomized Block Design (CRBD) with two factors (cropping season and gradient) and two levels (Yala and Maha; upper and lower). The green and blue water footprints for both sites were estimated using the CROPWAT 8.0 model by crop water requirement option. The results revealed that the loss of NO3-N through leaching accounted for 8.61 ± 1.84 kg/ha (8%), and the leaching losses of PO43-- P were 0.49 ± 0.1 kg/ha (2%) under controlled runoff conditions during the experimental period. The nitrogen fertilizer-induced grey water footprint (WFgrey) for one tonne of rice produced was 193 ± 27 m3/t, and the phosphorous fertilizer-induced WFgrey was 61 ± 7 m3/t. The study identified nitrate as the critical element for water pollution. The estimated total water footprint (WFtotal), which was the sum of green, blue, and grey water footprint, was 1409 ± 95 m3/t under controlled runoff conditions, while the global average value is 1325 m3/t. The estimated value is about 6% higher than the global average value. Therefore, these findings demonstrate the need for further research.

Bromide reactivity in topsoil: Implications for use as a “conservative” tracer in assessing quantity and quality of water

AbstractBromide is a frequently used conservative tracer in soil leaching studies, including studies on contaminant leaching from arable topsoils. However, bromide often does not behave conservatively. Biogeochemists have known for many years that in natural soils, bromide is converted into organic bromine in a process known as bromination. However, bromination is seldom used as an explanation of non‐conservative leaching behavior by soil hydrologists. In a controlled small‐scale lysimeter study with arable soil we demonstrate such nonconservative behavior of bromide in opposition to control columns with fine gravel/coarse sand. By combining a literature review with the lysimeter study, we demonstrate the potential importance of bromination in topsoil and that bromination cannot be ignored, when interpreting bromide tracer experiments in arable soils. We also highlight the need for further studies on the processes of bromination and remineralization, to be able to account for these when conducting bromide leaching assessments.

Modeling biochar-soil depth dependency on fecal coliform straining under subsurface drip irrigation

Biochar has several benefits for soil, including improved flow and retention properties that decrease bacterial transport. To improve understanding of the underlying mechanisms and optimal irrigation strategies for contaminated gray water, we conducted a lysimeter study exploring impacts of biochar level (0, 0.5, and 1% w/w) and 30-days irrigation regime (0.003 and 0.0064 cm h−1). Biochar did not change hydraulic properties but at maximum allowable depletion (MAD) of 30, 50, and 70% biochar had a large impact on fecal coliform retention. At 15–25 cm depth where the subsurface dripper was located, 1% biochar-treated soil had 1.5 times greater retention than the controls. A combination of the lower irrigation rate (0.003 vs. 0.0064 cm h−1) and the greater biochar (1% vs. 0.5%) had greater impacts on bacteria inactivation and retention than the MAD levels. Nevertheless, adding 1% biochar resulted in a 2-fold increase of bacteria retention for 30% MAD and low flow rate than greater flow rates and MAD levels (50 and 70%). Our results provided novel data for inverse optimization to explore bacteria retention by differences in bacteria attachment, straining, survival or growth. Close to the irrigation dripper, straining was the pronounced mechanism under the best performing treatment of 1% biochar and 30% MAD. Therefore, we recommend application of biochar at the rate of 1% where wastewater is used for subsurface drip irrigation.

The impact of irrigation with treated wastewaters on soil and kikuyu grass nutrient compositions.

A lysimeter study was conducted for 1 year to examine how the source of wastewater for irrigation impacted soil physicochemical properties and kikuyu grass (Pennisetum clandestinum) nutrient composition. The wastewater used included treated wastewater produced by a membrane bioreactor (MBR) and intermittently decanted aerated lagoon (IDAL) treatment systems. No significant differences were observed between the treatments regarding total nitrogen and total phosphorus across the depths of the columns. However, highly significant differences were observed for Na content of the soils at various depths. Remarkable differences were recorded for soil exchangeable K and Na at different depths. In contrast, soil exchangeable Ca and Mg experienced no significant differences concerning the depth of the columns. For kikuyu grass, sodium contents of the grasses irrigated with MBR and IDAL treated wastewaters increased more than 200% and 100%, respectively, when compared with the grass irrigated with tap water. Over the period of monitoring considered in this study, there was no sign of excessive soil salinity/sodicity issues. The MBR treated wastewater has the potential to supply the grass with a constant dosage of valuable nutrients such as N and P without the requirement of using chemical fertilizers. This reduces the risk of contamination of receiving waters and groundwater and enhances the recycling of the nutrients in the wastewater to achieve a circular economy of nutrients. PRACTITIONER POINTS: Application of treated wastewaters revealed no harmful effects on soil and plant nutritional properties over the study period. The membrane bioreactor (MBR) treated wastewater potentially supplies the grass with constant dosage of valuable nutrients in the absence of chemical fertilisers. Sodium contents of the grasses irrigated with MBR and IDAL treated wastewaters increased more than 200% and 100%, respectively. Soil soluble and exchangeable cations showed very similar trends of changes versus the depth of the soil over the study period.

Plant availability and leaching of 15N‐labelled mineral fertilizer residues retained in agricultural soil for 25 years: A lysimeter study

AbstractBackgroundA high use‐efficiency of fertilizer N remains essential to sustain high crop productivity with low environmental impact. However, little is known on the long‐term lability of mineral fertilizer N.AimsTo quantify crop uptake and leaching of 15N‐labelled mineral fertilizer that has been retained in an agricultural soil for 25–30 years in crops with variable growing season.MethodsA field plot received 15N‐labelled mineral fertilizers over a period of 5 years and was then kept under arable cropping for 12 years. After relocation to 16 lysimeters, the topsoil grew set‐aside grassland for the next 13 years. Then crop uptakes and leaching losses of 15N remaining in soil was tested over a 2‐year period by either converting set‐aside grass to production grassland, or by replacing it with spring barley (+/− autumn cover crop) or vegetation‐free fallow. All treatments received unlabelled mineral N fertilizers.ResultsCrop uptake and leaching of 15N were generally highest in the first test year after termination of the set‐aside. The leaching of residual 15N in soil declined in the order: vegetation‐free soil (4.7%), spring barley (1.9%), spring barley + cover crop (0.7%) and production grassland (0.2%). Corresponding losses for the second leaching period were 2.7%, 0.9%, 0.4% and 0.06%. There was a fixed relationship between leaching losses of 15N and total N.ConclusionsAfter residing in soil for 25–30 years, the lability of labelled mineral N fertilizer residues appeared slightly higher than the lability of bulk soil N. Autumn vegetation was crucial for reducing leaching losses.

Effect of biosolids amendment on the fate and mobility of non-steroidal anti-inflammatory drugs (NSAIDs) in a field-based lysimeter cell study

Non-steroidal anti-inflammatory drugs (NSAIDs) are widely used globally to treat and prevent illness. Biosolids change physico-chemical characteristics of soil and can affect the mobility of NSAIDs. A field-based lysimeter study evaluated the effect of three rates (0, 7, and 28 Mg ha−1) of alkaline treated biosolids (ATB) on the leaching potential of naproxen (NPX), ibuprofen (IBF), and ketoprofen (KTF) over 34 days in a sandy loam textured soil. Although all three NSAIDs in the lysimeter cells vertically migrated to deeper soil depths after spiking, the sum of all NPX, IBF, and KTF detected in the leachate samples from all treatments were only 0.03%, 0.02%, and 0.04% of the initial spiking mass to the surface soil, respectively. A mass balance analysis indicated a low accumulation of these compounds in the soil at the end of the study (Day 34) from all treatments with only 4.8%, 0.5%, and 0.7% of initial spiked NPX, IBF, and KTF, respectively. Application of ATB significantly increased soil pH and organic matter (OM) content of the soils but did not impact retention of the compounds in the soil profile. Overall, all three NSAIDs in the present study presented low mobility in the loamy sand textured agricultural soil.

Перспективні енергетичні культури на осушуваних торфовищах Лісостепу та їх водоспоживання в умовах зміни клімату

Goal. To determine the productivity of energy plantations, to investigate the parameters of water consumption of the main bioenergy crops on the drained organogenic soils of the Forest Steppe of Ukraine in modern conditions of climate change. Methods. Experimental on the basis of lysimeter studies and comparative-analytical, carried out on experimental sites of reclamation systems, mathematical modeling and processing of experimental data. The results. It was found that the maximum water consumption characteristic of the tristem willow in August is 8.02 thousand m3/ha, and this fact confirms the significant drying effect of tree crops. The lowest water consumption during the period of active vegetation was recorded in giant miscanthus — 2.53 thousand m3/ha. The total water consumption of Jerusalem artichoke from May to October was 18,100 m3/ha, corn — 12, sorghum — 10,800 m3/ha. It was found that lowering the groundwater level from 80 to 100 cm had little effect on the water consumption of Jerusalem artichoke, willow and miscanthus. The difference for these cultures does not exceed 1–3%. However, corn water consumption decreased by 112 L/kg dry matter, or 17%, and sorghum water consumption decreased by 205 L/kg, or 30% overall. In case of creation of large-scale bioenergy plantations, the area of which is measured in hundreds of hectares, it is necessary to modernize and repair the drying and humidification system. Conclusions. Climatic changes had a positive effect on the productivity of corn and sweet sorghum, the yield of dry biomass of which increased by 0.8 and 3.4 t/ha on average over three years, respectively, and negatively on the productivity of willow, it fell by 1.4 t/ha ; the productivity of miscanthus and Jerusalem artichoke did not change significantly. Therefore, when growing large plantations of energy crops, it is necessary to take into account the water regime of the land used: in fields with limited water resources, grow such annual crops as sorghum and corn, on lands with sufficient moisture — miscanthus, Jerusalem artichoke, in overmoistened places — willow plantations.