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2. Carbon and Nitrogen Mineralization of Common Organic Amendments in Olive Grove Soils.

Author

Domouso, Pablo, Pareja-Sánchez, Evangelina, Calero, Julio, and García-Ruiz, Roberto

Subjects
SOIL amendments, CARBON sequestration, COVER crops, SOIL quality, MINERALIZATION
Abstract

Cover crops (CC), pruning residues (PR), and olive mill pomace (OP) are common amendments to enhance soil quality in olive groves; however, there is limited information on the dynamics of carbon (C) and nitrogen (N) during their decomposition under varying conditions. In this laboratory decomposition experiment, we assessed the C and N mineralization of CC, PR, and OP at application rates of 2 and 5 mg C g−1 in soils with varying organic C levels, both with and without the addition of NO3. The results indicated that C and N mineralization patterns varied significantly between amendments, although the predicted remaining C after one year was similar for CC and PR (46.7–48.9%) and slightly lower for OP (40.0%). Soil organic carbon level did not affect remaining amendment-C. The addition of N accelerated the decomposition rate of labile C by 15% but slowed down that of the recalcitrant C another 13%, with no significant effect on remaining C. Conversely, increasing the C dose led to a 13% overall reduction in amendment-C mineralization across all combinations of factors. CC decomposition released between −8 and 31% of the amendment-N by day 130, while PR and OP showed net N immobilization. Therefore, CC residues contribute to both C sequestration and N availability, while PR and OP residues can improve N retention in the olive groves while also contributing to C sequestration. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Conservation Practices Boost Soil-Protected Organic Carbon Stocks in Olive Orchards.

Author

Pareja-Sánchez, Evangelina, Domouso, Pablo, Gómez-Muñoz, Beatriz, Heras-Linares, María T., and García-Ruíz, Roberto

Subjects
CARBON sequestration, AGRICULTURE, CARBON in soils, OLIVE, ORCHARDS, COVER crops
Abstract

Carbon farming practices are pivotal for enhancing soil organic carbon (SOC) storage in agricultural systems. This study focuses on evaluating the effects of spontaneous cover crops as a conservation strategy compared to conventional management practices on total, non-protected, and protected SOC fractions, as well as carbon saturation, in olive groves across 13 paired sites (26 sites in total) in Andalucía, Spain. The research evaluates organic carbon concentrations in different soil fractions: non-protected (250–2000 µm), physically protected (53–250 µm), and chemically protected (<53 µm). The results reveal that olive groves managed with temporary spontaneous cover crops (CC) over the last 8–12 years generally exhibit higher SOC concentrations compared to those managed conventionally (BS), with significant differences observed across multiple sites. CC sites exhibited higher carbon stocks, with protected carbon averaging 42.6 Mg C ha−1 compared to 29.7 Mg C ha−1 in BS, and non-protected carbon at 10.3 Mg C ha−1 versus 4.8 Mg C ha−1. A direct relationship was identified between total SOC and both protected and non-protected carbon fractions, indicating that the soil of the studies olive orchards is far from being saturated in protected SOC. Moreover, the soil of the CC olive farms had a lower carbon saturation deficit (45.3%) compared to BS (67.2%). The findings show that maintaining the cover crops in olive orchards significantly contributed to carbon sequestration and reduced carbon saturation deficits by increasing the stocks of protected SOC. [ABSTRACT FROM AUTHOR]

Published
2024
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11. No-tillage reduces long-term yield-scaled soil nitrous oxide emissions in rainfed Mediterranean agroecosystems: A field and modelling approach

Author

Comisión Interministerial de Ciencia y Tecnología, CICYT (España), Ministerio de Economía y Competitividad (España), Plaza-Bonilla, Daniel [0000-0003-4998-8585], Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Pareja-Sánchez, Evangelina [0000-0002-2702-100X], Justes, Eric [0000-0001-7390-7058], Cantero-Martínez, Carlos [0000-0002-6984-2025], Plaza-Bonilla, Daniel, Álvaro-Fuentes, Jorge, Bareche, Javier, Pareja-Sánchez, Evangelina, Justes, Éric, Cantero-Martínez, Carlos, Comisión Interministerial de Ciencia y Tecnología, CICYT (España), Ministerio de Economía y Competitividad (España), Plaza-Bonilla, Daniel [0000-0003-4998-8585], Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Pareja-Sánchez, Evangelina [0000-0002-2702-100X], Justes, Eric [0000-0001-7390-7058], Cantero-Martínez, Carlos [0000-0002-6984-2025], Plaza-Bonilla, Daniel, Álvaro-Fuentes, Jorge, Bareche, Javier, Pareja-Sánchez, Evangelina, Justes, Éric, and Cantero-Martínez, Carlos

Abstract

There is a strong need to identify agricultural management practices that maintain agronomic productivity while diminishing soil N2O emissions. The yield-scaled N2O emissions (YSNE) indicator can help to evaluate the adequacy of a given agricultural practice under both aspects. Long-term (18-yr) soil water and mineral N dynamics, crop biomass and yields, and 2011–2012 soil N2O emissions and ancillary variables were measured on barley (Hordeum vulgare L.) production in a tillage (conventional tillage, CT; no-tillage, NT) and N rate (0, 60 and 120 kg N ha−1) combination under rainfed Mediterranean conditions (NE Spain). Once evaluated, the STICS soil-crop model was used to simulate the 18-yr soil N2O emissions of each tillage system under increasing N rates (0, 30, 60, 90 and 120 kg N ha−1) in order to identify optimum management to reduce YSNE, being initialized with observed data. Cropping season precipitation was highly variable during the experiment, being a key regulating mechanism for crop yields and simulated soil N2O emissions. Crop yield under NT with N outperformed CT in 11 years. STICS performed reasonably well when simulating cumulative N2O emissions and ancillary variables with model efficiencies greater than 0.5. The 18-yr average simulated cumulative N2O emissions were 0.50, 0.82 and 1.09 kg N2O-N ha−1 yr−1 for CT-0, CT-60 and CT-120, respectively, and they were 0.53, 0.92 and 1.19 kg N2O-N ha−1 yr−1 for their counterparts under NT. These averages mask a large variability between years, according to precipitation. The 18-yr mean yield-scaled N2O emissions were 2.8–3.3 times lower under NT, compared to the corresponding CT treatments. Under CT, N application would increase YSNE in most years while YSNE would be more resilient to the application of increasing N rates under NT. Our work demonstrates that in rainfed Mediterranean systems NT is a win-win strategy for the equilibrium between agricultural productivity and low soil N2O emissions.

Published
2018

13. Monoterpene emission of Quercus suber L. highly infested by Cerambyx welensii Küster

Author

Sánchez-Osorio, Israel, López-Pantoja, Gloria, Tapias, Raúl, Pareja-Sánchez, Evangelina, and Nevado, Luis

Subjects
0106 biological sciences, [SDV]Life Sciences [q-bio], Monoterpene, Quercus decline, Sabinene, Quercus suber, 010603 evolutionary biology, 01 natural sciences, Intraspecific competition, chemistry.chemical_compound, Pinene-type, Dehesa, parasitic diseases, Dominance (ecology), Limonene, Ecology, biology, Host (biology), Forestry, biology.organism_classification, Horticulture, chemistry, Woodborer, Myrcene, 010606 plant biology & botany
Abstract

Cork oaks highly infested by Cerambyx welensii emit an amount of limonene at dusk, when C. welensii adults become active. In contrast, emissions by neighboring cork oaks free of C. welensii are dominated by pinene-type compounds. The activity of the woodborer Cerambyx welensii Kuster is a key factor in the decline of Quercus suber L. dehesas. This study aimed to estimate whether trees highly infested by C. welensii exhibited a peculiar emission profile, with known antennally active compounds. Monoterpenes were sampled in situ in 2006 (day/late evening) and 2008 (early evening) from Q. suber stratified by whether or not trees were highly infested by C. welensii and analyzed by gas chromatography. Limonene, α-pinene, β-pinene, sabinene, and myrcene accounted for over 87.2% of overall monoterpene emissions. Monoterpene composition and emission rates differed between the two groups, both during daytime and early evening, with a high presence of limonene in infested trees and dominance of pinene-type compounds in non-infested trees. This work evidenced differences in foliar monoterpene emissions between Q. suber trees highly infested by C. welensii and non-infested trees, with a high presence of limonene in the former and dominance of pinene-type compounds in non-infested trees. We hypothesize that the detection—especially during the onset of insects daily flight—of certain compounds (e.g., limonene), together with the detection of specific ratios of several monoterpenes (e.g., those of limonene to pinene-type compounds), has a role in the intraspecific host selection by C. welensii.

Published
2019
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14. Soil organic carbon sequestration when converting a rainfed cropping system to irrigated corn under different tillage systems and N fertilizer rates

Author

Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Pareja-Sánchez, Evangelina, Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, Plaza-Bonilla, Daniel, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Pareja-Sánchez, Evangelina, Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, and Plaza-Bonilla, Daniel

Abstract

The aim of this study was to evaluate the impact of 21 years of tillage and N fertilization and the conversion from a rainfed to an irrigated cropping system on soil organic C (SOC). The study was carried out in northeastern Spain in a long‐term tillage and N rate field experiment established in 1996 under barley rainfed conditions, which in 2015 was converted into irrigation with corn. Three types of tillage (conventional tillage, CT; reduced tillage, RT; no‐tillage, NT) and three mineral N fertilization rates (0, 60, and 120 kg N ha−1 under barley, and 0, 200, and 400 kg N ha−1 under corn) were compared. Annual C‐inputs as aboveground crop residues and annual SOC sequestration rate (∆SOCrate) (0–40 cm depth) were calculated in three different periods (P1, P2 and P3) under rainfed (‐R) and irrigated (‐I) conditions (P1‐R, from 1996 to 2009; P2‐R, from 2009 to 2015; P3‐I, from 2015 to 2017). At the end of P3‐I, particulate organic C (POC) was measured from the 0–5, 5–10, 10–20, 20–30, and 30–40 cm depths. Averaged over all treatments, ∆SOCrate was 492, 222, and 969 kg C ha−1 yr−1 for P1‐R, P2‐R, and P3‐I, respectively. In P1‐R and P3‐I, C‐input explained 70% of the variability of ∆SOCrate. In P1‐R, ∆SOCrate followed the order NT > RT > CT, while for N rate, order was high > medium > 0. In P3‐I at the highest N rate, ∆SOCrate followed the order NT > RT > CT. In P2‐R, ∆SOCrate did not show differences between tillage and/or N rate treatments. The increase in SOC after conversion from a rainfed to an irrigation system was mainly explained by POC, which was increased by 75% compared to the previous rainfed period. The modification of the cropping system through the introduction of irrigation and adequate crop management practices under no‐tillage and adjusted N fertilizer rates can contribute to the sequestration of large amounts of atmospheric CO2.

Published
2020

15. Impact of tillage and N fertilization rate on soil N2O emissions in irrigated maize in a Mediterranean agroecosystem

Author

Ministerio de Economía y Competitividad (España), Cantero-Martínez, Carlos [0000-0002-6984-2025], Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Pareja-Sánchez, Evangelina, Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, Plaza-Bonilla, Daniel, Ministerio de Economía y Competitividad (España), Cantero-Martínez, Carlos [0000-0002-6984-2025], Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Pareja-Sánchez, Evangelina, Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, and Plaza-Bonilla, Daniel

Abstract

In irrigated Mediterranean conditions there is a lack of knowledge about the best combination of tillage and N fertilization practices to reduce soil nitrous oxide (N2O) emissions while maintaining maize productivity. The aim of this work was to investigate the effects of different soil management practices and synthetic N fertilization rates on soil N2O emissions and their relationship with maize grain yield to determine the best management system to reduce yield-scaled N2O emissions (YSNE) in a semiarid area recently converted to irrigation under Mediterranean conditions. A long-term tillage and N rate field experiment established in 1996 under barley (Hordeum vulgare L.) rainfed conditions, was converted to irrigated maize (Zea mays L.) in 2015. After the transformation to irrigation, the field experiment maintained the same tillage treatments and N fertilization rates. Three types of tillage (conventional tillage, CT; reduced tillage, RT; no-tillage, NT) and three mineral N fertilization rates (0, 200, 400 kg N ha−1) were compared during three years (2015–2017) in a randomized block design with three replications. Soil N2O emissions, water-filled pore space, soil temperature, mineral N content (as NH4+ and NO3−), denitrification potential and maize grain yield and above-ground N uptake were quantified. Moreover, the emission factor (EF) and YSNE were calculated. The results showed that the combination of NT and the highest rate of N fertilization led to greater N2O emissions. Furthermore, the lowest N2O fluxes were observed in CT when WFPS was below 40% and the highest N2O fluxes were seen in NT when WFPS was above 60% coinciding with the greatest denitrification potential. Cumulative N2O emissions in 2017 and 2015 followed the order 400 > 200 > 0 kg N ha−1, while in 2016, rate of 400 and 200 kg N ha−1 showed greater cumulative N2O emission compared to the control. Only RT showed differences between growing seasons on cumulative N2O emissions, with greater value

Published
2020

16. Sustainable wheat production in mediterranean areas: considering crop diversification as new strategy

Author

Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, Lampurlanés Castel, Jorge, Arrúe Ugarte, José Luis, Pareja-Sánchez, Evangelina, Franco-Luesma, Samuel, Plaza-Bonilla, Daniel, Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Arrúe Ugarte, José Luis [0000-0002-5855-9240], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Álvaro-Fuentes, Jorge, Arrúe Ugarte, José Luis, and Plaza-Bonilla, Daniel

Abstract

1 Pag., The work shows, through results from different long-term experiments and some insights on crop rotation performance in commercial farms, how the adoption of conservation tillage, rational use of N fertilizers, sowing date delay and crop diversification, as integrated cropping system approach, can make wheat-based production systems more sustainable under Mediterranean conditions.

Published
2019

17. The role of sustainable agricultural practices to mitigate greenhouse gases and to sequester soil carbon under newly irrigated Mediterranean agroecosystems

Author

Pareja Sánchez, Evangelina, Cantero Martínez, Carlos, Plaza Bonilla, Daniel, and Universitat de Lleida. Departament de Producció Vegetal i Ciència Forestal

Subjects
Gasos d'efecte hivernacle, Fertilització N, Fertilización N, Sistemas de laboreo, Gases de efecto invernadero, N fertilization, Producció Vegetal, Sistemes de conreu, Greenhouse gases emissions, Tillage systems
Abstract

Les àrees del secà mediterrànies es transformen en regadiu per estabilitzar o millorar el rendiment dels cultius. L’ocupació gradual del riego ha permès augmentar l’ús del nitrogen i la intensitat del laboreo. Per tant, l'objectiu principal d'aquest estudi va ser la d’evaluar els efectes dels diferents sistemes de conreu i les dosis de fertilitzants de N en les emissions de GEH (metà, CH4; diòxid de carboni, CO2, òxid nitrós, N2O) a l'atmosfera, així com, el segrest de C del sòl, l'estructura de la superfície del sòl i la productivitat del cultiu en una àrea recentment transformada a regadiu. Per aconseguir aquest objectiu, es va dur a terme un estudi en NE Espanya en un experiment de llarga durada (LTE) de conreu i dosis de fertilització N establert el 1996 sota la producció d'ordi (Hordeum vulgare L.) en secà, posteriorment, es transformar en monocultiu blat de moro (Zea mays L.) amb reg per aspersió en 2015. Aquest estudi es va realitzar durant tres campanyes consecutives de cultiu de blat de moro (és a dir, els anys 2015, 2016 i 2017). Es van comparar tres tipus de conreu (conreu convencional, CT, conreu reduït, RT, No conreu, NT) i tres dosis de fertilització mineral N (0, 200, 400 kg N ha-1) en un disseny de blocs a l'atzar amb tres repeticions. El 2015, es va crear un experiment adjacent (experiment a curt termini, STE) amb el mateix disseny que el LTE però amb una gestió anterior diferent basada en NT. En el LTE, les emissions de CO2, CH4 i N2O del sòl es van quantificar durant tres anys. A més, es va calcular el factor d'emissió de N2O (EF) i les emissions de N2O a escala de rendiment. També, es va calcular la taxa anual del segrest de SOC (ΔSOCrate) (0-40 cm de profunditat) per a cada tractament en tres períodes diferents (P1-, P2-, P3-) en condicions de secà (-R) i condicions de regadiu (-I) (P1-R, de 1996 a 2009; P2-R, de 2009 al 2015; P3-I, de 2015 a 2017). A més, en LTE i STE superfície del sòl (0-5 cm) es van mesurar macroagregats secs i estables en l’aigua i la seva concentració de C, així com altres fraccions del sòl (concentració total de SOC i concentració de C làbil). Així mateix, es va analitzar la resistència a la penetració en la superfície del sòl (PR) i la infiltració d'aigua durant la segona temporada de cultiu de blat de moro (és a dir, l'any 2016). Ingualment, en els dos camps experimentals, es va mesurar anualment la biomassa aèria, el rendiment de gra, els components de rendiment i l'eficiència d'ús d'aigua i nitrogen (WUE i NUE, respectivament). En els agroecosistemes Mediterranis recentment transformats a regadiu, una reducció de la dosi de fertilització N juntament amb una reducció en el conreu, és una estratègia òptima en termes de manteniment de la productivitat dels cultius. A més, la reducció del conreu millora l'estat estructural del sòl, per tal de proporcionar al sòl suficient resistència i assegurar un desenvolupament òptim dels cultius. Si bé la reducció del conreu genera més emissions de GEH del sòl a l'atmosfera, aquestes es compensen amb un major rendiment de blat de moro i segrest de SOC. Las áreas de secano Mediterráneas se transforman en regadio para estabilizar o aumentar el rendimiento de los cultivos. La ocupación gradual del riego lleva a un aumento en el uso de nitrógeno y la intensidad del laboreo. Por lo tanto, el objetivo principal de este estudio fue la evaluar los efectos de los diferentes sistemas de laboreo y las dosis de fertilizantes de N en las emisiones de GEI (metano, CH4; dióxido de carbono, CO2, óxido nitroso, N2O) a la atmósfera, así como, el secuestro de C del suelo, la estructura de la superficie del suelo y la productividad del cultivo en un área recientemente transformada a regadío. Para lograr ese objetivo, se llevó a cabo un estudio en NE España en un experimento de larga duración (LTE) de laboreo y dosis de fertilización N establecido en 1996 bajo la producción de cebada (Hordeum vulgare L.) en secano, posteriormente, se transformó en monocultivo maíz (Zea mays L.) con riego por aspersión en 2015. Este estudio se realizó durante tres campañas consecutivas de cultivo de maíz (es decir, los años 2015, 2016 y 2017). Se compararon tres tipos de laboreo (laboreo convencional, CT, laboreo reducido, RT, No laboreo, NT) y tres dosis de fertilización mineral N (0, 200, 400 kg N ha-1) en un diseño de bloques al azar con tres repeticiones. En 2015, se creó un experimento adyacente (experimento a corto plazo, STE) con el mismo diseño que el LTE pero con una gestión anterior diferente basada en NT. En el LTE, las emisiones de CO2, CH4 y N2O del suelo se cuantificaron durante tres años. Además, se calculó el factor de emisión de N2O (EF) y las emisiones de N2O a escala de rendimiento. También, se calculó la tasa anual de secuestro de SOC (∆SOCrate) (0-40 cm de profundidad) para cada tratamiento en tres periodos diferentes (P1-, P2-, P3-) en condiciones de secano (-R) y condiciones de regadio (-I) (P1-R, de 1996 a 2009; P2-R, de 2009 a 2015; P3-I, de 2015 a 2017). Además, en LTE y STE superficie del suelo (0-5 cm) se midieron macroagregados secos y estables en agua y su concentración de C, así como otras fracciones del suelo (concentración total de SOC y concentración de C lábil). Asimismo, se analizaron la resistencia a la penetración en la superficie del suelo (PR) y la infiltración de agua durante la segunda temporada de cultivo de maíz (es decir, el año 2016). Ingualmente, en ambos campos experimentales, se midió anualmente la biomasa aerea, el rendimiento de grano, los componentes de rendimiento y la eficiencia de uso de agua y nitrógeno (WUE y NUE, respectivamente). En los agroecosistemas Mediterráneos recientemente transformados a regadio, una reducción de la dosis de fertilización N junto con una reducción en el laboreo, es una estrategia óptima en términos de mantenimiento de la productividad de los cultivos. Además, la disminución del laboreo mejora el estado estructural del suelo, a fin de proporcionar al suelo suficiente resistencia y asegurar un desarrollo óptimo de los cultivos. Si bien la reducción del laboreo genera mayores emisiones de GEI del suelo a la atmósfera, estas se compensan con un mayor rendimiento de maíz y secuestro de SOC. Mediterranean rainfed areas are transformed into irrigation to stabilize or increase crop yields. The gradual occupation of irrigation leads to an increase in nitrogen use and intensity of tillage. Therefore, the main objective of this study was the identification of the effect of different tillage systems and N fertilizer rates on GHG emissions (methane, CH4; carbon dioxide, CO2; nitrous oxide, N2O) to the atmosphere, as well as, soil C sequestration, soil surface structure and crop productivity when converting rainfed lands to irrigated. In order to achieve that objective a study was carried out in NE Spain in a long-term (LTE) tillage and N rate field experiment established in 1996 under rainfed barley (Hordeum vulgare L.) conditions which was converted to irrigation with maize (Zea mays L.) monoculture as cropping system in 2015. This study was conducted during three consecutive maize growing seasons (i.e. years 2015, 2016, and 2017). Three types of tillage (conventional tillage, CT; reduced tillage, RT; no-tillage, NT) and three mineral N fertilization rates (0, 200, 400 kg N ha-1) were compared in a randomized block design with three replications. In 2015, an adjacent experiment (short-term experiment, STE) with the same layout as the LTE but with different previous management based on NT was set up. In the LTE, soil CO2, CH4 and N2O emissions were quantified during three years. Also, N2O emission factor (EF) and yield-scaled N2O emissions were determined. In addition, annual SOC sequestration rate (∆SOCrate) (0-40 cm depth) was calculated for each treatment in three different periods (P1-, P2-, P3-) under rainfed (-R) conditions and irrigated (-I) conditions (P1-R, from 1996 to 2009; P2-R, 2009 to 2015; P3-I, from 2015 to 2017). Moreover, in LTE and STE soil surface (0-5 cm) dry and water-stable macroaggregates and their C concentration, as well as other soil fractions (total SOC concentration and labile C concentration) were measured. Also soil surface penetration resistance (PR), and water infiltration were analyzed during the second maize growing season (i.e. year 2016). In addition, in both experimental fields, above ground biomass, maize grain yield, yield components and water and nitrogen use efficiency (WUE and NUE, respectively) were measured annually. In Mediterranean agroecosystems recently transformed to irrigated land, a reduction in N fertilization rate together with a reduction in tillage are optimum strategies in terms of maintenance of crop productivity. In addition, reductions of tillage improve the structural state of the soil, in order to provide the soil enough resilience and ensure an optimum development of crops. Although the reduction of tillage generates higher GHG emissions from the soil to the atmosphere, this is compensated by a greater maize yield and SOC sequestration.

Published
2019

20. Sustainable wheat production in mediterranean areas: considering crop diversification as new strategy

Author

Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Arrúe Ugarte, José Luis [0000-0002-5855-9240], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, Lampurlanés Castel, Jorge, Arrúe Ugarte, José Luis, Pareja-Sánchez, Evangelina, Franco-Luesma, Samuel, Plaza-Bonilla, Daniel, Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Arrúe Ugarte, José Luis [0000-0002-5855-9240], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, Lampurlanés Castel, Jorge, Arrúe Ugarte, José Luis, Pareja-Sánchez, Evangelina, Franco-Luesma, Samuel, and Plaza-Bonilla, Daniel

Abstract

The work shows, through results from different long-term experiments and some insights on crop rotation performance in commercial farms, how the adoption of conservation tillage, rational use of N fertilizers, sowing date delay and crop diversification, as integrated cropping system approach, can make wheat-based production systems more sustainable under Mediterranean conditions.

Published
2019

21. Is it feasible to reduce tillage and N use while improving maize yield in irrigated Mediterranean agroecosystems?

Author

Ministerio de Economía y Competitividad (España), Plaza-Bonilla, Daniel [0000-0003-4998-8585], Álvaro-Fuentes, Jorge [0000-0003-2902-5204], Cantero-Martínez, Carlos [0000-0002-6984-2025], Pareja-Sánchez, Evangelina, Plaza-Bonilla, Daniel, Álvaro-Fuentes, Jorge, Cantero-Martínez, Carlos, Ministerio de Economía y Competitividad (España), Plaza-Bonilla, Daniel [0000-0003-4998-8585], Álvaro-Fuentes, Jorge [0000-0003-2902-5204], Cantero-Martínez, Carlos [0000-0002-6984-2025], Pareja-Sánchez, Evangelina, Plaza-Bonilla, Daniel, Álvaro-Fuentes, Jorge, and Cantero-Martínez, Carlos

Abstract

Mediterranean rainfed areas are transformed into irrigation to stabilize or increase crop yields. The gradual occupation of irrigation leads to an increase in nitrogen use and intensity of tillage. The aim of this work was to evaluate the combined impact of tillage systems and mineral N fertilization rates on maize grain yield, water and nitrogen use efficiencies (WUE and NUE) under Mediterranean irrigated conditions. The study was carried out in NE Spain during three maize growing seasons (i.e. years 2015, 2016 and 2017). A long-term (LTE) tillage and N rate field experiment established in 1996 under rainfed conditions was transformed into irrigation with maize (Zea mays L.) monocrop as cropping system in 2015. Three types of tillage (conventional tillage, CT; reduced tillage, RT; no-tillage, NT) and three mineral N fertilization rates (0, 200, 400 kg N ha−1) were compared. In 2015, an adjacent experiment (short-term experiment, STE) with the same layout was set up in an area previously managed under long-term rainfed NT for the last 21 years. In the long-term tillage and N fertilization combination (LTE), the reduction of tillage (NT and RT) led to greater grain yield when applying 200 and 400 kg N ha−1 compared to the use of the same rates under CT. Differently, in the sort-term experiment with preceding NT (STE), tillage systems did not influence grain yields, while N application led to greater yields than the control (0 kg N ha−1). In both situations (LTE and STE), NT and RT enhanced soil water content before planting leading to greater crop growth compared to CT. The lack of available water under CT caused lower maize stover, yield, and yield components in LTE and, therefore, lower WUEB (for biomass) and WUEY (for yield). In LTE, the use of long-term CT led to a significant accumulation of nitrate compared to NT. Differently, in the STE, soil nitrate content did not show differences between tillage systems. In the LTE, water and N were used more efficiently to

Published
2019

22. Tillage and nitrogen fertilization in irrigated maize: key practices to reduce soil CO2 and CH4 emissions

Author

Ministerio de Economía y Competitividad (España), Cantero-Martínez, Carlos [0000-0002-6984-2025], Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Pareja-Sánchez, Evangelina, Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, Plaza-Bonilla, Daniel, Ministerio de Economía y Competitividad (España), Cantero-Martínez, Carlos [0000-0002-6984-2025], Álvaro-Fuentes, Jorge [0000-0002-0192-7954], Plaza-Bonilla, Daniel [0000-0003-4998-8585], Pareja-Sánchez, Evangelina, Cantero-Martínez, Carlos, Álvaro-Fuentes, Jorge, and Plaza-Bonilla, Daniel

Abstract

In newly irrigated Mediterranean agroecosystems, the combined effect of tillage and N fertilization on soil carbon dioxide (CO2) and methane (CH4) fluxes is at present poorly understood. The goal of this study was to quantify both soil CO2 and CH4 emissions as well as crop performance under different tillage systems and N fertilization rates during three maize (Zea mays L.) growing seasons (2015–2017) in a semiarid area converted to irrigated. Three types of tillage (conventional tillage, CT, reduced tillage, RT, and no-tillage, NT) and three mineral N fertilization rates (0, 200, and 400 kg N ha−1) were compared in a randomized block design with three replications. Weekly soil CO2 and CH4 emissions, soil temperature and gravimetric moisture were measured. Moreover, maize above-ground biomass, grain yield, and above-ground C-inputs were quantified. Carbon dioxide emissions ranged from 173 to 4378 mg CO2-C m-2 d-1. No-tillage showed a greater mean soil CO2 flux than CT when applying the highest rate of N (400 kg N ha-1). Although some emissions of CH4 were observed, all treatments acted as net CH4 sinks during most of the experimental period. A linear multiple relationship between soil CO2 fluxes and soil gravimetric moisture (0–5 cm depth) and temperature (10 cm depth) were found. In the 2015 growing season, greater cumulative CO2 emissions were found under NT and RT compared with CT, while in 2016 N T showed the highest values compared to CT with intermediate values in RT. Differently, in 2017 no differences between tillage systems were found. When applying N fertilizer, NT and RT increased maize grain production and above-ground C-inputs compared to CT, since a severe soil crusting occurred in this last, which caused crop water deficit. The results suggest that tillage intensity and N fertilization rate reduction can increase maize biomass production and yield which leads to greater C-input that returns to the soil.

Published
2019

23. Long-term no-till as a means to maintain soil surface structure in an agroecosystem transformed into irrigation

Author

Ministerio de Economía y Competitividad (España), Pareja-Sánchez, Evangelina, Plaza-Bonilla, Daniel, Ramos, María Concepción, Lampurlanés Castel, Jorge, Álvaro-Fuentes, Jorge, Cantero-Martínez, Carlos, Ministerio de Economía y Competitividad (España), Pareja-Sánchez, Evangelina, Plaza-Bonilla, Daniel, Ramos, María Concepción, Lampurlanés Castel, Jorge, Álvaro-Fuentes, Jorge, and Cantero-Martínez, Carlos

Abstract

The aim of this study was to determine the most appropriate soil management to reduce the structural degradation of soils susceptible to crusting in Mediterranean areas recently transformed into irrigation. A long-term field experiment (LTE) under rainfed conditions was established in 1996 in NE Spain to compare three tillage systems (no-tillage, NT; reduced tillage, RT; conventional tillage, CT). The experiment was transformed to irrigated corn in 2015. In 2015, an adjacent experiment with the same layout was created (short-term experiment, STE) in an area previously managed under long-term NT. The study was carried out during the second corn growing season (i.e. year 2016). Soil samples were collected from 0 to 5 cm depth at different dates during corn season. Dry and water-stable macroaggregates and their C concentration, soil organic carbon (SOC) and labile C concentration, soil respiration, bulk density, penetration resistance (PR), water infiltration, macroporosity, microporosity, amount of crop residues and ground cover, corn development, aerial biomass, and grain yield were measured. In LTE and STE tillage led to a breakdown of dry sieved aggregates (of 2–4 and 4–8 mm size) in RT and CT, being slowly reconsolidated throughout the corn growing season. However, macroaggregate water-stability did not increase in CT and RT compared to NT due to a lower SOC concentration, making the soil more susceptible to its degradation by the action of water. SOC differences between treatments were more pronounced in LTE than STE given the long-term differential management in the first, which allowed greater accumulation of SOC under NT. In LTE, PR between corn rows was greater under NT than CT and RT and non-significantly different between treatments within the row. In the case of STE, PR increased over time after tillage (CT and RT) to match NT in the last sampling. Crop establishment was slower in CT than NT in LTE highlighting the impact of soil surface degradation on cro

Published
2017

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