A. Sofo, L.S. Zurlo, Giuseppe Vitale, A. M. Palese
{"title":"地中海橄榄园20年可持续管理的碳封存","authors":"A. Sofo, L.S. Zurlo, Giuseppe Vitale, A. M. Palese","doi":"10.5194/EGUSPHERE-EGU21-1488","DOIUrl":null,"url":null,"abstract":"<p>Olive is a widespread crop within Mediterranean area and Italy is one of the biggest producer of olives and oil in the world. From an environmental point of view, centered on carbon (C) sequestration, managing olive orchards sustainably is an urgent and actual issue.</p><p>This trial was done in a 2-ha olive orchard (<em>Olea europaea</em> L., cv. ‘Maiatica’; 70-year-old plants, with a distance of 8 × 8 m and NE orientation) located in Ferrandina (Southern Italy, Basilicata region; N 40°29’; E 16°28’). The soil is a sandy loam (Haplic Calcisol - WRB), with a mean bulk density of 1.30 g cm<sup>–3</sup> and sediment as parental material. The major landform is plain, the slope form is classified as convex-straight and the gradient class as gently sloping (2-5%). Half of the orchard has been managed using sustainable agricultural practices (sustainable management, <em><sub>Sung</sub></em>) for 20 years (2000-2020). Trees were drip-irrigated from March to October with urban wastewater. A light pruning was carried out every year during winter. The soil was permanently covered by spontaneous self-seeding weeds, mowed twice a year. Cover crop residues and prunings were shredded and left along the row as mulch.</p><p>The other half of the orchard was kept as ‘control’ plot. It was rainfed and conducted with a locally conventional management (<em>C</em><sub>mng</sub>), according to the practices usually adopted by farmers. The <em>C</em><sub>mng</sub> was managed by tillage performed 2-3 times per year to control weeds. Intensive pruning was carried out every two years, but pruned residues were removed from the orchard. A mineral fertilization was carried out once per year, during the fruit set and pit hardening phase (early spring).</p><p>The average value (<em>n</em> = 5; 0-100 cm soil depth) of baseline soil organic carbon (SOC) stock (related to the <em>C</em><sub>mng</sub>) in the 20-year period was 4.79 t SOC ha<sup>–1</sup>, with an average additional SOC storage potential because of the adoption of the <em>S</em><sub>mng</sub> of 0.15 t SOC ha<sup>–1</sup> yr<sup>–1</sup>, and a SOC stock after 20 years of <em>S</em><sub>mng</sub> of 7.75 t SOC ha<sup>–1</sup> yr<sup>–1</sup>.</p><p>In the <em>S</em><sub>mng</sub> system, soil acted as a significant sink for C, especially due to the supplies of the organic resources internal to the system. The <em>S</em><sub>mng</sub> system, made up of mature olive trees, was also able to fix in its aboveground and belowground components, a > 2-times higher total amount of C than the <em>C</em><sub>mng</sub>. Spontaneous vegetation was the most important pool, sequestering about 35% of the total fixed C. Also pruning material had a substantial importance in C fixation. Emissions of CO<sub>2</sub> eq per kg of olives, calculated according to the Life Cycle Assessment (LCA), were 0.08 kg in the <em>S</em><sub>mng</sub> system and 0.11 kg in the <em>C</em><sub>mng</sub> system. Besides C sequestration, the application of the <em>S</em><sub>mng</sub> markedly improved physical, chemical, and biological soil fertility, with benefits on plants and production.</p><p>The application of a sustainable soil and plant management makes olive growing a multifunctional rural activity, not only aimed at production, but including many other objectives, such as environmental, landscaping cultural, social and recreational.</p>","PeriodicalId":22413,"journal":{"name":"The EGU General Assembly","volume":"54 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2021-03-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Carbon sequestration in a Mediterranean olive orchard managed sustainably over a 20-year period\",\"authors\":\"A. Sofo, L.S. Zurlo, Giuseppe Vitale, A. M. Palese\",\"doi\":\"10.5194/EGUSPHERE-EGU21-1488\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Olive is a widespread crop within Mediterranean area and Italy is one of the biggest producer of olives and oil in the world. From an environmental point of view, centered on carbon (C) sequestration, managing olive orchards sustainably is an urgent and actual issue.</p><p>This trial was done in a 2-ha olive orchard (<em>Olea europaea</em> L., cv. ‘Maiatica’; 70-year-old plants, with a distance of 8 × 8 m and NE orientation) located in Ferrandina (Southern Italy, Basilicata region; N 40°29’; E 16°28’). The soil is a sandy loam (Haplic Calcisol - WRB), with a mean bulk density of 1.30 g cm<sup>–3</sup> and sediment as parental material. The major landform is plain, the slope form is classified as convex-straight and the gradient class as gently sloping (2-5%). Half of the orchard has been managed using sustainable agricultural practices (sustainable management, <em><sub>Sung</sub></em>) for 20 years (2000-2020). Trees were drip-irrigated from March to October with urban wastewater. A light pruning was carried out every year during winter. The soil was permanently covered by spontaneous self-seeding weeds, mowed twice a year. Cover crop residues and prunings were shredded and left along the row as mulch.</p><p>The other half of the orchard was kept as ‘control’ plot. It was rainfed and conducted with a locally conventional management (<em>C</em><sub>mng</sub>), according to the practices usually adopted by farmers. The <em>C</em><sub>mng</sub> was managed by tillage performed 2-3 times per year to control weeds. Intensive pruning was carried out every two years, but pruned residues were removed from the orchard. A mineral fertilization was carried out once per year, during the fruit set and pit hardening phase (early spring).</p><p>The average value (<em>n</em> = 5; 0-100 cm soil depth) of baseline soil organic carbon (SOC) stock (related to the <em>C</em><sub>mng</sub>) in the 20-year period was 4.79 t SOC ha<sup>–1</sup>, with an average additional SOC storage potential because of the adoption of the <em>S</em><sub>mng</sub> of 0.15 t SOC ha<sup>–1</sup> yr<sup>–1</sup>, and a SOC stock after 20 years of <em>S</em><sub>mng</sub> of 7.75 t SOC ha<sup>–1</sup> yr<sup>–1</sup>.</p><p>In the <em>S</em><sub>mng</sub> system, soil acted as a significant sink for C, especially due to the supplies of the organic resources internal to the system. The <em>S</em><sub>mng</sub> system, made up of mature olive trees, was also able to fix in its aboveground and belowground components, a > 2-times higher total amount of C than the <em>C</em><sub>mng</sub>. Spontaneous vegetation was the most important pool, sequestering about 35% of the total fixed C. Also pruning material had a substantial importance in C fixation. Emissions of CO<sub>2</sub> eq per kg of olives, calculated according to the Life Cycle Assessment (LCA), were 0.08 kg in the <em>S</em><sub>mng</sub> system and 0.11 kg in the <em>C</em><sub>mng</sub> system. Besides C sequestration, the application of the <em>S</em><sub>mng</sub> markedly improved physical, chemical, and biological soil fertility, with benefits on plants and production.</p><p>The application of a sustainable soil and plant management makes olive growing a multifunctional rural activity, not only aimed at production, but including many other objectives, such as environmental, landscaping cultural, social and recreational.</p>\",\"PeriodicalId\":22413,\"journal\":{\"name\":\"The EGU General Assembly\",\"volume\":\"54 1\",\"pages\":\"\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2021-03-03\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"1\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"The EGU General Assembly\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.5194/EGUSPHERE-EGU21-1488\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"The EGU General Assembly","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.5194/EGUSPHERE-EGU21-1488","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
Carbon sequestration in a Mediterranean olive orchard managed sustainably over a 20-year period
Olive is a widespread crop within Mediterranean area and Italy is one of the biggest producer of olives and oil in the world. From an environmental point of view, centered on carbon (C) sequestration, managing olive orchards sustainably is an urgent and actual issue.
This trial was done in a 2-ha olive orchard (Olea europaea L., cv. ‘Maiatica’; 70-year-old plants, with a distance of 8 × 8 m and NE orientation) located in Ferrandina (Southern Italy, Basilicata region; N 40°29’; E 16°28’). The soil is a sandy loam (Haplic Calcisol - WRB), with a mean bulk density of 1.30 g cm–3 and sediment as parental material. The major landform is plain, the slope form is classified as convex-straight and the gradient class as gently sloping (2-5%). Half of the orchard has been managed using sustainable agricultural practices (sustainable management, Sung) for 20 years (2000-2020). Trees were drip-irrigated from March to October with urban wastewater. A light pruning was carried out every year during winter. The soil was permanently covered by spontaneous self-seeding weeds, mowed twice a year. Cover crop residues and prunings were shredded and left along the row as mulch.
The other half of the orchard was kept as ‘control’ plot. It was rainfed and conducted with a locally conventional management (Cmng), according to the practices usually adopted by farmers. The Cmng was managed by tillage performed 2-3 times per year to control weeds. Intensive pruning was carried out every two years, but pruned residues were removed from the orchard. A mineral fertilization was carried out once per year, during the fruit set and pit hardening phase (early spring).
The average value (n = 5; 0-100 cm soil depth) of baseline soil organic carbon (SOC) stock (related to the Cmng) in the 20-year period was 4.79 t SOC ha–1, with an average additional SOC storage potential because of the adoption of the Smng of 0.15 t SOC ha–1 yr–1, and a SOC stock after 20 years of Smng of 7.75 t SOC ha–1 yr–1.
In the Smng system, soil acted as a significant sink for C, especially due to the supplies of the organic resources internal to the system. The Smng system, made up of mature olive trees, was also able to fix in its aboveground and belowground components, a > 2-times higher total amount of C than the Cmng. Spontaneous vegetation was the most important pool, sequestering about 35% of the total fixed C. Also pruning material had a substantial importance in C fixation. Emissions of CO2 eq per kg of olives, calculated according to the Life Cycle Assessment (LCA), were 0.08 kg in the Smng system and 0.11 kg in the Cmng system. Besides C sequestration, the application of the Smng markedly improved physical, chemical, and biological soil fertility, with benefits on plants and production.
The application of a sustainable soil and plant management makes olive growing a multifunctional rural activity, not only aimed at production, but including many other objectives, such as environmental, landscaping cultural, social and recreational.
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