Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia

Background The anthropogenic global climate change has negative impacts on various sectors and communities who particularly rely on rain-fed agriculture. Parkland agroforestry practice can contribute to mitigate and adapt to the forthcoming climate change through carbon sequestration. However, empir...
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Autor*in:	Tsedeke, Reta Eshetu [verfasserIn] Dawud, Seid Muhie [verfasserIn] Tafere, Solomon Mulu [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2021

Schlagwörter:	Soil organic carbon Above-ground biomass carbon Below-ground biomass carbon

Übergeordnetes Werk:	Enthalten in: Environmental Systems Research - Berlin : SpringerOpen, 2012, 10(2021), 1 vom: 08. Jan.
Übergeordnetes Werk:	volume:10 ; year:2021 ; number:1 ; day:08 ; month:01

Links:	Volltext

DOI / URN:	10.1186/s40068-020-00211-3

Katalog-ID:	SPR04263542X

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520			\|a Background The anthropogenic global climate change has negative impacts on various sectors and communities who particularly rely on rain-fed agriculture. Parkland agroforestry practice can contribute to mitigate and adapt to the forthcoming climate change through carbon sequestration. However, empirical studies on carbon stocks potential of parklands agroforestry practices . Methodology By using two-stage stratified random sampling technique, 4 kebeles from two agro ecology were selected and 8 farms/plots/ of 40 m*40 m sample size were selected from each kebele for the vegetation inventory. Tree species-specific allometric equations were used to determine carbon stock potential of parkland agroforestry practice. Results The result reveal that, AGC, BGC, SOC and Total Carbon have significant variation (p < 0.05) across kebeles. The mean total carbon stock of Bolo Giorgis, Bolo Slase, Agirat and Korma Agere is 48.87 Mg C $ ha^{− 1} $, 58.21 Mg C $ ha^{− 1} $, 57.81 Mg C $ ha^{− 1} $and 73.71 Mg C $ ha^{− 1} $; respectively. On average, carbon stock of parklands practice in Minjar shenkora was 59.65 Mg C $ ha^{− 1} $. Conclusions The parkland agroforestry practice has a large potential to deliver regulating ecosystem services like opportunities to mitigate the impending climate-changing through carbon sequestration and increasing the resilience of the agricultural system at Minjar shenkora woreda. To enhance the multiple ecosystem services of the parkland agroforestry practices in sustainable way: local by-laws should be strengthened to avoid illegal tree cutting and free grazing.
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Parkland agroforestry practice can contribute to mitigate and adapt to the forthcoming climate change through carbon sequestration. However, empirical studies on carbon stocks potential of parklands agroforestry practices . Methodology By using two-stage stratified random sampling technique, 4 kebeles from two agro ecology were selected and 8 farms/plots/ of 40 m*40 m sample size were selected from each kebele for the vegetation inventory. Tree species-specific allometric equations were used to determine carbon stock potential of parkland agroforestry practice. Results The result reveal that, AGC, BGC, SOC and Total Carbon have significant variation (p < 0.05) across kebeles. The mean total carbon stock of Bolo Giorgis, Bolo Slase, Agirat and Korma Agere is 48.87 Mg C $ ha^{− 1} $, 58.21 Mg C $ ha^{− 1} $, 57.81 Mg C $ ha^{− 1} $and 73.71 Mg C $ ha^{− 1} $; respectively. On average, carbon stock of parklands practice in Minjar shenkora was 59.65 Mg C $ ha^{− 1} $. Conclusions The parkland agroforestry practice has a large potential to deliver regulating ecosystem services like opportunities to mitigate the impending climate-changing through carbon sequestration and increasing the resilience of the agricultural system at Minjar shenkora woreda. To enhance the multiple ecosystem services of the parkland agroforestry practices in sustainable way: local by-laws should be strengthened to avoid illegal tree cutting and free grazing.</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Soil organic carbon</subfield><subfield code="7">(dpeaa)DE-He213</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Above-ground biomass carbon</subfield><subfield code="7">(dpeaa)DE-He213</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Below-ground biomass carbon</subfield><subfield code="7">(dpeaa)DE-He213</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Dawud, Seid Muhie</subfield><subfield code="e">verfasserin</subfield><subfield code="4">aut</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Tafere, Solomon Mulu</subfield><subfield code="e">verfasserin</subfield><subfield code="4">aut</subfield></datafield><datafield tag="773" ind1="0" ind2="8"><subfield code="i">Enthalten in</subfield><subfield code="t">Environmental Systems Research</subfield><subfield code="d">Berlin : SpringerOpen, 2012</subfield><subfield code="g">10(2021), 1 vom: 08. 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author	Tsedeke, Reta Eshetu
spellingShingle	Tsedeke, Reta Eshetu ddc 333.7 misc Soil organic carbon misc Above-ground biomass carbon misc Below-ground biomass carbon Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia
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topic_title	333.7 ASE Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia Soil organic carbon (dpeaa)DE-He213 Above-ground biomass carbon (dpeaa)DE-He213 Below-ground biomass carbon (dpeaa)DE-He213
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title	Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia
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title_full	Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia
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author_browse	Tsedeke, Reta Eshetu Dawud, Seid Muhie Tafere, Solomon Mulu
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title_sort	assessment of carbon stock potential of parkland agroforestry practice: the case of minjar shenkora; north shewa, ethiopia
title_auth	Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia
abstract	Background The anthropogenic global climate change has negative impacts on various sectors and communities who particularly rely on rain-fed agriculture. Parkland agroforestry practice can contribute to mitigate and adapt to the forthcoming climate change through carbon sequestration. However, empirical studies on carbon stocks potential of parklands agroforestry practices . Methodology By using two-stage stratified random sampling technique, 4 kebeles from two agro ecology were selected and 8 farms/plots/ of 40 m*40 m sample size were selected from each kebele for the vegetation inventory. Tree species-specific allometric equations were used to determine carbon stock potential of parkland agroforestry practice. Results The result reveal that, AGC, BGC, SOC and Total Carbon have significant variation (p < 0.05) across kebeles. The mean total carbon stock of Bolo Giorgis, Bolo Slase, Agirat and Korma Agere is 48.87 Mg C $ ha^{− 1} $, 58.21 Mg C $ ha^{− 1} $, 57.81 Mg C $ ha^{− 1} $and 73.71 Mg C $ ha^{− 1} $; respectively. On average, carbon stock of parklands practice in Minjar shenkora was 59.65 Mg C $ ha^{− 1} $. Conclusions The parkland agroforestry practice has a large potential to deliver regulating ecosystem services like opportunities to mitigate the impending climate-changing through carbon sequestration and increasing the resilience of the agricultural system at Minjar shenkora woreda. To enhance the multiple ecosystem services of the parkland agroforestry practices in sustainable way: local by-laws should be strengthened to avoid illegal tree cutting and free grazing.
abstractGer	Background The anthropogenic global climate change has negative impacts on various sectors and communities who particularly rely on rain-fed agriculture. Parkland agroforestry practice can contribute to mitigate and adapt to the forthcoming climate change through carbon sequestration. However, empirical studies on carbon stocks potential of parklands agroforestry practices . Methodology By using two-stage stratified random sampling technique, 4 kebeles from two agro ecology were selected and 8 farms/plots/ of 40 m*40 m sample size were selected from each kebele for the vegetation inventory. Tree species-specific allometric equations were used to determine carbon stock potential of parkland agroforestry practice. Results The result reveal that, AGC, BGC, SOC and Total Carbon have significant variation (p < 0.05) across kebeles. The mean total carbon stock of Bolo Giorgis, Bolo Slase, Agirat and Korma Agere is 48.87 Mg C $ ha^{− 1} $, 58.21 Mg C $ ha^{− 1} $, 57.81 Mg C $ ha^{− 1} $and 73.71 Mg C $ ha^{− 1} $; respectively. On average, carbon stock of parklands practice in Minjar shenkora was 59.65 Mg C $ ha^{− 1} $. Conclusions The parkland agroforestry practice has a large potential to deliver regulating ecosystem services like opportunities to mitigate the impending climate-changing through carbon sequestration and increasing the resilience of the agricultural system at Minjar shenkora woreda. To enhance the multiple ecosystem services of the parkland agroforestry practices in sustainable way: local by-laws should be strengthened to avoid illegal tree cutting and free grazing.
abstract_unstemmed	Background The anthropogenic global climate change has negative impacts on various sectors and communities who particularly rely on rain-fed agriculture. Parkland agroforestry practice can contribute to mitigate and adapt to the forthcoming climate change through carbon sequestration. However, empirical studies on carbon stocks potential of parklands agroforestry practices . Methodology By using two-stage stratified random sampling technique, 4 kebeles from two agro ecology were selected and 8 farms/plots/ of 40 m*40 m sample size were selected from each kebele for the vegetation inventory. Tree species-specific allometric equations were used to determine carbon stock potential of parkland agroforestry practice. Results The result reveal that, AGC, BGC, SOC and Total Carbon have significant variation (p < 0.05) across kebeles. The mean total carbon stock of Bolo Giorgis, Bolo Slase, Agirat and Korma Agere is 48.87 Mg C $ ha^{− 1} $, 58.21 Mg C $ ha^{− 1} $, 57.81 Mg C $ ha^{− 1} $and 73.71 Mg C $ ha^{− 1} $; respectively. On average, carbon stock of parklands practice in Minjar shenkora was 59.65 Mg C $ ha^{− 1} $. Conclusions The parkland agroforestry practice has a large potential to deliver regulating ecosystem services like opportunities to mitigate the impending climate-changing through carbon sequestration and increasing the resilience of the agricultural system at Minjar shenkora woreda. To enhance the multiple ecosystem services of the parkland agroforestry practices in sustainable way: local by-laws should be strengthened to avoid illegal tree cutting and free grazing.
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title_short	Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia
url	https://dx.doi.org/10.1186/s40068-020-00211-3
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Parkland agroforestry practice can contribute to mitigate and adapt to the forthcoming climate change through carbon sequestration. However, empirical studies on carbon stocks potential of parklands agroforestry practices . Methodology By using two-stage stratified random sampling technique, 4 kebeles from two agro ecology were selected and 8 farms/plots/ of 40 m*40 m sample size were selected from each kebele for the vegetation inventory. Tree species-specific allometric equations were used to determine carbon stock potential of parkland agroforestry practice. Results The result reveal that, AGC, BGC, SOC and Total Carbon have significant variation (p < 0.05) across kebeles. The mean total carbon stock of Bolo Giorgis, Bolo Slase, Agirat and Korma Agere is 48.87 Mg C $ ha^{− 1} $, 58.21 Mg C $ ha^{− 1} $, 57.81 Mg C $ ha^{− 1} $and 73.71 Mg C $ ha^{− 1} $; respectively. On average, carbon stock of parklands practice in Minjar shenkora was 59.65 Mg C $ ha^{− 1} $. Conclusions The parkland agroforestry practice has a large potential to deliver regulating ecosystem services like opportunities to mitigate the impending climate-changing through carbon sequestration and increasing the resilience of the agricultural system at Minjar shenkora woreda. 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Assessment of carbon stock potential of parkland agroforestry practice: the case of Minjar Shenkora; North Shewa, Ethiopia

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