Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia

Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd. Ausführliche Beschreibung

Gespeichert in:

Autor*in:	Mekonnen, Mulatie [verfasserIn] Keesstra, Saskia D Baartman, Jantiene E. M Stroosnijder, Leo Maroulis, Jerry

Format:	Artikel
Sprache:	Englisch

Erschienen:	2017

Rechteinformationen:	Nutzungsrecht: Copyright © 2016 John Wiley & Sons, Ltd. © Wageningen University & Research

Schlagwörter:	soil and water conservation structures Koga reservoir floodplain sediment trapping efficacy wetland waterway

Übergeordnetes Werk:	Enthalten in: Land degradation & development - Chichester, Sussex : Wiley, 1996, 28(2017), 2, Seite 708-717
Übergeordnetes Werk:	volume:28 ; year:2017 ; number:2 ; pages:708-717

Links:	Volltext Link aufrufen Link aufrufen Link aufrufen

DOI / URN:	10.1002/ldr.2629

Katalog-ID:	OLC1991165609

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520			\|a Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd.
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allfields	10.1002/ldr.2629 doi PQ20170301 (DE-627)OLC1991165609 (DE-599)GBVOLC1991165609 (PRQ)p1419-af40034f5031ef7102fea0b4087898d15564364796e21ca7210576074a03a83d3 (KEY)0175141720170000028000200708reducingsedimentconnectivitythroughmanmadeandnatur DE-627 ger DE-627 rakwb eng 630 ZDB Mekonnen, Mulatie verfasserin aut Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd. Nutzungsrecht: Copyright © 2016 John Wiley & Sons, Ltd. © Wageningen University & Research soil and water conservation structures Koga reservoir floodplain sediment trapping efficacy wetland waterway Keesstra, Saskia D oth Baartman, Jantiene E. M oth Stroosnijder, Leo oth Maroulis, Jerry oth Enthalten in Land degradation & development Chichester, Sussex : Wiley, 1996 28(2017), 2, Seite 708-717 (DE-627)211582530 (DE-600)1319202-4 (DE-576)9211582539 1085-3278 nnns volume:28 year:2017 number:2 pages:708-717 http://dx.doi.org/10.1002/ldr.2629 Volltext http://onlinelibrary.wiley.com/doi/10.1002/ldr.2629/abstract http://search.proquest.com/docview/1865956972 http://www.narcis.nl/publication/RecordID/oai:library.wur.nl:wurpubs%2F514968 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-UMW SSG-OLC-ARC SSG-OLC-TEC SSG-OLC-GEO SSG-OPC-GGO AR 28 2017 2 708-717
spelling	10.1002/ldr.2629 doi PQ20170301 (DE-627)OLC1991165609 (DE-599)GBVOLC1991165609 (PRQ)p1419-af40034f5031ef7102fea0b4087898d15564364796e21ca7210576074a03a83d3 (KEY)0175141720170000028000200708reducingsedimentconnectivitythroughmanmadeandnatur DE-627 ger DE-627 rakwb eng 630 ZDB Mekonnen, Mulatie verfasserin aut Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd. Nutzungsrecht: Copyright © 2016 John Wiley & Sons, Ltd. © Wageningen University & Research soil and water conservation structures Koga reservoir floodplain sediment trapping efficacy wetland waterway Keesstra, Saskia D oth Baartman, Jantiene E. M oth Stroosnijder, Leo oth Maroulis, Jerry oth Enthalten in Land degradation & development Chichester, Sussex : Wiley, 1996 28(2017), 2, Seite 708-717 (DE-627)211582530 (DE-600)1319202-4 (DE-576)9211582539 1085-3278 nnns volume:28 year:2017 number:2 pages:708-717 http://dx.doi.org/10.1002/ldr.2629 Volltext http://onlinelibrary.wiley.com/doi/10.1002/ldr.2629/abstract http://search.proquest.com/docview/1865956972 http://www.narcis.nl/publication/RecordID/oai:library.wur.nl:wurpubs%2F514968 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-UMW SSG-OLC-ARC SSG-OLC-TEC SSG-OLC-GEO SSG-OPC-GGO AR 28 2017 2 708-717
allfields_unstemmed	10.1002/ldr.2629 doi PQ20170301 (DE-627)OLC1991165609 (DE-599)GBVOLC1991165609 (PRQ)p1419-af40034f5031ef7102fea0b4087898d15564364796e21ca7210576074a03a83d3 (KEY)0175141720170000028000200708reducingsedimentconnectivitythroughmanmadeandnatur DE-627 ger DE-627 rakwb eng 630 ZDB Mekonnen, Mulatie verfasserin aut Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd. Nutzungsrecht: Copyright © 2016 John Wiley & Sons, Ltd. © Wageningen University & Research soil and water conservation structures Koga reservoir floodplain sediment trapping efficacy wetland waterway Keesstra, Saskia D oth Baartman, Jantiene E. M oth Stroosnijder, Leo oth Maroulis, Jerry oth Enthalten in Land degradation & development Chichester, Sussex : Wiley, 1996 28(2017), 2, Seite 708-717 (DE-627)211582530 (DE-600)1319202-4 (DE-576)9211582539 1085-3278 nnns volume:28 year:2017 number:2 pages:708-717 http://dx.doi.org/10.1002/ldr.2629 Volltext http://onlinelibrary.wiley.com/doi/10.1002/ldr.2629/abstract http://search.proquest.com/docview/1865956972 http://www.narcis.nl/publication/RecordID/oai:library.wur.nl:wurpubs%2F514968 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-UMW SSG-OLC-ARC SSG-OLC-TEC SSG-OLC-GEO SSG-OPC-GGO AR 28 2017 2 708-717
allfieldsGer	10.1002/ldr.2629 doi PQ20170301 (DE-627)OLC1991165609 (DE-599)GBVOLC1991165609 (PRQ)p1419-af40034f5031ef7102fea0b4087898d15564364796e21ca7210576074a03a83d3 (KEY)0175141720170000028000200708reducingsedimentconnectivitythroughmanmadeandnatur DE-627 ger DE-627 rakwb eng 630 ZDB Mekonnen, Mulatie verfasserin aut Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd. Nutzungsrecht: Copyright © 2016 John Wiley & Sons, Ltd. © Wageningen University & Research soil and water conservation structures Koga reservoir floodplain sediment trapping efficacy wetland waterway Keesstra, Saskia D oth Baartman, Jantiene E. M oth Stroosnijder, Leo oth Maroulis, Jerry oth Enthalten in Land degradation & development Chichester, Sussex : Wiley, 1996 28(2017), 2, Seite 708-717 (DE-627)211582530 (DE-600)1319202-4 (DE-576)9211582539 1085-3278 nnns volume:28 year:2017 number:2 pages:708-717 http://dx.doi.org/10.1002/ldr.2629 Volltext http://onlinelibrary.wiley.com/doi/10.1002/ldr.2629/abstract http://search.proquest.com/docview/1865956972 http://www.narcis.nl/publication/RecordID/oai:library.wur.nl:wurpubs%2F514968 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-UMW SSG-OLC-ARC SSG-OLC-TEC SSG-OLC-GEO SSG-OPC-GGO AR 28 2017 2 708-717
allfieldsSound	10.1002/ldr.2629 doi PQ20170301 (DE-627)OLC1991165609 (DE-599)GBVOLC1991165609 (PRQ)p1419-af40034f5031ef7102fea0b4087898d15564364796e21ca7210576074a03a83d3 (KEY)0175141720170000028000200708reducingsedimentconnectivitythroughmanmadeandnatur DE-627 ger DE-627 rakwb eng 630 ZDB Mekonnen, Mulatie verfasserin aut Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd. Nutzungsrecht: Copyright © 2016 John Wiley & Sons, Ltd. © Wageningen University & Research soil and water conservation structures Koga reservoir floodplain sediment trapping efficacy wetland waterway Keesstra, Saskia D oth Baartman, Jantiene E. M oth Stroosnijder, Leo oth Maroulis, Jerry oth Enthalten in Land degradation & development Chichester, Sussex : Wiley, 1996 28(2017), 2, Seite 708-717 (DE-627)211582530 (DE-600)1319202-4 (DE-576)9211582539 1085-3278 nnns volume:28 year:2017 number:2 pages:708-717 http://dx.doi.org/10.1002/ldr.2629 Volltext http://onlinelibrary.wiley.com/doi/10.1002/ldr.2629/abstract http://search.proquest.com/docview/1865956972 http://www.narcis.nl/publication/RecordID/oai:library.wur.nl:wurpubs%2F514968 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-UMW SSG-OLC-ARC SSG-OLC-TEC SSG-OLC-GEO SSG-OPC-GGO AR 28 2017 2 708-717
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The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. 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author	Mekonnen, Mulatie
spellingShingle	Mekonnen, Mulatie ddc 630 misc soil and water conservation structures misc Koga reservoir misc floodplain misc sediment trapping efficacy misc wetland misc waterway Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia
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topic_title	630 ZDB Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia soil and water conservation structures Koga reservoir floodplain sediment trapping efficacy wetland waterway
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title	Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia
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title_full	Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia
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title_sort	reducing sediment connectivity through man‐made and natural sediment sinks in the minizr catchment, northwest ethiopia
title_auth	Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia
abstract	Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd.
abstractGer	Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd.
abstract_unstemmed	Man‐made and natural sediment sinks provide a practical means for reducing downstream reservoir sedimentation by decreasing soil erosion and enhancing the rate of sedimentation within a catchment. The Minizr catchment (20 km 2 ) in the northwest Ethiopian highlands contains numerous man‐made soil and water conservation (SWC) structures such as soil bunds (Erken), fanya juu ridge (Cab) and micro‐trenches and natural sediment sinks such as wetlands, floodplains and grassed waterways. These sediment sinks reduce downstream sedimentation into the Koga reservoir, located at the catchment outlet, however, a large quantity of sediment is still reaching the reservoir. This study evaluates the function and effectiveness of both man‐made SWC structures and natural sediment sinks in reducing sediment export from the Minizr catchment. SWC structures and natural sediment sinks were digitized using Google Earth Imagery. Sediment pins and vertical sampling through the deposit were used to quantify the amount of deposited sediment. In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. Copyright © 2016 John Wiley & Sons, Ltd.
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title_short	Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia
url	http://dx.doi.org/10.1002/ldr.2629 http://onlinelibrary.wiley.com/doi/10.1002/ldr.2629/abstract http://search.proquest.com/docview/1865956972 http://www.narcis.nl/publication/RecordID/oai:library.wur.nl:wurpubs%2F514968
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author2	Keesstra, Saskia D Baartman, Jantiene E. M Stroosnijder, Leo Maroulis, Jerry
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In addition, inflow and outflow of suspended sediment data were used to calculate the sediment‐trapping efficacies (STE) of man‐made SWC structures (soil bunds and fanya juu ridges) and natural sediment sinks. Results reveal that 144 km soil bunds and fanya juu ridges trapped 7,920 Mg y −1 (55 kg m −1 y −1 ) and micro‐trenches trapped 13·26 Mg y −1 , each micro‐trench on average trapped 23 kg y −1 . The 17 ha floodplain located in the centre of the catchment trapped 9,970 Mg y −1 (59 kg m −2 y −1 ), while a wetland with a surface area of 24 ha, located near the outlet of the catchment, trapped 8,715 Mg y −1 (36 kg m −2 y −1 ). The STEs of soil bunds and fanya juu ridges, wetlands and floodplains were 54%, 85% and 77%, respectively. Substantial differences were observed between the STE of grassed and un‐grassed waterways at 75% and 21%, respectively. Existing man‐made and natural sediment sinks played an important role in trapping sediment, with 38% (26,600 Mg y −1 ) of transported sediment being trapped, while 62% (43,000 Mg y −1 ) is exported from the catchment and thus enters the Koga reservoir. Therefore, additional catchment treatment measures are required as an integrated catchment scale sediment trapping approach to help reduce sediment loads entering Koga reservoir. Moreover, to maximize the effectiveness of sediment trapping measures, avoid structural failure and ensure their sustainability, regular maintenance is needed. 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Reducing Sediment Connectivity Through man‐Made and Natural Sediment Sinks in the Minizr Catchment, Northwest Ethiopia

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