Mountain wetland soil carbon stocks of Huascarán National Park, Peru
Although wetlands contain a disproportionately high amount of earth’s total soil carbon, many regions are still poorly mapped and with unquantified carbon stocks. The tropical Andes contain a high concentration of wetlands consisting mostly of wet meadows and peatlands, yet their total organic carbo...
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| Published in | Frontiers in plant science Vol. 14; p. 1048609 |
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| Main Authors | , , , , , , |
| Format | Journal Article |
| Language | English |
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25.04.2023
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| Abstract | Although wetlands contain a disproportionately high amount of earth’s total soil carbon, many regions are still poorly mapped and with unquantified carbon stocks. The tropical Andes contain a high concentration of wetlands consisting mostly of wet meadows and peatlands, yet their total organic carbon stocks are poorly quantified, as well as the carbon fraction that wet meadows store compared to peatlands. Therefore, our goal was to quantify how soil carbon stocks vary between wet meadows and peatlands for a previously mapped Andean region, Huascarán National Park, Peru. Our secondary goal was to test a rapid peat sampling protocol to facilitate field sampling in remote areas. We sampled soil to calculate carbon stocks of four wetland types: cushion peat, graminoid peat, cushion wet meadow, and graminoid wet meadow. Soil sampling was conducted by using a stratified randomized sampling scheme. Wet meadows were sampled to the mineral boundary using a gouge auger, and we used a combination of full peat cores and a rapid peat sampling procedure to estimate peat carbon stocks. In the lab, soils were processed for bulk density and carbon content, and total carbon stock of each core was calculated. We sampled 63 wet meadows and 42 peatlands. On a per hectare basis, carbon stocks varied strongly between peatlands (avg. 1092 MgC ha
-1
) and wet meadows (avg. 30 MgC ha
-1
). Overall, wetlands in Huascarán National Park contain 24.4 Tg of carbon with peatlands storing 97% of the total wetland carbon and wet meadows accounting for 3% of the wetland carbon in the park. In addition, our results show that rapid peat sampling can be an effective method for sampling carbon stocks in peatlands. These data are important for countries developing land use and climate change policies as well as providing a rapid assessment method for wetland carbon stock monitoring programs. |
|---|---|
| AbstractList | Although wetlands contain a disproportionately high amount of earth’s total soil carbon, many regions are still poorly mapped and with unquantified carbon stocks. The tropical Andes contain a high concentration of wetlands consisting mostly of wet meadows and peatlands, yet their total organic carbon stocks are poorly quantified, as well as the carbon fraction that wet meadows store compared to peatlands. Therefore, our goal was to quantify how soil carbon stocks vary between wet meadows and peatlands for a previously mapped Andean region, Huascarán National Park, Peru. Our secondary goal was to test a rapid peat sampling protocol to facilitate field sampling in remote areas. We sampled soil to calculate carbon stocks of four wetland types: cushion peat, graminoid peat, cushion wet meadow, and graminoid wet meadow. Soil sampling was conducted by using a stratified randomized sampling scheme. Wet meadows were sampled to the mineral boundary using a gouge auger, and we used a combination of full peat cores and a rapid peat sampling procedure to estimate peat carbon stocks. In the lab, soils were processed for bulk density and carbon content, and total carbon stock of each core was calculated. We sampled 63 wet meadows and 42 peatlands. On a per hectare basis, carbon stocks varied strongly between peatlands (avg. 1092 MgC ha
-1
) and wet meadows (avg. 30 MgC ha
-1
). Overall, wetlands in Huascarán National Park contain 24.4 Tg of carbon with peatlands storing 97% of the total wetland carbon and wet meadows accounting for 3% of the wetland carbon in the park. In addition, our results show that rapid peat sampling can be an effective method for sampling carbon stocks in peatlands. These data are important for countries developing land use and climate change policies as well as providing a rapid assessment method for wetland carbon stock monitoring programs. Although wetlands contain a disproportionately high amount of earth's total soil carbon, many regions are still poorly mapped and with unquantified carbon stocks. The tropical Andes contain a high concentration of wetlands consisting mostly of wet meadows and peatlands, yet their total organic carbon stocks are poorly quantified, as well as the carbon fraction that wet meadows store compared to peatlands. Therefore, our goal was to quantify how soil carbon stocks vary between wet meadows and peatlands for a previously mapped Andean region, Huascarán National Park, Peru. Our secondary goal was to test a rapid peat sampling protocol to facilitate field sampling in remote areas. We sampled soil to calculate carbon stocks of four wetland types: cushion peat, graminoid peat, cushion wet meadow, and graminoid wet meadow. Soil sampling was conducted by using a stratified randomized sampling scheme. Wet meadows were sampled to the mineral boundary using a gouge auger, and we used a combination of full peat cores and a rapid peat sampling procedure to estimate peat carbon stocks. In the lab, soils were processed for bulk density and carbon content, and total carbon stock of each core was calculated. We sampled 63 wet meadows and 42 peatlands. On a per hectare basis, carbon stocks varied strongly between peatlands (avg. 1092 MgC ha ) and wet meadows (avg. 30 MgC ha ). Overall, wetlands in Huascarán National Park contain 24.4 Tg of carbon with peatlands storing 97% of the total wetland carbon and wet meadows accounting for 3% of the wetland carbon in the park. In addition, our results show that rapid peat sampling can be an effective method for sampling carbon stocks in peatlands. These data are important for countries developing land use and climate change policies as well as providing a rapid assessment method for wetland carbon stock monitoring programs. Although wetlands contain a disproportionately high amount of earth’s total soil carbon, many regions are still poorly mapped and with unquantified carbon stocks. The tropical Andes contain a high concentration of wetlands consisting mostly of wet meadows and peatlands, yet their total organic carbon stocks are poorly quantified, as well as the carbon fraction that wet meadows store compared to peatlands. Therefore, our goal was to quantify how soil carbon stocks vary between wet meadows and peatlands for a previously mapped Andean region, Huascarán National Park, Peru. Our secondary goal was to test a rapid peat sampling protocol to facilitate field sampling in remote areas. We sampled soil to calculate carbon stocks of four wetland types: cushion peat, graminoid peat, cushion wet meadow, and graminoid wet meadow. Soil sampling was conducted by using a stratified randomized sampling scheme. Wet meadows were sampled to the mineral boundary using a gouge auger, and we used a combination of full peat cores and a rapid peat sampling procedure to estimate peat carbon stocks. In the lab, soils were processed for bulk density and carbon content, and total carbon stock of each core was calculated. We sampled 63 wet meadows and 42 peatlands. On a per hectare basis, carbon stocks varied strongly between peatlands (avg. 1092 MgC ha-1) and wet meadows (avg. 30 MgC ha-1). Overall, wetlands in Huascarán National Park contain 24.4 Tg of carbon with peatlands storing 97% of the total wetland carbon and wet meadows accounting for 3% of the wetland carbon in the park. In addition, our results show that rapid peat sampling can be an effective method for sampling carbon stocks in peatlands. These data are important for countries developing land use and climate change policies as well as providing a rapid assessment method for wetland carbon stock monitoring programs. Although wetlands contain a disproportionately high amount of earth's total soil carbon, many regions are still poorly mapped and with unquantified carbon stocks. The tropical Andes contain a high concentration of wetlands consisting mostly of wet meadows and peatlands, yet their total organic carbon stocks are poorly quantified, as well as the carbon fraction that wet meadows store compared to peatlands. Therefore, our goal was to quantify how soil carbon stocks vary between wet meadows and peatlands for a previously mapped Andean region, Huascarán National Park, Peru. Our secondary goal was to test a rapid peat sampling protocol to facilitate field sampling in remote areas. We sampled soil to calculate carbon stocks of four wetland types: cushion peat, graminoid peat, cushion wet meadow, and graminoid wet meadow. Soil sampling was conducted by using a stratified randomized sampling scheme. Wet meadows were sampled to the mineral boundary using a gouge auger, and we used a combination of full peat cores and a rapid peat sampling procedure to estimate peat carbon stocks. In the lab, soils were processed for bulk density and carbon content, and total carbon stock of each core was calculated. We sampled 63 wet meadows and 42 peatlands. On a per hectare basis, carbon stocks varied strongly between peatlands (avg. 1092 MgC ha-1) and wet meadows (avg. 30 MgC ha-1). Overall, wetlands in Huascarán National Park contain 24.4 Tg of carbon with peatlands storing 97% of the total wetland carbon and wet meadows accounting for 3% of the wetland carbon in the park. In addition, our results show that rapid peat sampling can be an effective method for sampling carbon stocks in peatlands. These data are important for countries developing land use and climate change policies as well as providing a rapid assessment method for wetland carbon stock monitoring programs.Although wetlands contain a disproportionately high amount of earth's total soil carbon, many regions are still poorly mapped and with unquantified carbon stocks. The tropical Andes contain a high concentration of wetlands consisting mostly of wet meadows and peatlands, yet their total organic carbon stocks are poorly quantified, as well as the carbon fraction that wet meadows store compared to peatlands. Therefore, our goal was to quantify how soil carbon stocks vary between wet meadows and peatlands for a previously mapped Andean region, Huascarán National Park, Peru. Our secondary goal was to test a rapid peat sampling protocol to facilitate field sampling in remote areas. We sampled soil to calculate carbon stocks of four wetland types: cushion peat, graminoid peat, cushion wet meadow, and graminoid wet meadow. Soil sampling was conducted by using a stratified randomized sampling scheme. Wet meadows were sampled to the mineral boundary using a gouge auger, and we used a combination of full peat cores and a rapid peat sampling procedure to estimate peat carbon stocks. In the lab, soils were processed for bulk density and carbon content, and total carbon stock of each core was calculated. We sampled 63 wet meadows and 42 peatlands. On a per hectare basis, carbon stocks varied strongly between peatlands (avg. 1092 MgC ha-1) and wet meadows (avg. 30 MgC ha-1). Overall, wetlands in Huascarán National Park contain 24.4 Tg of carbon with peatlands storing 97% of the total wetland carbon and wet meadows accounting for 3% of the wetland carbon in the park. In addition, our results show that rapid peat sampling can be an effective method for sampling carbon stocks in peatlands. These data are important for countries developing land use and climate change policies as well as providing a rapid assessment method for wetland carbon stock monitoring programs. |
| Author | Resh, Sigrid C. Hribljan, John A. Bourgeau-Chavez, Laura Chimner, Rodney A. Bowser, Gillian Lilleskov, Erik A. Battaglia, Michael |
| AuthorAffiliation | 5 United States Department of Agriculture (USDA) Forest Service, Northern Research Station, Climate, Fire and Carbon Cycle Sciences Unit , Houghton, MI , United States 2 University of Nebraska Omaha, Department of Biology , Omaha, NE , United States 1 Michigan Technological University, College of Forest Resources and Environmental Science , Houghton, MI , United States 3 Michigan Tech Research Institute, Michigan Technological University , Ann Arbor, MI , United States 4 Department of Ecosystem Science and Sustainability, Colorado State University , Fort Collins, CO , United States |
| AuthorAffiliation_xml | – name: 4 Department of Ecosystem Science and Sustainability, Colorado State University , Fort Collins, CO , United States – name: 5 United States Department of Agriculture (USDA) Forest Service, Northern Research Station, Climate, Fire and Carbon Cycle Sciences Unit , Houghton, MI , United States – name: 1 Michigan Technological University, College of Forest Resources and Environmental Science , Houghton, MI , United States – name: 2 University of Nebraska Omaha, Department of Biology , Omaha, NE , United States – name: 3 Michigan Tech Research Institute, Michigan Technological University , Ann Arbor, MI , United States |
| Author_xml | – sequence: 1 givenname: Rodney A. surname: Chimner fullname: Chimner, Rodney A. – sequence: 2 givenname: Sigrid C. surname: Resh fullname: Resh, Sigrid C. – sequence: 3 givenname: John A. surname: Hribljan fullname: Hribljan, John A. – sequence: 4 givenname: Michael surname: Battaglia fullname: Battaglia, Michael – sequence: 5 givenname: Laura surname: Bourgeau-Chavez fullname: Bourgeau-Chavez, Laura – sequence: 6 givenname: Gillian surname: Bowser fullname: Bowser, Gillian – sequence: 7 givenname: Erik A. surname: Lilleskov fullname: Lilleskov, Erik A. |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/37180385$$D View this record in MEDLINE/PubMed |
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| Cites_doi | 10.1111/j.1365-2486.2010.02279.x 10.1657/1523-0430(2007)39[229:MMOCPA]2.0.CO;2 10.1111/j.1469-185X.1968.tb00968.x 10.3390/rs12152458 10.1007/s13157-010-0039-5 10.2136/sssaj2012.0040 10.1002/2016JG003550 10.1672/UCRT083-205 10.1111/gcb.13807 10.1007/s13157-014-0574-6 10.1657/1938-4246-42.1.19 10.1029/2019JF005273 10.2307/jj.17681907.26 10.1016/S0033-5894(02)00011-X 10.1088/1748-9326/9/12/124017 10.3389/feart.2021.676748 10.1007/s13157-019-01200-8 10.1007/s11273-016-9482-2 10.1080/00045608.2010.497369 10.1038/ncomms13835 10.1007/s10040-008-0380-4 10.1146/annurev-environ-110615-085520 10.1016/j.scitotenv.2020.139361 10.1111/j.1365-2389.2011.01364.x 10.1007/s13157-019-01134-1 10.19189/MaP.2022.SNPG.Sc.1818931 10.1016/j.cageo.2014.03.005 |
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| Keywords | wet meadows bofedales puna peatlands tropics |
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| References | Parsekian (B32) 2012; 76 Hribljan (B21) 2017; 23 Mark (B28) 2010; 100 Chambers (B7) 2011; 7 Cooper (B17) 2010; 42 Silvestri (B35) 2019; 124 Nahlik (B29) 2016; 7 Hribljan (B20) 2023 (B37) 2022 Billings (B2) 1968; 43 Luteyn (B26) 1999 Beucher (B1) 2020; 12 Chimner (B8) 2020 Salvador (B33) 2014; 15 Wolf (B38) 2015; 15 Bourgeau-Chavez (B4) 2021; 9 Chimner (B10) 2008; 3 Comas (B15) 2017; 122 Young (B39) 1997 Clifford (B14) 2014; 67 Magnan (B27) 2023; 29 Cooper (B16) 2012 Chimner (B12) 2014; 34 Hribljan (B22) 2016; 24 Boaga (B3) 2020; 737 Chimner (B11) 2010; 30 Kauffman (B23) 2012 Page (B30) 2016; 41 Cavieres (B6) 2007; 39 Suárez (B36) 2021; 27 Kolka (B24) 2018 Brus (B5) 2011; 2 Cleef (B13) 1979 Draper (B18) 2014; 9 Earle (B19) 2003; 59 Chimner (B9) 2019; 39 Page (B31) 2011; 17 Loheide (B25) 2009; 17 Schook (B34) 2020; 40 |
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| Snippet | Although wetlands contain a disproportionately high amount of earth’s total soil carbon, many regions are still poorly mapped and with unquantified carbon... Although wetlands contain a disproportionately high amount of earth's total soil carbon, many regions are still poorly mapped and with unquantified carbon... |
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| SubjectTerms | bofedales peatlands Plant Science puna tropics wet meadows |
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| Title | Mountain wetland soil carbon stocks of Huascarán National Park, Peru |
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