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Die Messung von Tagesgängen der Kohlenstoffdioxid-Flüsse mit manuellen Hauben startet vor Sonnenaufgang (Großes Moor bei Gifhorn, 04:45 Uhr).
© Thünen-Institut/AK
Die Messung von Tagesgängen der Kohlenstoffdioxid-Flüsse mit manuellen Hauben startet vor Sonnenaufgang (Großes Moor bei Gifhorn, 04:45 Uhr).
Institut für

AK Agrarklimaschutz

Bodenzustandserhebung Landwirtschaft (BZE-LW)

Publikationen

  1. 0

    Froger C, Tondini E, Arrouays D, Oorts K, Poeplau C, Wetterlind J, Putku E, Saby NPA, Fantappiè M, Styc Q, Chenu C, Salomez J, Callewaert S, Vanwindekens FM, Huyghebaert B, Herinckx J, Heilek S, Harbo LS, Carvalho Gomes L De, Lázaro-López A, et al (2024) Comparing LUCAS Soil and national systems: Towards a harmonized European Soil monitoring network. Geoderma 449:117027, DOI:10.1016/j.geoderma.2024.117027

    https://literatur.thuenen.de/digbib_extern/dn068762.pdf

  2. 1

    Don A, Drexler S, Poeplau C (2024) Indikatoren zur Bewertung von Humusgehalten für die Bodengesundheit. Bodenschutz(1):8-15

  3. 2

    Poeplau C, Don A (2023) A simple soil organic carbon level metric beyond the organic carbon-to-clay ratio. Soil Use Manag 39(3):1057-1067, DOI:10.1111/sum.12921

    https://literatur.thuenen.de/digbib_extern/dn066438.pdf

  4. 3

    Begill N, Don A, Poeplau C (2023) No detectable upper limit of mineral-associated organic carbon in temperate agricultural soils. Global Change Biol 29(16):4662-4669, DOI:10.1111/gcb.16804

    https://literatur.thuenen.de/digbib_extern/dn066439.pdf

  5. 4

    Poeplau C, Begill N, Don A (2023) Response to: "The robust concept of mineral-associated organic matter saturation: A letter to Begill et al. (2023)". Global Change Biol 29(21):e4-e6, DOI:10.1111/gcb.16920

    https://literatur.thuenen.de/digbib_extern/dn066732.pdf

  6. 5

    Poeplau C, Gregorich E (2022) Advances in measuring soil organic carbon stocks and dynamics at the profile scale. Cambridge: Burleigh Dodds Science Publishing, 28 p, DOI:10.19103/AS.2022.0106.10

    https://literatur.thuenen.de/digbib_extern/dn064729.pdf

  7. 6

    Drexler S, Broll G, Flessa H, Don A (2022) Benchmarking soil organic carbon to support agricultural carbon management: A German case study. J Plant Nutr Soil Sci 185(3):427-440, DOI:10.1002/jpln.202200007

    https://literatur.thuenen.de/digbib_extern/dn064821.pdf

  8. 7

    Poeplau C, Don A, Flessa H (2022) Bodenzustandserhebung Landwirtschaft. Braunschweig: Thünen-Institut für Agrarklimaschutz, 2 p, Project Brief Thünen Inst 2022/02, DOI:10.3220/PB1641478727000

    https://literatur.thuenen.de/digbib_extern/dn064478.pdf

  9. 8

    Harbo LS, Schulz G, Heinemann H, Dechow R, Poeplau C (2022) Flower strips as a carbon sequestration measure in temperate croplands. Plant Soil 482(1-2):647-663, DOI:10.1007/s11104-022-05718-5

    https://literatur.thuenen.de/digbib_extern/dn065469.pdf

  10. 9

    Poeplau C, Prietz R, Don A (2022) Plot-scale variability of organic carbon in temperate agricultural soils - Implications for soil monitoring. J Plant Nutr Soil Sci 185(3):403-416, DOI:10.1002/jpln.202100393

    https://literatur.thuenen.de/digbib_extern/dn064730.pdf

  11. 10

    Schneider F, Amelung W, Don A (2021) Origin of carbon in agricultural soil profiles deduced from depth gradients of C:N ratios, carbon fractions, δ13C and δ15N values. Plant Soil 460:123-148, DOI:10.1007/s11104-020-04769-w

    https://literatur.thuenen.de/digbib_extern/dn063084.pdf

  12. 11

    Wittnebel M, Tiemeyer B, Dettmann U (2021) Peat and other organic soils under agricultural use in Germany: Properties and challenges for classification [online]. Mires Peat 27:19, zu finden in <http://mires-and-peat.net/modules/download_gallery/dlc.php?file=405&id=1628187927> [zitiert am 11.08.2021], DOI:10.19189/MaP.2020.SJ.StA.2093

    https://literatur.thuenen.de/digbib_extern/dn063812.pdf

  13. 12

    Poeplau C, Don A, Schneider F (2021) Roots are key to increasing the mean residence time of organic carbon entering temperate agricultural soils. Global Change Biol 27(19):4921-4934, DOI:10.1111/gcb.15787

    https://literatur.thuenen.de/digbib_extern/dn063791.pdf

  14. 13

    Säurich A, Tiemeyer B, Dettmann U, Fiedler S, Don A (2021) Substrate quality of drained organic soils - Implications for carbon dioxide fluxes. J Plant Nutr Soil Sci 184(5):543-555, DOI:10.1002/jpln.202000475

    https://literatur.thuenen.de/digbib_extern/dn063797.pdf

  15. 14

    Poeplau C, Don A, Flessa H, Heidkamp A, Jacobs A, Prietz R (2020) Erste Bodenzustandserhebung Landwirtschaft - Kerndatensatz [Datenpublikation] [online]. 12 Excel-Dateien. Göttingen: Open Agrar Repositorium, zu finden in <https://www.openagrar.de/receive/openagrar_mods_00054877> [zitiert am 30.09.2021], DOI:10.3220/DATA20200203151139

  16. 15

    Jacobs A, Poeplau C, Weiser C, Fahrion-Nitschke A, Don A (2020) Exports and inputs of organic carbon on agricultural soils in Germany. Nutr Cycl Agroecosyst 118:249-271, DOI:10.1007/s10705-020-10087-5

    https://literatur.thuenen.de/digbib_extern/dn062762.pdf

  17. 16

    Drexler S, Broll G, Don A, Flessa H (2020) Standorttypische Humusgehalte landwirtschaftlich genutzter Böden Deutschlands. Braunschweig: Johann Heinrich von Thünen-Institut, 200 p, Thünen Rep 75, DOI:10.3220/REP1583152694000

    https://literatur.thuenen.de/digbib_extern/dn062138.pdf

  18. 17

    Poeplau C, Jacobs A, Don A, Vos C, Schneider F, Wittnebel M, Tiemeyer B, Heidkamp A, Prietz R, Flessa H (2020) Stocks of organic carbon in German agricultural soils - Key results of the first comprehensive inventory. J Plant Nutr Soil Sci 183(6):665-681, DOI:10.1002/jpln.202000113

    https://literatur.thuenen.de/digbib_extern/dn062722.pdf

  19. 18

    Säurich A, Tiemeyer B, Don A, Fiedler S, Bechtold M, Amelung W, Freibauer A (2019) Drained organic soils under agriculture - the more degraded the soil the higher the specific basal respiration. Geoderma 355:113911, DOI:10.1016/j.geoderma.2019.113911

    https://literatur.thuenen.de/digbib_extern/dn061249.pdf

  20. 19

    Vos C, Don A, Hobley EU, Prietz R, Heidkamp A, Freibauer A (2019) Factors controlling the variation in organic carbon stocks in agricultural soils of Germany. Eur J Soil Sci 70(3):550-564, DOI:10.1111/ejss.12787

  21. 20

    Säurich A, Tiemeyer B, Dettmann U, Don A (2019) How do sand addition, soil moisture and nutrient status influence greenhouse gas fluxes from drained organic soils? Soil Biol Biochem 135:71-84, DOI:10.1016/j.soilbio.2019.04.013

    https://literatur.thuenen.de/digbib_extern/dn060978.pdf

  22. 21

    Flessa H, Don A, Jacobs A, Dechow R, Tiemeyer B, Poeplau C (2019) Humus in landwirtschaftlich genutzten Böden Deutschlands : Ausgewählte Ergebnisse der Bodenzustandserhebung. Berlin: BMEL, 47 p

  23. 22

    Poeplau C, Helfrich M, Dechow R, Szoboszlay M, Tebbe CC, Don A, Greiner B, Zopf D, Thumm U, Korevaar H, Geerts R (2019) Increased microbial anabolism contributes to soil carbon sequestration by mineral fertilization in temperate grasslands. Soil Biol Biochem 130:167-176, DOI:10.1016/j.soilbio.2018.12.019

  24. 23

    Jaconi A, Poeplau C, Ramirez-Lopez L, Wesemael B van, Don A (2019) Log-ratio transformation is the key to determining soil organic carbon fractions with near-infrared spectroscopy. Eur J Soil Sci 70(1):127-139, DOI:10.1111/ejss.12761

  25. 24

    Riggers C, Poeplau C, Don A, Bamminger C, Höper H, Dechow R (2019) Multi-model ensemble improved the prediction of trends in soil organic carbon stocks in German croplands. Geoderma 345:17-30, DOI:10.1016/j.geoderma.2019.03.014

  26. 25

    Jaconi A, Vos C, Don A (2019) Near infrared spectroscopy as an easy and precise method to estimate soil texture. Geoderma 337:906-913, DOI:10.1016/j.geoderma.2018.10.038

  27. 26

    Schneider F, Don A (2019) Root-restricting layers in German agricultural soils. Part I: extent and cause. Plant Soil 442(1-2):433-451, DOI:10.1007/s11104-019-04185-9

    https://literatur.thuenen.de/digbib_extern/dn061271.pdf

  28. 27

    Schneider F, Don A (2019) Root-restricting layers in German agricultural soils. Part II: adaptation and melioration strategies. Plant Soil 442(1-2):419-432, DOI:10.1007/s11104-019-04186-8

    https://literatur.thuenen.de/digbib_extern/dn061272.pdf

  29. 28

    Weiser C, Fuß R, Kage H, Flessa H (2018) Do farmers in Germany exploit the potential yield and nitrogen benefits from preceding oilseed rape in winter wheat cultivation? Arch Agron Soil Sci 64(1):25-37, DOI:10.1080/03650340.2017.1326031

  30. 29

    Vos C, Jaconi A, Jacobs A, Don A (2018) Hot regions of labile and stable soil organic carbon in Germany - Spatial variability and driving factors. Soil 4:153-167, DOI:10.5194/soil-4-153-2018

    https://literatur.thuenen.de/digbib_extern/dn059858.pdf

  31. 30

    Jacobs A, Flessa H, Don A, Heidkamp A, Prietz R, Dechow R, Gensior A, Poeplau C, Riggers C, Schneider F, Tiemeyer B, Vos C, Wittnebel M, Müller T, Säurich A, Fahrion-Nitschke A, Gebbert S, Jaconi A, Kolata H, Laggner A, et al (2018) Landwirtschaftlich genutzte Böden in Deutschland - Ergebnisse der Bodenzustandserhebung. Braunschweig: Johann Heinrich von Thünen-Institut, 316 p, Thünen Rep 64, DOI:10.3220/REP1542818391000

    https://literatur.thuenen.de/digbib_extern/dn060497.pdf

  32. 31

    Poeplau C, Zopf D, Greiner B, Geerts R, Korvaar H, Thumm U, Don A, Heidkamp A, Flessa H (2018) Why does mineral fertilization increase soil carbon stocks in temperate grasslands? Agric Ecosyst Environ 265:144-155, DOI:10.1016/j.agee.2018.06.003

  33. 32

    Jaconi A, Don A, Freibauer A (2017) Prediction of soil organic carbon at the country scale: stratification strategies for near-infrared data. Eur J Soil Sci 68(6):919-929, DOI:10.1111/ejss.12485

  34. 33

    Poeplau C, Vos C, Don A (2017) Soil organic carbon stocks are systematically overestimated by misuse of the parameters bulk density and rock fragment content. Soil 3:61-66, DOI:10.5194/soil-3-61-2017

    https://literatur.thuenen.de/digbib_extern/dn058467.pdf

  35. 34

    Walter K, Don A, Tiemeyer B, Freibauer A (2016) Determining soil bulk density for carbon stock calculation: a systematic method comparison. Soil Sci Soc Am J 80(3):579-591, DOI:10.2136/sssaj2015.11.0407

    https://literatur.thuenen.de/digbib_extern/dn056867.pdf

  36. 35

    Poeplau C (2016) Estimating root: shoot ratio and soil carbon inputs in temperate grasslands with the RothC model. Plant Soil 407(1):293-305, DOI:10.1007/s11104-016-3017-8

  37. 36

    Vos C, Don A, Prietz R, Heidkamp A, Freibauer A (2016) Field-based soil-texture estimates could replace laboratory analysis. Geoderma 267:215-219, DOI:10.1016/j.geoderma.2015.12.022

  38. 37

    Freibauer A (2015) Großinventur auf deutschen Äckern. Ökologie & Landbau(4):15-17

  39. 38

    Bach M, Heidkamp A, Siebner C, Freibauer A (2011) The German agricultural soil carbon inventory: conceptual framework and methodology. Geophys Res Abstr 13:EGU2011-1606

    https://literatur.thuenen.de/digbib_extern/dn049772.pdf

  40. 39

    Bach M, Freibauer A, Siebner C, Flessa H (2011) The German Agricultural Soil Inventory: sampling design for a representative assessment of soil organic carbon stocks. Proced Environ Sci 7:323-328, DOI:10.1016/j.proenv.2011.07.056

    Ergebnisse

    Die nachfolgende Karte zeigt die Kohlenstoffgehalte der von uns beprobten Oberböden unter landwirtschaftlicher Nutzung.

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