Abstract
Context
Albedo can be used to quantify ecosystem and landscape contributions to local and global climate. Such contributions are conventionally expressed as radiative forcing (RF) and global warming impact (GWI). We contextualize our results within landscape carbon production and storage to highlight the importance of changes in albedo for landscape GWI from multiple causes, including net ecosystem production (NEP) and greenhouse gas (GHG) emissions.
Objective
To examine the spatiotemporal changes in albedo (Δα) in contrasting managed landscapes through calculations of albedo-induced RF (RFΔα) and GWI (GWIΔα) under different climatic conditions.
Methods
We selected five contrasting landscapes within the Kalamazoo River watershed in southern Michigan USA as proof of concept. The daily MCD43A3 MODIS (V006) product was used to analyze the inter- and intra-annual variations of growing season albedo. In addition, the variations of RFΔα and GWIΔα were computed based on landscape composition and climate.
Results
The RFΔα (− 5.6 W m−2) and GWIΔα (− 1.3 CO2eq ha−1 year−1) were high in forest-dominated landscapes, indicating cooling effects and CO2eq mitigation impacts similar to crops. The CO2eq mitigation of cropland-dominated landscapes was on average 52% stronger than forest-dominated landscapes. In the landscape with the highest proportion of forest, under dry and wet conditions CO2eq mitigation was reduced by up to 24% and ~ 30%, respectively; in one cropland-dominated landscape wet conditions reduced CO2eq mitigation by 23%.
Conclusions
Findings demonstrate that quantifying spatiotemporal changes in albedo in managed landscapes and under different climatic conditions is essential to understand how landscape modification affects RFΔα and GWIΔα and thereby contributes to ecosystem-level GWI.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abraha M, Chen J, Chu H, Zenone T, John R, Su YJ, Hamilton SK (2015) Evapotranspiration of annual and perennial biofuel crops in a variable climate. Glob Change Biol Bioenergy 7:1344–1356
Abraha M, Gelfand I, Hamilton SK, Shao C, Su YJ, Robertson JP, Chen J (2016) Ecosystem water-use efficiency of annual corn and perennial grasslands: contributions from land-use history and species composition. Ecosystems 19:1001–1012
Abraha M, Gelfand I, Hamilton SK, Shao C, Su YJ, Chen J, Robertson JP (2019) Carbon debt of field-scale conservation reserve program grasslands converted to annual and perennial bioenergy crops. Environ Res Lett 14:024019. https://doi.org/10.1088/1748-9326/aafc10
Akbari H, Menon S, Rosenfeld A (2009) Global cooling: increasing world-wide urban albedos to offset CO2. Clim Change 94:275–286
Anderson RG, Canadell JG, Randerson JT, Jackson RB, Hungate BA, Baldocchi DD, Ban-Weiss GA, Bonan GB, Caldeira K, Cao L, Diffenbaugh NS, Gurney KR, Kueppers LM, Law BE, Luyssaert S, O'Halloran TL (2011) Biophysical considerations in forestry for climate protection. Front Ecol Environ 9:174–182. https://doi.org/10.1890/090179
Anderson-Teixeira KJ, Snyder PK, Twine TE, Cuadra SV, Costa MH, DeLucia EH (2012) Climate-regulation services of natural and agricultural ecoregions of the Americas. Nat Clim Change 2:177–181
Antón A, Cebrian J, Heck KL, Duarte CM, Sheehan KL, Miller M-EC, Foster CD (2011) Decoupled effects (positive to negative) of nutrient enrichment on ecosystem services. Ecol Appl 21:991–1009. https://doi.org/10.1890/09-0841.1
Bala G, Caldeira K, Wickett M, Phillips TJ, Lobell DB, Delire C, Mirin A (2007) Combined climate and carbon-cycle effects of large-scale deforestation. Proc Natl Acad Sci USA 104:6550–6555
Barnes CA, Roy DP (2010) Radiative forcing over the conterminous United States due to contemporary land cover land use change and sensitivity to snow and interannual albedo variability. J Geophys Res Biogeosciences 115:G04033. https://doi.org/10.1029/2010JG001428
Bennett AF, Radford JQ, Haslem A (2006) Properties of land mosaics: implications for nature conservation in agricultural environments. Biol Conserv 133:250–264
Berbet MLC, Costa MH (2003) Climate change after tropical deforestation: seasonal variability of surface albedo and its effects on precipitation change. J Clim 16:2099–2104. https://doi.org/10.1175/1520-0442(2003)016%3c2099:CCATDS%3e2.0.CO;2
Betts RA (2000) Offset of the potential carbon sink from boreal forestation by decreases in surface albedo. Nature 408:187–190
Betts RA (2001) Biogeophysical impacts of land use on present-day climate: near-surface temperature change and radiative forcing. Atmos Sci Lett 2:39–51. https://doi.org/10.1006/asle.2001.0037
Bird DN, Kunda M, Mayer A, Schlamadinger B, Canella L, Johnston M (2008) Incorporating changes in albedo in estimating the climate mitigation benefits of land use change projects. Biogeosci Discuss 5:1511–1543
Bonan GB (2008) Forests and climate change: forcings, feedbacks, and the climate benefits of forests. Science 320:1444–1449
Bonan GB (2016) Ecological climatology: concepts and applications. Cambridge University Press, Cambridge, p 723
Boucher O, Friedlingstein P, Collins B, Shine KP (2009) The indirect global warming potential and global temperature change potential due to methane oxidation. Environ Res Lett 4:044007
Bright RM (2015) Metrics for biogeophysical climate forcings from land use and land cover changes and their inclusion in life cycle assessment: a critical review. Environ Sci Technol 49:3291–3303
Bright RM, Zhao K, Jackson RB, Cherubini F (2015) Quantifying surface albedo and other direct biogeophysical climate forcings of forestry activities. Glob Change Biol 21:3246–3266
Brovkin V, Boysen L, Raddatz T, Gayler V, Loew A, Claussen M (2013) Evaluation of vegetation cover and land-surface albedo in MPI-ESM CMIP5 simulations. J Adv Model Earth SY 5:48–57
Brown DG, Pijanowski BC, Duh JD (2000) Modeling the relationships between land use and land cover on private lands in the Upper Midwest, USA. J Environ Manage 59:247–263
Burton VB, Zak DR, Denton SR, Spurr SH (1998) Forest ecology. 4th Edition. pp 225-240, New York
Cai H, Wang J, Wang Y, Wang M, Qin Z, Dunn B (2016) Consideration of land use change-induced surface albedo effects in life-cycle analysis of biofuels. Energy Environ Sci 9:2855–2867
Campbell GS, Norman JM (1998) Introduction to environmental biophysics, 2nd edn. Springer, New York, p 286
Carrer D, Pique G, Ferlicoq M, Ceamanos X, Ceschia E (2018) What is the potential of cropland albedo management in the fight against global warming? A case study based on the use of cover crops. Environ Res Lett 13:044030
Chen J, Brosofske KD, Noormets A, Crow TR, Bresee MK, Le Moine JM, Euskirchen ES, Mather SV, Zheng D (2004) A working framework for quantifying carbon sequestration in disturbed land mosaics. Environ Manage 33:S210–S221
Chen J, Sciusco P, Ouyang Z, Zhang R, Henebry GM, John R, Roy DP (2019) Linear downscaling from MODIS to Landsat: connecting landscape composition with ecosystem functions. Landsc Ecol 34:2917–2934
Chen J, Wan S, Henebry GM, Qi J, Gutman G, Sun G, Kappas M (2013) Dryland East Asia: land dynamics amid social and climate change. Walter de Gruyter, Berlin, Boston, p 470
Cherubini F, Bright RM, Strømman AH (2012) Site-specific global warming potentials of biogenic CO2 for bioenergy: contributions from carbon fluxes and albedo dynamics. Environ Res Lett 7:045902
Chrysoulakis N, Mitraka Z, Gorelick N (2018) Exploiting satellite observations for global surface albedo trends monitoring. Theor Appl Climatol 137:1171–1179
Culf AD, Fisch G, Hodnett MG (1995) The albedo of Amazonian forest and ranch land. J Clim 8:1544–1554
Davin EL, de Noblet-Ducoudré N, Friedlingstein P (2007) Impact of land cover change on surface climate: relevance of the radiative forcing concept. Geophys Res Lett 34:L13702
Davin EL, Seneviratne SI, Ciais P, Olioso A, Wang T (2014) Preferential cooling of hot extremes from cropland albedo management. Proc Natl Acad Sci USA 111:9757–9761
Dickinson RE (1983) Land surface processes and climate—surface albedos and energy balance. Adv Geophys 25:305–353
Eagle AJ, Henry LR, Olander LP, Haugen-Kozyra K, Millar N, Robertson GP (2010) Greenhouse gas mitigation potential of agricultural land management in the United States. A Synthesis of the Literature. Technical Working Group on Agricultural Greenhouse Gases (T‐AGG) Report 68p
Eagle AJ, Henry LR, Olander LP, Haugen-Kozyra K, Millar N, Robertson GP (2012) Greenhouse gas mitigation potential of agricultural land management in the United States: A synthesis of the literature. Report NIR, 10-04, 72p.
Euskirchen ES, Chen J, Li H, Gustafson EJ, Crow TR (2002) Modeling landscape net ecosystem productivity (LandNEP) under alternative management regimes. Ecol Model 154:75–91
Feilhauer H, He KS, Rocchini D (2012) Modeling species distribution using niche-based proxies derived from composite bioclimatic variables and MODIS NDVI. Remote Sens 4:2057–2075
Fletcher R, Fortin M-J (2018) Spatial dependence and autocorrelation. In: Fletcher R, Fortin M-J (eds) Spatial ecology and conservation modeling: applications with R. Springer International Publishing, Cham, pp 133–168
Forster P, Ramaswamy V, Artaxo P, Berntsen T, Betts R, Fahey DW, Haywood J, Lean J, Lowe DC, Raga G, Schulz M, Dorland RV, Bodeker G, Etheridge D, Foukal P, Geller FM, Joos F, Keeling CD, Keeling R, Kinne S, Lassey K, Oram D, O’Shaughnessy K, Ramankutty N, Reid G, Rind D, Rosenlof R, Sausen R, Schwarzkopf D, Solanki SK, Stenchikov G, Stuber N, Takemura T, Textor C, Wang R, Weiss R, Whorf T, Nakajima T, Ramanathan V, Ramaswamy V, Artaxo P, Berntsen T, Betts R, Fahey DW, Haywood J, Lean J, Lowe DC, Myhre G, Nganga J, Prinn R, Raga G, Schulz M, Dorland RV (2007) Changes in atmospheric constituents and in radiative forcing. J Clim 25:527–542
Fuglestvedt JS, Berntsen TK, Godal O, Sausen R, Shine KP, Skodvin T (2003) Metrics of climate change: assessing radiative forcing and emission indices. Clim Change 58:267–331
Gelfand I, Robertson GP (2015) Mitigation of greenhouse gas emissions in agricultural ecosystems. In: Hamilton SK, Doll JE, Robertson GP (eds) The ecology of agricultural landscapes: long-term research on the path to sustainability. Oxford University Press, New York, pp 310–339
Gelfand I, Sahajpal R, Zhang X, Izaurralde RC, Gross KL, Robertson GP (2013) Sustainable bioenergy production from marginal lands in the US Midwest. Nature 493:514–517
Georgescu M, Lobell DB, Field CB (2011) Direct climate effects of perennial bioenergy crops in the United States. Proc Natl Acad Sci USA 108:4307–4312
Goosse H (2015) Climate system dynamics and modeling. Cambridge University Press, Cambridge, p 357
Gorelick N, Hancher M, Dixon M, Ilyushchenko S, Thau D, Moore R (2017) Google Earth Engine: planetary-scale geospatial analysis for everyone. Remote Sens Environ 202:18–27
Govindasamy B, Duffy PB, Caldeira K (2001) Land use changes and northern hemisphere cooling. Geophys Res Lett 28:291–294
Gray V (2007) Climate Change 2007: the physical science basis summary for policymakers. Energy Environ 18:433–440
Haas G, Wetterich F, Köpke U (2001) Comparing intensive, extensified and organic grassland farming in southern Germany by process life cycle assessment. Agric Ecosyst Environ 83:43–53
Haines A (2003) Climate change 2001: the scientific basis. Contribution of working group 1 to the third assessment report of the intergovernmental panel on climate change. Houghton JT, Ding Y, Griggs DJ, Noguer M, van Der Winden PJ, Dai X. Cambridge: Cambridge University Press, 2001, Pp. 881, £34.95 (HB) ISBN: 0-21-01495-6; £90.00 (HB) ISBN: 0-521-80767-0. Int J Epidemiol 32(2):321
Haralick RM, Shanmugam K, Dinstein I (1973) Textural features for image classification. IEEE Trans Syst Man Cybern SMC 3:610–621
Henderson-Sellers A, Wilson MF (1983) Surface albedo data for climatic modeling. Rev Geophys 21:1743–1778
Houspanossian J, Giménez R, Jobbágy E, Nosetto M (2017) Surface albedo raise in the South American Chaco: combined effects of deforestation and agricultural changes. Agric For Meteorol 232:118–127
Iqbal M (2012) An Introduction to Solar Radiation. Elsevier, New York, 390p
Jeong SJ, Ho C-H, Gim HJ, Brown ME (2011) Phenology shifts at start vs. end of growing season in temperate vegetation over the Northern Hemisphere for the period 1982–2008. Glob Change Bio 17:2385–2399
Jeong SJ, Ho CH, Piao S, Kim J, Ciais P, Lee YB, Jhun JG, Park SK (2014) Effects of double cropping on summer climate of the North China Plain and neighbouring regions. Nat Clim Change 4:615–619
Jiao T, Williams A, Ghimire B, Masek J, Gao F, Schaaf C (2017) Global climate forcing from albedo change caused by large-scale deforestation and reforestation: quantification and attribution of geographic variation. Clim Change 142:463–476
Kaye JP, Quemada M (2017) Using cover crops to mitigate and adapt to climate change. A review. Agron Sustain Dev 37:4
Lee X, Goulden ML, Hollinger DY, Barr A, Black TA, Bohrer G, Bracho R, Drake B, Goldstein A, Gu L, Katul G, Kolb T, Law BE, Margolis H, Meyers T, Monson R, Munger W, Oren R, Paw UKT, Richardson AD, Schmid HP, Staebler R, Wofsy S, Zhao L (2011) Observed increase in local cooling effect of deforestation at higher latitudes. Nature 479:384–387
Lenton TM, Vaughan NE (2009) The radiative forcing potential of different climate geoengineering options. Atmos Chem Phys 9:5539–5561
Li B, Gasser T, Ciais P, Piao S, Tao S, Balkanski Y, Hauglustaine D, Boisier JP, Chen Z, Huang M, Li LZ, Li Y, Liu H, Liu J, Peng S, Shen Z, Sun Z, Wang R, Wang T, Yin G, Yin Y, Zeng Z, Zhou F (2016) The contribution of China’s emissions to global climate forcing. Nature 531(7594):357
Li J, Wang XR, Wang XJ, Ma WC, Zhang H (2009) Remote sensing evaluation of urban heat island and its spatial pattern of the Shanghai metropolitan area, China. Ecol Complex 6:413–420
Liang S, Zhao X, Liu S, Yuan W, Cheng X, Xiao Z, Zhang X, Liu Q, Cheng J, Tang H, Qu Y, Bo Y, Qu Y, Ren H, Yu K, Townshend J (2013) A long-term Global LAnd Surface Satellite (GLASS) data-set for environmental studies. Int J Digit Earth 6:5–33
Loarie SR, Lobell DB, Asner GP, Mu Q, Field CB (2011) Direct impacts on local climate of sugar-cane expansion in Brazil. Nat Clim Change 1:105–109
Luyssaert S, Jammet M, Stoy PC, Estel S, Pongratz J, Ceschia E, Churkina G, Don A, Erb K, Ferlicoq M, Gielen B, Grünwald T, Houghton RA, Klumpp K, Knohl A, Kolb T, Kuemmerle T, Laurila T, Lohila A, Loustau D, McGrath MJ, Meyfroidt P, Moors EJ, Naudts K, Novick K, Otto J, Pilegaard K, Pio CA, Rambal S, Rebmann C, Ryder J, Suyker AE, Varlagin A, Wattenbach Dolman AJ (2014) Land management and land-cover change have impacts of similar magnitude on surface temperature. Nat Clim Change 4:389–393
Mallya G, Zhao L, Song XC, Niyogi D, Govindaraju RS (2013) 2012 Midwest drought in the United States. J Hydrol Eng 18:737–745
Matthews HD, Weaver AJ, Eby M, Meissner KJ (2003) Radiative forcing of climate by historical land cover change. Geophysical Res Lett. https://doi.org/10.1525/bio.2013.63.4.6
Merlin O (2013) An original interpretation of the wet edge of the surface temperature-albedo space to estimate crop evapotranspiration (SEB-1S), and its validation over an irrigated area in northwestern Mexico. Hydrol Earth Sysy Sci 17:3623–3637
Michigan State Climatologist’s Office (2013). Gull Lake (3504). Michigan State University. Retrieved from http://climate.geo.msu.edu/climate_mi/stations/3504/
Miller JN, VanLoocke A, Gomez-Casanovas N, Bernacchi CJ (2016) Candidate perennial bioenergy grasses have a higher albedo than annual row crops. Glob Change Biol Bioenergy 8:818–825
Mira M, Weiss M, Baret F, Courault D, Hagolle O, Gallego-Elvira B, Olioso A (2015) The MODIS (collection V006) BRDF/albedo product MCD43D: temporal course evaluated over agricultural landscape. Remote Sens Environ 170:216–228
Moustafa SE, Rennermalm AK, Román MO, Wang Z, Schaaf CB, Smith LC, Koenig LS, Erb A (2017) Evaluation of satellite remote sensing albedo retrievals over the ablation area of the southwestern Greenland ice sheet. Remote Sens Environ 198:115–125
Muñoz I, Campra P, Fernández-Alba AR (2010) Including CO2-emission equivalence of changes in land surface albedo in life cycle assessment. Methodology and case study on greenhouse agriculture. Int J Life Cycle Assess 15:672–681
Omernik JM, Griffith GE (2014) Ecoregions of the conterminous United States: evolution of a hierarchical spatial framework. Environ Manage 54:1249–1266
Peters GP, Aamaas B, Lund MT, Solli C, Fuglestvedt JS (2011) Alternative “global warming” metrics in life cycle assessment: a case study with existing transportation data. Environ Sci Technol 45:8633–8641
Picard G, Domine F, Krinner G, Arnaud L, Lefebvre E (2012) Inhibition of the positive snow-albedo feedback by precipitation in interior Antarctica. Nat Clim Change 2:795–798
Pielke RA, Pitman A, Niyogi D, Mahmood R, McAlpine C, Hossain F, Goldewijk KK, Nair U, Betts R, Fall S, Reichstein M, Kabat P, deNoblet N (2011) Land use/land cover changes and climate: modeling analysis and observational evidence. Wiley Interdiscip Rev Clim Change 2:828–850
Poeplau C, Don A (2015) Carbon sequestration in agricultural soils via cultivation of cover crops – a meta-analysis. Agric Ecosyst Environ 200:33–41
Raudsepp-Hearne C, Peterson GD, Tengö M, Bennett EM, Holland T, Benessaiah K, MacDonald GK, Pfeifer L (2010) Untangling the environmentalist’s paradox: why is human well-being increasing as ecosystem services degrade? Bioscience 60:576–589
Robertson GP, Hamilton SK, Barham BL, Dale BE, Izaurralde RC, Jackson RD, Landis DA, Swinton SM, Thelen KD, Tiedje JM (2017) Cellulosic biofuel contributions to a sustainable energy future: choices and outcomes. Science 356:1349
Robertson GP, Paul EA, Harwood RR (2000) Greenhouse gases in intensive agriculture: contributions of individual gases to the radiative forcing of the atmosphere. Science 289:1922–1925
Román MO, Schaaf CB, Woodcock CE, Strahler AH, Yang X, Braswell RH, Curtis PS, Davis KJ, Dragoni D, Goulden ML (2009) The MODIS (collection V005) BRDF/albedo product: assessment of spatial representativeness over forested landscapes. Remote Sens Environ 113:2476–2498
Schaetzl RJ, Darden JT, Brandt DS (2009) Michigan geography and geology. Pearson Learning Solutions
Seidl R, Spies TA, Peterson DL, Stephens SL, Hicke JA (2016) Searching for resilience: addressing the impacts of changing disturbance regimes on forest ecosystem services. J Appl Ecol 53:120–129
Shao C, Li L, Dong G, Chen J (2014) Spatial variation of net radiation and its contribution to energy balance closures in grassland ecosystems. Ecol Process 3:7
Smith P, Martino D, Cai Z, Gwary D, Janzen H, Kumar P, McCarl B, Ogle S, O’Mara F, Rice C, Scholes B, Sirotenko O, Howden M, McAllister T, Pan G, Romanenkov V, Schneider U, Towprayoon S, Wattenbach M, Smith J (2008) Greenhouse gas mitigation in agriculture. Philos Trans R So B: Biol Sci 363:789–813
Storelvmo T, Leirvik T, Lohmann U, Phillips PC, Wild M (2016) Disentangling greenhouse warming and aerosol cooling to reveal Earth’s climate sensitivity. Nat Geosci 9:286
Sun Q, Wang Z, Li Z, Erb A, Schaaf CB (2017) Evaluation of the global MODIS 30 arc-second spatially and temporally complete snow-free land surface albedo and reflectance anisotropy dataset. Int J Appl Earth Obs Geoinformation 58:36–49
Team RC (2017) R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. https://www.Rproject.org
Tian L, Chen J, Shao C (2018) Interdependent dynamics of LAI-albedo across the roofing landscapes: Mongolian and Tibetan Plateaus. Remote Sens 10:1159
Wang D, Liang S, He T, Yu Y, Schaaf C, Wang Z (2015) Estimating daily mean land surface albedo from MODIS data. J Geophys Res Atmos 120:4825–4841
Wang K, Liu J, Zhou X, Sparrow M, Ma M, Sun Z, Jiang W (2004) Validation of the MODIS global land surface albedo product using ground measurements in a semidesert region on the Tibetan Plateau. J Geophys Res Atmos 109:D05107
Wang Z, Crystal BS, Alan HS, Mark JC, Miguel OR, Yanmin S, Curtis EW, David YH, David RF (2014) Evaluation of MODIS Albedo Product (MCD43A) over grassland, agriculture and forest surface types during dormant and snow-covered periods. Remote Sens Environ 140:60–77
Yuan ZY, Chen HYH (2015) Decoupling of nitrogen and phosphorus in terrestrial plants associated with global changes. Nat Clim Change 5:465–469
Zhang Y, Wang X, Pan Y, Hu R (2013) Diurnal and seasonal variations of surface albedo in a spring wheat field of arid lands of Northwestern China. Int J Biometeorol 57:67–73
Zhao K, Jackson RB (2014) Biophysical forcings of land-use changes from potential forestry activities in North America. Ecol Monogr 84:329–353
Zheng L, Zhao G, Dong J, Ge Q, Tao J, Zhang X, Qi Y, Doughty RB, Xiao X (2019) Spatial, temporal, and spectral variations in albedo due to vegetation changes in China’s grasslands. ISPRS J Photogramm Remote Sens 152:1–12
Acknowledgements
This study was supported, in part, by the NASA Carbon Cycle & Ecosystems program (NNX17AE16G), the Great Lakes Bioenergy Research Center funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Numbers DE-SC0018409 and DE-FC02-07ER64494 and the Natural Science Foundation Long-term Ecological Research Program (DEB 1637653) at the Kellogg Biological Station, the NASA Science of Terra and Aqua program (NNX14AJ32G). We wish to thank Dr. Geoffrey Henebry for helpful suggestions and comments during the post-review process. We also thank the two anonymous reviewers who helped improving the quality of our manuscript.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Sciusco, P., Chen, J., Abraha, M. et al. Spatiotemporal variations of albedo in managed agricultural landscapes: inferences to global warming impacts (GWI). Landscape Ecol 35, 1385–1402 (2020). https://doi.org/10.1007/s10980-020-01022-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10980-020-01022-8