Capturing interactions between nitrogen and hydrological cycles under historical climate and land use: Susquehanna watershed analysis with the GFDL land model LM3-TAN

We developed a process model LM3-TAN to assess the combined effects of direct human influences and climate change on terrestrial and aquatic nitrogen (TAN) cycling. The model was developed by expanding NOAA's Geophysical Fluid Dynamics Laboratory land model LM3V-N of coupled terrestrial carbon and nitrogen (C-N) cycling and including new N cycling processes and inputs such as a soil denitrification, point N sources to streams (i.e., sewage), and stream transport and microbial processes. Because the model integrates ecological, hydrological, and biogeochemical processes, it captures key controls of the transport and fate of N in the vegetation–soil–river system in a comprehensive and consistent framework which is responsive to climatic variations and land-use changes. We applied the model at 1/8° resolution for a study of the Susquehanna River Basin. We simulated with LM3-TAN stream dissolved organic-N, ammonium-N, and nitrate-N loads throughout the river network, and we evaluated the modeled loads for 1986–2005 using data from 16 monitoring stations as well as a reported budget for the entire basin. By accounting for interannual hydrologic variability, the model was able to capture interannual variations of stream N loadings. While the model was calibrated with the stream N loads only at the last downstream Susquehanna River Basin Commission station Marietta (40°02' N, 76°32' W), it captured the N loads well at multiple locations within the basin with different climate regimes, land-use types, and associated N sources and transformations in the sub-basins. Furthermore, the calculated and previously reported N budgets agreed well at the level of the whole Susquehanna watershed. Here we illustrate how point and non-point N sources contributing to the various ecosystems are stored, lost, and exported via the river. Local analysis of six sub-basins showed combined effects of land use and climate on soil denitrification rates, with the highest rates in the Lower Susquehanna Sub-Basin (extensive agriculture; Atlantic coastal climate) and the lowest rates in the West Branch Susquehanna Sub-Basin (mostly forest; Great Lakes and Midwest climate). In the re-growing secondary forests, most of the N from non-point sources was stored in the vegetation and soil, but in the agricultural lands most N inputs were removed by soil denitrification, indicating that anthropogenic N applications could drive substantial increase of N 2 O emission, an intermediate of the denitrification process.

[1]  Elena Shevliakova,et al.  An Enhanced Model of Land Water and Energy for Global Hydrologic and Earth-System Studies , 2014 .

[2]  R. Q. Thomas,et al.  Insights into mechanisms governing forest carbon response to nitrogen deposition: A model–data comparison using observed responses to nitrogen addition , 2013 .

[3]  Ronald,et al.  GFDL’s ESM2 Global Coupled Climate–Carbon Earth System Models. Part I: Physical Formulation and Baseline Simulation Characteristics , 2012 .

[4]  Kevin H. McGonigal 2010 NUTRIENTS AND SUSPENDED SEDIMENT IN THE SUSQUEHANNA RIVER BASIN , 2011 .

[5]  S. Gerber,et al.  Nitrogen cycling and feedbacks in a global dynamic land model , 2010 .

[6]  K. Schilling,et al.  Modeling Nitrate-Nitrogen Load Reduction Strategies for the Des Moines River, Iowa Using SWAT , 2009, Environmental management.

[7]  George C. Hurtt,et al.  Carbon cycling under 300 years of land use change: Importance of the secondary vegetation sink , 2009 .

[8]  E. Stehfest,et al.  Global scale DAYCENT model analysis of greenhouse gas emissions and mitigation strategies for cropped soils , 2009 .

[9]  Mark B. David,et al.  Dynamic modeling of nitrogen losses in river networks unravels the coupled effects of hydrological and biogeochemical processes , 2009 .

[10]  Brian D. Smerdon,et al.  Review of hydrologic models for forest management and climate change applications in British Columbia and Alberta. , 2009 .

[11]  J. Galloway,et al.  Transformation of the Nitrogen Cycle: Recent Trends, Questions, and Potential Solutions , 2008, Science.

[12]  William H. McDowell,et al.  Stream denitrification across biomes and its response to anthropogenic nitrate loading , 2008, Nature.

[13]  Osvaldo E. Sala,et al.  Climate Change Impacts on , 2008 .

[14]  J. Hoffman THE 2008 SUSQUEHANNA RIVER BASIN WATER QUALITY ASSESSMENT REPORT , 2008 .

[15]  H. Paerl,et al.  Nitrogen deposition in U.S. coastal bays and estuaries , 2007 .

[16]  Peter E. Thornton,et al.  Influence of carbon‐nitrogen cycle coupling on land model response to CO2 fertilization and climate variability , 2007 .

[17]  C. Driscoll,et al.  Sulfur and Nitrogen Deposition on Ecosystems in the United States , 2007 .

[18]  M. Heinen Simplified denitrification models : Overview and properties , 2006 .

[19]  E. Wood,et al.  Development of a 50-Year High-Resolution Global Dataset of Meteorological Forcings for Land Surface Modeling , 2006 .

[20]  S. Malyshev,et al.  The underpinnings of land‐use history: three centuries of global gridded land‐use transitions, wood‐harvest activity, and resulting secondary lands , 2006 .

[21]  C. Goodale,et al.  The influence of climate on average nitrogen export from large watersheds in the Northeastern United States , 2006 .

[22]  R. Howarth,et al.  � 2006, by the American Society of Limnology and Oceanography, Inc. Eutrophication of freshwater and marine ecosystems , 2022 .

[23]  J. Lynch,et al.  Improved daily precipitation nitrate and ammonium concentration models for the Chesapeake Bay Watershed. , 2005, Environmental pollution.

[24]  Christina L. Tague,et al.  RHESSys: Regional Hydro-Ecologic Simulation System—An Object- Oriented Approach to Spatially Distributed Modeling of Carbon, Water, and Nutrient Cycling , 2004 .

[25]  G. Asner,et al.  Nitrogen Cycles: Past, Present, and Future , 2004 .

[26]  I. Schmidt,et al.  NITROGEN UPTAKE BY ARCTIC SOIL MICROBES AND PLANTS IN RELATION TO SOIL NITROGEN SUPPLY , 2004 .

[27]  James N. Galloway,et al.  Pre-industrial and contemporary fluxes of nitrogen through rivers: a global assessment based on typology , 2004 .

[28]  V. Smith Eutrophication of freshwater and coastal marine ecosystems a global problem , 2003, Environmental science and pollution research international.

[29]  E. W. Boyer,et al.  Where did all the nitrogen go? Fate of nitrogen inputs to large watersheds in the northeastern U.S.A. , 2002 .

[30]  Véronique Beaujouan,et al.  A nitrogen model for European catchments: INCA, new model structure and equations , 2002 .

[31]  Elizabeth W. Boyer,et al.  Nitrogen retention in rivers: model development and application to watersheds in the northeastern U.S.A. , 2002 .

[32]  Elizabeth W. Boyer,et al.  Anthropogenic nitrogen sources and relationships to riverine nitrogen export in the northeastern U.S.A. , 2002 .

[33]  John C. Field,et al.  Climate change impacts on U.S. Coastal and Marine Ecosystems , 2002 .

[34]  Lawrence E. Band,et al.  Forest ecosystem processes at the watershed scale: hydrological and ecological controls of nitrogen export , 2001 .

[35]  G. Asner,et al.  Dissolved Organic Carbon in Terrestrial Ecosystems: Synthesis and a Model , 2001, Ecosystems.

[36]  J. G. Kroes,et al.  ANIMO 3.5; user's guide for the ANIMO version 3.5 nutrient leaching model , 1998 .

[37]  Stephen W. Pacala,et al.  LINEAR ANALYSIS OF SOIL DECOMPOSITION: INSIGHTS FROM THE CENTURY MODEL , 1998 .

[38]  L. Joseph Bachman,et al.  Ground-water discharge and base-flow nitrate loads of nontidal streams, and their relation to a hydrogeomorphic classification of the Chesapeake Bay Watershed, middle Atlantic Coast , 1998 .

[39]  T. Sogn,et al.  Simulating effects of S and N deposition on soil water chemistry by the nutrient cycling model NuCM , 1997 .

[40]  F. Chapin,et al.  A model of nitrogen uptake by Eriophorum vaginatum roots in the field: Ecological implications , 1997 .

[41]  J. Houghton Climate change 1994 : radiative forcing of climate change and an evaluation of the IPCC IS92 emission scenarios , 1995 .

[42]  P. Crutzen,et al.  A three-dimensional model of the global ammonia cycle , 1994 .

[43]  J. Bril,et al.  Modelling N2O emission from (grazed) grassland , 1994 .

[44]  Robert J. Scholes,et al.  Observations and modeling of biomass and soil organic matter dynamics for the grassland biome worldwide , 1993 .

[45]  J. Stoddard,et al.  The Role of Nitrate in the Acidification of Streams in the Catskill Mountains of New York , 1992 .

[46]  D. Schindler,et al.  Acidification by nitric acid — Future considerations , 1990 .

[47]  Andrew N. Sharpley,et al.  EPIC, Erosion/Productivity Impact Calculator , 1990 .

[48]  John R. Williams,et al.  EPIC-erosion/productivity impact calculator: 1. Model documentation. , 1990 .

[49]  A. Henriksen,et al.  Increasing contributions of nitrogen to the acidity of surface waters in Norway , 1988 .

[50]  Lars Bergström,et al.  Simulated nitrogen dynamics and losses in a layered agricultural soil , 1987 .

[51]  L. B. Leopold,et al.  The hydraulic geometry of stream channels and some physiographic implications , 1953 .