TY - JOUR T1 - Ecological worldview, agricultural or natural resource-based activities, and geography affect perceived importance of ecosystem services JF - Landscape and Urban Planning Y1 - 2020 A1 - Wardropper, C.B. A1 - Mase, A.S. A1 - Qiu, J. A1 - Kohl, P. A1 - Booth, E.G. A1 - Rissman, A.R. KW - agriculture KW - ecosystem services KW - New Ecological Paradigm KW - Urban KW - Water AB - Understanding public perceptions of the importance of ecosystem services (ES) is crucial for the development and communication of sustainable management and policies. Yet public perspectives on ES and their sociocultural and geographic patterns are not well understood. This study asks: Which ES are perceived as more or less important by the general public?; Which ES are considered most similar when the public are asked to evaluate the importance of specific water, agricultural and natural resources ES?; And, what individual and geographic factors are associated with perceived importance of different ES? We conducted a survey of residents in an urban and agricultural watershed in the U.S. Upper Midwest (n = 1136). This study asked respondents about a wider range of ES than is typical, and examines how ecological worldviews influence the perceived importance of ES. Respondents rated regional provision of drinking and surface water quality, clean lakes and rivers for wildlife, and a reliable supply of drinking and surface water most important. Those with a stronger ecological worldview tended to rate natural areas and processes as more important and agricultural products as less important than respondents with a more anthropocentric worldview. Perceived importance of various ES was also predicted by other individual-level factors relating to livelihood, outdoor recreation, and proximity to lakes, forests and agriculture. For example, respondents with livelihoods dependent on agriculture rated agricultural products and rural character highly. These findings bolster the case for more context-specific assessments of public importance ratings for environmental benefits to inform planning and management. VL - 197 SN - 0169-2046 UR - http://www.sciencedirect.com/science/article/pii/S0169204619305869 JO - Landscape and Urban Planning ER - TY - JOUR T1 - Comparing the effects of climate and land use on surface water quality using future watershed scenarios JF - Science of the Total Environment Y1 - 2019 A1 - Motew, Melissa A1 - Chen, Xi A1 - Carpenter, Stephen R. A1 - Booth, Eric G. A1 - Seifert, Jenny A1 - Qiu, Jiangxiao A1 - Loheide, Steven P. A1 - Turner, Monica G. A1 - Zipper, Samuel C. A1 - Kucharik, Christopher J. KW - climate KW - land use KW - Manure KW - phosphorus KW - Surface water quality KW - Watershed AB - Eutrophication of freshwaters occurs in watersheds with excessive pollution of phosphorus (P). Factors that affect P cycling and transport, including climate and land use, are changing rapidly and can have legacy effects, making future freshwater quality uncertain. Focusing on the Yahara Watershed (YW) of southern Wisconsin, USA, an intensive agricultural landscape, we explored the relative influence of land use and climate on three indicators of water quality over a span of 57 years (2014–2070). The indicators included watershed-averaged P yield from the land surface, direct drainage P loads to a lake, and average summertime lake P concentration. Using biophysical model simulations of future watershed scenarios, we found that climate exerted a stronger influence than land use on all three indicators, yet land use had an important role in influencing long term outcomes for each. Variations in P yield due to land use exceeded those due to climate in 36 of 57 years, whereas variations in load and lake total P concentration due to climate exceeded those due to land use in 54 of 57 years, and 52 of 57 years, respectively. The effect of land use was thus strongest for P yield off the landscape and attenuated in the stream and lake aquatic systems where the influence of weather variability was greater. Overall these findings underscore the dominant role of climate in driving inter-annual nutrient fluxes within the hydrologic network and suggest a challenge for land use to influence water quality within streams and lakes over timescales less than a decade. Over longer timescales, reducing applications of P throughout the watershed was an effective management strategy under all four climates investigated, even during decades with wetter conditions and more frequent extreme precipitation events. VL - 693 SN - 0048-9697 UR - http://www.sciencedirect.com/science/article/pii/S0048969719334047 ER - TY - JOUR T1 - Management of minimum lake levels and impacts on flood mitigation: A case study of the Yahara Watershed, Wisconsin, USA JF - Journal of Hydrology Y1 - 2019 A1 - Chen, Xi A1 - Motew, Melissa M. A1 - Booth, Eric G. A1 - Zipper, Samuel C. A1 - Loheide, Steven P. A1 - Kucharik, Christopher J. KW - ecosystem services KW - Flood exposure assessment KW - Hydrologic model KW - Lake level management AB - Lake level regulation is commonly used to manage water resources and mitigate flood risk in watersheds with linked river–lake systems. In this study, we first assess exposure, in terms of both population and land area, to flooding impacts in the Yahara Watershed’s chain of four lakes in southern Wisconsin as affected by minimum lake level management. A flooding exposure assessment shows that the areas surrounding the upstream lakes, Mendota and Monona, have dense urban areas with high populations that are exposed to flooding; Waubesa has low elevations along its lakeshore, resulting in a large potential flooding area; and the most downstream lake, Kegonsa, has a large area of surrounding cropland that is exposed to flooding but impacts a limited population. We then use a linked modeling framework of a land surface model (Agro-IBIS) and a hydrologic-routing model (THMB) to simulate daily lake level over a study period of 1994–2013 in the Yahara Watershed with different minimum lake level management strategies. Modeling results show that the peak lake levels and corresponding exposed land area and population to flooding will decrease under a lower target minimum lake level. However, at the same time, the number of days that the lake level is below winter minimum will increase, which may adversely affect ecosystem health. In addition, our sensitivity analysis indicates that reducing target minimum lake levels will help mitigate flood risk in terms of both flood magnitude and frequency. Nevertheless, this must be balanced against the need to maintain adequately high lake levels for ecosystem services and recreational functions of the lakes. VL - 577 SN - 0022-1694 UR - http://www.sciencedirect.com/science/article/pii/S0022169419306407 JO - Journal of Hydrology ER - TY - JOUR T1 - Nonlinear groundwater influence on biophysical indicators of ecosystem services JF - Nature Sustainability Y1 - 2019 A1 - Qiu, Jiangxiao A1 - Zipper, Samuel C. A1 - Motew, Melissa A1 - Booth, Eric G. A1 - Kucharik, Christopher J. A1 - Loheide, Steven P. AB - Groundwater is a fundamental control on biophysical processes underpinning essential ecosystem services (ES). However, interactions and feedbacks among groundwater, climate and multiple ES remain less well understood. We investigated groundwater effects on a portfolio of food, water and biogeochemical ES indicators in an urbanizing agricultural watershed. Our results show that food production, water quality and quantity, and flood control are most sensitive to groundwater, with the strongest responses under wet and dry climate extremes. Climate mediates groundwater effects, such that several ES have synergies during dry climate, but trade-offs (groundwater increased some ES but declined others) under wet climate. There is substantial spatial heterogeneity in groundwater effects on ES, which is driven primarily by water table depth (WTD) and is also sensitive to soil texture and land cover. Most ES indicators respond nonlinearly to WTD when groundwater is within a critical depth (approximately 2.5 m) of land surface, indicating that small WTD changes can have disproportionately large effects on ES in shallow groundwater areas. Within this critical WTD, increasingly shallow groundwater leads to nonlinear increases in surface flood risk, sediment erosion and phosphorus yield; nonlinear decreases in drainage to the deep vadose zone and thus groundwater recharge; and bidirectional responses of crop and grass production, carbon storage and nitrate leaching. Our study illustrates the complex role of groundwater in affecting multiple ES and highlights that strategically managing groundwater may enhance ES resilience to climate extremes in shallow groundwater settings. SN - 2398-9629 UR - https://doi.org/10.1038/s41893-019-0278-2 JO - Nature Sustainability ER - TY - JOUR T1 - Continuous separation of land use and climate effects on the past and future water balance JF - Journal of Hydrology Y1 - 2018 A1 - Zipper, Samuel C. A1 - Motew, Melissa A1 - Booth, Eric G. A1 - Chen, Xi A1 - Qiu, Jiangxiao A1 - Kucharik, Christopher J. A1 - Carpenter, Stephen R. A1 - Loheide II, Steven P. KW - Baseflow KW - Climate change KW - Evapotranspiration KW - Land use change KW - Streamflow KW - Urbanization AB - Understanding the combined and separate effects of climate and land use change on the water cycle is necessary to mitigate negative impacts. However, existing methodologies typically divide data into discrete (before and after) periods, implicitly representing climate and land use as step changes when in reality these changes are often gradual. Here, we introduce a new regression-based methodological framework designed to separate climate and land use effects on any hydrological flux of interest continuously through time, and estimate uncertainty in the contribution of these two drivers. We present two applications in the Yahara River Watershed (Wisconsin, USA) demonstrating how our approach can be used to understand synergistic or antagonistic relationships between land use and climate in either the past or the future: (1) historical streamflow, baseflow, and quickflow in an urbanizing subwatershed; and (2) simulated future evapotranspiration, drainage, and direct runoff from a suite of contrasting climate and land use scenarios for the entire watershed. In the historical analysis, we show that ∼60% of recent streamflow changes can be attributed to climate, with approximately equal contributions from quickflow and baseflow. However, our continuous method reveals that baseflow is significantly increasing through time, primarily due to land use change and potentially influenced by long-term increases in groundwater storage. In the simulation of future changes, we show that all components of the future water balance will respond more strongly to changes in climate than land use, with the largest potential land use effects on drainage. These results indicate that diverse land use change trajectories may counteract each other while the effects of climate are more homogeneous at watershed scales. Therefore, management opportunities to counteract climate change effects will likely be more effective at smaller spatial scales, where land use trajectories are unidirectional. VL - 565 UR - http://www.sciencedirect.com/science/article/pii/S0022169418306188 ER - TY - JOUR T1 - The synergistic effect of manure supply and extreme precipitation on surface water quality JF - Environmental Research Letters Y1 - 2018 A1 - Melissa Motew A1 - Eric G. Booth A1 - Stephen R. Carpenter A1 - Xi Chen A1 - Christopher J. Kucharik AB - Over-enrichment of phosphorus (P) in agroecosystems contributes to eutrophication of surface waters. In the Midwest U.S. and elsewhere, climate change is increasing the frequency of high-intensity precipitation events, which can serve as a primary conduit of P transport. Despite uncertainty in their estimates, process-based watershed models are important tools that help characterize watershed hydrology and biogeochemistry and scale up important mechanisms affecting water quality. Using one such model developed for an agricultural watershed in Wisconsin, we conducted a 2x2 factorial experiment to test the effects of (high/low) terrestrial P supply (PSUP) and (high/low) precipitation intensity (PREC) on surface water quality. Sixty-year simulations were conducted for each of the four runs, with annual results obtained for watershed average P yield and concentration at the field scale (220m x 220m grid cells), P load and concentration at the stream scale, and summertime total P concentration (TP) in Lake Mendota. ANOVA results were generated for the 2x2 factorial design, with PSUP and PREC treated as categorical variables. The results showed a significant, positive interaction (p<0.01) between the two drivers for dissolved P concentration at the field and stream scales, and total P concentration at the field, stream, and lake scales. The synergy in dissolved P was linked to nonlinear dependencies between P stored in manure and the daily runoff to rainfall ratio. The synergistic response of dissolved P loss may have important ecological consequences because dissolved P is highly bioavailable. Overall, the results suggest that high levels of terrestrial P supplied as manure can exacerbate water quality problems in the future as the frequency of high-intensity rainfall events increases with a changing climate. Conversely, lowering terrestrial manure P supply may help improve the resilience of surface water quality to extreme events. SN - 1748-9326 UR - http://iopscience.iop.org/10.1088/1748-9326/aaade6 ER - TY - JOUR T1 - Extreme precipitation and phosphorus loads from two agricultural watersheds JF - Limnology and Oceanography Y1 - 2017 A1 - Carpenter, Stephen R. A1 - Booth, Eric G. A1 - Kucharik, Christopher J. AB - Phosphorus runoff from agricultural land is a major cause of eutrophication in lakes and reservoirs. Frequency and intensity of extreme precipitation events are increasing in agricultural regions of the Upper Midwestern U.S., and these increases are projected to continue as climate warms. We quantified the linkage between extreme daily precipitation and extreme daily discharge, phosphorus (P) load, and P concentration for Pheasant Branch and the Yahara River, two tributaries of Lake Mendota, Wisconsin, U.S.A. using the generalized Pareto distribution. Although precipitation extremes have increased since 1940, over the shorter period of stream monitoring (1994–2015 for Pheasant Branch and 1991–2015 for Yahara) there is no significant trend in extreme precipitation. Nonetheless a disproportionate number of extreme precipitation events (for example seven of the 11 largest 24-h events since 1901) occurred during the period of stream monitoring. Daily precipitation extremes were associated with extremes in daily discharge and P load. P load return levels increased steeply and almost linearly with precipitation on log-log axes. The trend toward more frequent and intense precipitation extremes will increase P loading and intensify the eutrophication of the lake, unless the excessive P enrichment of the watershed is reversed. SN - 1939-5590 UR - http://dx.doi.org/10.1002/lno.10767 ER - TY - JOUR T1 - The Influence of Legacy P on Lake Water Quality in a Midwestern Agricultural Watershed JF - Ecosystems Y1 - 2017 A1 - Motew, Melissa A1 - Chen, Xi A1 - Booth, Eric G. A1 - Carpenter, Stephen R. A1 - Pinkas, Pavel A1 - Zipper, Samuel C. A1 - Loheide, Steven P. A1 - Donner, Simon D. A1 - Tsuruta, Kai A1 - Vadas, Peter A. A1 - Kucharik, Christopher J. AB - Decades of fertilizer and manure applications have led to a buildup of phosphorus (P) in agricultural soils and sediments, commonly referred to as legacy P. Legacy P can provide a long-term source of P to surface waters where it causes eutrophication. Using a suite of numerical models, we investigated the influence of legacy P on water quality in the Yahara Watershed of southern Wisconsin, USA. The suite included Agro-IBIS, a terrestrial ecosystem model; THMB, a hydrologic and nutrient routing model; and the Yahara Water Quality Model which estimates water quality indicators in the Yahara chain of lakes. Using five alternative scenarios of antecedent P storage (legacy P) in soils and channels under historical climate conditions, we simulated outcomes of P yield from the landscape, lake P loading, and three lake water quality indicators. Legacy P had a significant effect on lake loads and water quality. Across the five scenarios for Lake Mendota, the largest and most upstream lake, average P yield (kg ha−1) varied by −41 to +22%, P load (kg y−1) by −35 to +14%, summer total P (TP) concentration (mg l−1) by −25 to +12%, Secchi depth (m) by −7 to +3%, and the probability of hypereutrophy by −67 to +34%, relative to baseline conditions. The minimum storage scenario showed that a 35% reduction in present-day loads to Lake Mendota corresponded with a 25% reduction in summer TP and smaller reductions in the downstream lakes. Water quality was more vulnerable to heavy rainfall events at higher amounts of P storage and less so at lower amounts. Increases in heavy precipitation are expected with climate change; therefore, water quality could be protected by decreasing P reserves. SN - 1435-0629 UR - http://dx.doi.org/10.1007/s10021-017-0125-0 JO - Ecosystems ER - TY - JOUR T1 - Alternative scenarios of bioenergy crop production in an agricultural landscape and implications for bird communities JF - Ecological Applications Y1 - 2016 A1 - Blank, Peter J. A1 - Williams, Carol L. A1 - Sample, David W. A1 - Meehan, Timothy D. A1 - Turner, Monica G. KW - bioenergy crops KW - grass biomass KW - grassland birds KW - land-use change KW - landscape scenarios KW - row-crop agriculture KW - species of greatest conservation need AB - Increased demand and government mandates for bioenergy crops in the United States could require a large allocation of agricultural land to bioenergy feedstock production and substantially alter current landscape patterns. Incorporating bioenergy landscape design into land-use decision making could help maximize benefits and minimize trade-offs among alternative land uses. We developed spatially explicit landscape scenarios of increased bioenergy crop production in an 80-km radius agricultural landscape centered on a potential biomass-processing energy facility and evaluated the consequences of each scenario for bird communities. Our scenarios included conversion of existing annual row crops to perennial bioenergy grasslands and conversion of existing grasslands to annual bioenergy row crops. The scenarios explored combinations of four biomass crop types (three potential grassland crops along a gradient of plant diversity and one annual row crop [corn]), three land conversion percentages to bioenergy crops (10%, 20%, or 30% of row crops or grasslands), and three spatial configurations of biomass crop fields (random, clustered near similar field types, or centered on the processing plant), yielding 36 scenarios. For each scenario, we predicted the impact on four bird community metrics: species richness, total bird density, species of greatest conservation need (SGCN) density, and SGCN hotspots (SGCN birds/ha ≥ 2). Bird community metrics consistently increased with conversion of row crops to bioenergy grasslands and consistently decreased with conversion of grasslands to bioenergy row crops. Spatial arrangement of bioenergy fields had strong effects on the bird community and in some cases was more influential than the amount converted to bioenergy crops. Clustering grasslands had a stronger positive influence on the bird community than locating grasslands near the central plant or at random. Expansion of bioenergy grasslands onto marginal agricultural lands will likely benefit grassland bird populations, and bioenergy landscapes could be designed to maximize biodiversity benefits while meeting targets for biomass production. VL - 26 SN - 1939-5582 UR - http://dx.doi.org/10.1890/14-1490 IS - 1 ER - TY - JOUR T1 - From qualitative to quantitative environmental scenarios: Translating storylines into biophysical modeling inputs at the watershed scale JF - Environmental Modelling & Software Y1 - 2016 A1 - Booth, Eric G. A1 - Qiu, Jiangxiao A1 - Carpenter, Stephen R. A1 - Schatz, Jason A1 - Chen, Xi A1 - Kucharik, Christopher J. A1 - Loheide II, Steven P. A1 - Motew, Melissa M. A1 - Seifert, Jenny M. A1 - Turner, Monica G. KW - Biophysical modeling KW - Climate change KW - Land use change KW - scenarios KW - Social-ecological systems KW - Watershed AB - Scenarios are increasingly used for envisioning future social-ecological changes and consequences for human well-being. One approach integrates qualitative storylines and biophysical models to explore potential futures quantitatively and maximize public engagement. However, this integration process is challenging and sometimes oversimplified. Using the Yahara Watershed (Wisconsin, USA) as a case study, we present a transparent and reproducible roadmap to develop spatiotemporally explicit biophysical inputs [climate, land use/cover (LULC), and nutrients] that are consistent with scenario narratives and can be linked to a process-based biophysical modeling suite to simulate long-term dynamics of a watershed and a range of ecosystem services. Our transferrable approach produces daily weather inputs by combining climate model projections and a stochastic weather generator, annual narrative-based watershed-scale LULC distributed spatially using transition rules, and annual manure and fertilizer (nitrogen and phosphorus) inputs based on current farm and livestock data that are consistent with each scenario narrative. VL - 85 SN - 1364-8152 UR - http://www.sciencedirect.com/science/article/pii/S1364815216304935 JO - Environmental Modelling & Software ER - TY - JOUR T1 - Is groundwater recharge always serving us well? Water supply provisioning, crop production, and flood attenuation in conflict in Wisconsin, USA JF - Ecosystem Services Y1 - 2016 A1 - Booth, Eric G. A1 - Zipper, Samuel C. A1 - Loheide II, Steven P. A1 - Kucharik, Christopher J. KW - Crop production KW - Flooding KW - Groundwater KW - Hydrologic services KW - Recharge KW - Water supply AB - Ecosystem service mapping can provide an avenue for making effective land management decisions in a holistic way. However, mapped quantities do not always appropriately represent the ecosystem services that are used by humans. We highlight this issue with a case study of groundwater recharge, water supply, flooding, and agricultural production in an urbanizing agricultural watershed in southern Wisconsin, USA. Groundwater recharge is typically treated as a beneficial ecosystem service or service indicator whose value to humans monotonically increases with the amount of recharge. While appropriate from a water supply perspective, this relationship breaks down when excess groundwater recharge leads to flooding and crop damage. We suggest moving beyond groundwater recharge as a stand-alone ecosystem service, and instead propose that observations and biophysical models should be used to quantify the final service humans receive from groundwater (e.g. reliability of water supply from a municipal well). Integration of such derived, point-based metrics with other ecosystem services that are more easily represented at the landscape scale remains a challenge for regional ecosystem service inventories and analyses. VL - 21, Part A SN - 2212-0416 UR - http://www.sciencedirect.com/science/article/pii/S2212041616302315 JO - Ecosystem Services ER - TY - JOUR T1 - Shifting drivers and static baselines in environmental governance: challenges for improving and proving water quality outcomes JF - Regional Environmental Change Y1 - 2016 A1 - Gillon, Sean A1 - Booth, Eric G. A1 - Rissman, Adena R. KW - Agricultural intensification KW - Climate change KW - Environmental governance KW - Land use change KW - Shifting drivers KW - Water quality AB - Understanding the conditions that enable or constrain success in environmental governance is crucial for developing effective interventions and adapting approaches. Efforts to achieve and assess success in environmental quality improvement are often impeded by changes in conditions that drive outcomes but lie outside the scope of intervention and monitoring. We document how long-term changes in land use, agriculture, and climate act as non-stationary, shifting drivers of change that combine to render water quality management interventions less effective and increasingly difficult to assess. Focusing on the Yahara River watershed of south-central Wisconsin, USA, we ask how baselines influence program modeling, monitoring, and evaluation, as well as adaptation in governance approach. Through historical trend, GIS, and policy and qualitative data analyses, we find that changes in long-term land use and precipitation pattern dynamics exert tremendous pressure on water quality outcomes but are not captured in snapshot baseline assessments used in management planning or evaluation. Specifically, agricultural sector change related to the intensification of milk and manure production is increasingly challenging to address through best management practices, and flashier precipitation associated with climate change makes it difficult to achieve goals and establish a causal connection between management interventions and outcomes. Analysis of shifting drivers demonstrates challenges facing environmental governance in the context of climatic and social–ecological change. We suggest that goal setting, program design, and evaluation incorporate new modes of analysis that address slowly changing and external determinants of success. VL - 16 SN - 1436-3798 UR - http://dx.doi.org/10.1007/s10113-015-0787-0 IS - 3 JO - Reg Environ Change ER - TY - JOUR T1 - Creating a safe operating space for iconic ecosystems JF - Science Y1 - 2015 A1 - Scheffer, M. A1 - Barrett, S. A1 - Carpenter, S. R. A1 - Folke, C. A1 - Green, A. J. A1 - Holmgren, M. A1 - Hughes, T. P. A1 - Kosten, S. A1 - van de Leemput, I. A. A1 - Nepstad, D. C. A1 - van Nes, E. H. A1 - Peeters, E. T. H. M. A1 - Walker, B. VL - 347 UR - http://www.sciencemag.org/content/347/6228/1317.short IS - 6228 JO - Science ER - TY - JOUR T1 - Planetary boundaries: Guiding human development on a changing planet JF - Science Y1 - 2015 A1 - Steffen, Will A1 - Richardson, Katherine A1 - Rockström, Johan A1 - Cornell, Sarah E. A1 - Fetzer, Ingo A1 - Bennett, Elena M. A1 - Biggs, Reinette A1 - Carpenter, Stephen R. A1 - de Vries, Wim A1 - de Wit, Cynthia A. A1 - Folke, Carl A1 - Gerten, Dieter A1 - Heinke, Jens A1 - Mace, Georgina M. A1 - Persson, Linn M. A1 - Ramanathan, Veerabhadran A1 - Reyers, Belinda A1 - Sörlin, Sverker AB - The planetary boundaries framework defines a safe operating space for humanity based on the intrinsic biophysical processes that regulate the stability of the Earth system. Here, we revise and update the planetary boundary framework, with a focus on the underpinning biophysical science, based on targeted input from expert research communities and on more general scientific advances over the past 5 years. Several of the boundaries now have a two-tier approach, reflecting the importance of cross-scale interactions and the regional-level heterogeneity of the processes that underpin the boundaries. Two core boundaries—climate change and biosphere integrity—have been identified, each of which has the potential on its own to drive the Earth system into a new state should they be substantially and persistently transgressed. VL - 347 UR - http://www.sciencemag.org/content/347/6223/1259855.abstract IS - 6223 JO - Science ER - TY - JOUR T1 - Plausible futures of a social-ecological system: Yahara watershed, Wisconsin, USA JF - Ecology and Society Y1 - 2015 A1 - Carpenter, Stephen R. A1 - Booth, Eric G. A1 - Gillon, Sean A1 - Kucharik, Christopher J. A1 - Loheide, Steven A1 - Mase, Amber S. A1 - Motew, Melissa A1 - Qiu, Jiangxiao A1 - Rissman, Adena R. A1 - Seifert, Jenny A1 - Soylu, Evren A1 - Turner, Monica A1 - Wardropper, Chloe B. KW - alternative futures KW - climate KW - ecosystem services KW - eutrophication KW - governance KW - lakes KW - land-use change KW - phosphorus KW - scenarios AB - Agricultural watersheds are affected by changes in climate, land use, agricultural practices, and human demand for energy, food, and water resources. In this context, we analyzed the agricultural, urbanizing Yahara watershed (size: 1345 km², population: 372,000) to assess its responses to multiple changing drivers. We measured recent trends in land use/cover and water quality of the watershed, spatial patterns of 10 ecosystem services, and spatial patterns and nestedness of governance. We developed scenarios for the future of the Yahara watershed by integrating trends and events from the global scenarios literature, perspectives of stakeholders, and models of biophysical drivers and ecosystem services. Four qualitative scenarios were created to explore plausible trajectories to the year 2070 in the watershed’s social-ecological system under different regimes: no action on environmental trends, accelerated technological development, strong intervention by government, and shifting values toward sustainability. Quantitative time-series for 2010–2070 were developed for weather and land use/cover during each scenario as inputs to model changes in ecosystem services. Ultimately, our goal is to understand how changes in the social-ecological system of the Yahara watershed, including management of land and water resources, can build or impair resilience to shifting drivers, including climate. VL - 20 UR - http://www.ecologyandsociety.org/vol20/iss2/art10/ IS - 2 JO - Ecology and Society ER - TY - JOUR T1 - Untangling the effects of shallow groundwater and soil texture as drivers of subfield-scale yield variability JF - Water Resources Research Y1 - 2015 A1 - Zipper, Samuel C. A1 - Soylu, Mehmet Evren A1 - Booth, Eric G. A1 - Loheide, Steven P. KW - 0402 Agricultural systems KW - 0486 Soils/pedology KW - 1813 Eco-hydrology KW - 1829 Groundwater hydrology KW - agroecosystem modeling KW - AgroIBIS-VSF KW - Hydrus-1D KW - Precision agriculture KW - soil-plant-atmosphere continuum KW - water table AB - Water table depth (WTD), soil texture, and growing season weather conditions all play critical roles in determining agricultural yield; however, the interactions among these three variables have never been explored in a systematic way. Using a combination of field observations and biophysical modeling, we answer two questions: (1) under what conditions can a shallow water table provide a groundwater yield subsidy and/or penalty to corn production?; and, (2) how do soil texture and growing season weather conditions influence the relationship between WTD and corn yield? Subfield-scale yield patterns during a dry (2012) and wet (2013) growing season are used to identify sensitivity to weather. Areas of the field that are negatively impacted by wet growing seasons have the shallowest observed WTD (< 1 m), while areas with consistently strong yield have intermediate WTD (1-3 m). Parts of the field that perform consistently poorly are characterized by deep WTD (> 3 m) and coarse soil textures. Modeling results find that beneficial impacts of shallow groundwater are more common than negative impacts under the conditions studied, and that the optimum WTD is shallower in coarser soils. While groundwater yield subsidies have a higher frequency and magnitude in coarse-grained soils, the optimum WTD responds to growing season weather at a relatively constant rate across soil types. We conclude that soil texture defines a baseline upon which WTD and weather interact to determine overall yield. Our work has implications for water resource management, climate/land use change impacts on agricultural production, and precision agriculture. This article is protected by copyright. All rights reserved. SN - 1944-7973 UR - http://dx.doi.org/10.1002/2015WR017522 ER - TY - JOUR T1 - Extreme daily loads: role in annual phosphorus input to a north temperate lake JF - Aquatic Sciences Y1 - 2014 A1 - Carpenter, Stephen R A1 - Booth, Eric G A1 - Kucharik, Christopher J A1 - Lathrop, Richard C KW - Daily load extremes KW - Lake KW - Phosphorus load KW - Water quality AB - Changes in fertilizer use, manure management or precipitation may alter the frequency of episodes of high nutrient runoff and thereby affect annual nutrient loads and total nutrient concentrations of lakes. We developed an empirical, stochastic model for daily P loads and used the model to project annual P loads and summer total P concentrations in Lake Mendota, Wisconsin, USA. Daily P loads (8,250 daily observations) were fit closely by a three-part gamma distribution composed of days with low, intermediate, and high P loads. High P load days happen when heavy rains or snowmelt occur on soil with abundant P, often as a result of manure or inorganic fertilizer application. In Lake Mendota, on average 29 days per year accounted for 74 % of the annual load. Simulations showed that median annual P loads increased linearly with the frequency of high P load days. However, the upper quantiles of the annual P load distribution increased more steeply than the median. Increases in the number of high P load days per year also increased summer concentrations of P in the lake. Thus increases in the frequency of high P load days due to larger precipitation events or increased application of fertilizers and manure may worsen widespread problems caused by P pollution of lakes in this agricultural watershed. SN - 1015-1621 UR - http://dx.doi.org/10.1007/s00027-014-0364-5 JO - Aquat Sci ER - TY - JOUR T1 - Regime Shift in Fertilizer Commodities Indicates More Turbulence Ahead for Food Security JF - PLOS One Y1 - 2014 A1 - Elser, J. J. A1 - Elser, T. J. A1 - Carpenter, S. R. A1 - Brock, W. A. AB - Recent human population increase has been enabled by a massive expansion of global agricultural production. A key component of this "Green Revolution'' has been application of inorganic fertilizers to produce and maintain high crop yields. However, the long-term sustainability of these practices is unclear given the eutrophying effects of fertilizer runoff as well as the reliance of fertilizer production on finite non-renewable resources such as mined phosphate-and potassium-bearing rocks. Indeed, recent volatility in food and agricultural commodity prices, especially phosphate fertilizer, has raised concerns about emerging constraints on fertilizer production with consequences for its affordability in the developing world. We examined 30 years of monthly prices of fertilizer commodities (phosphate rock, urea, and potassium) for comparison with three food commodities (maize, wheat, and rice) and three non-agricultural commodities (gold, nickel, and petroleum). Here we show that all commodity prices, except gold, had significant change points between 2007-2009, but the fertilizer commodities, and especially phosphate rock, showed multiple symptoms of nonlinear critical transitions. In contrast to fertilizers and to rice, maize and wheat prices did not show significant signs of nonlinear dynamics. From these results we infer a recent emergence of a scarcity price in global fertilizer markets, a result signaling a new high price regime for these essential agricultural inputs. Such a regime will challenge on-going efforts to establish global food security but may also prompt fertilizer use practices and nutrient recovery strategies that reduce eutrophication. VL - 9 SN - 1932-6203 UR - http://dx.doi.org/10.1371/journal.pone.0093998 IS - 5 ER - TY - JOUR T1 - Soil Moisture Regime and Land Use History Drive Regional Differences in Soil Carbon and Nitrogen Storage Across Southern Wisconsin JF - Soil Science Y1 - 2013 A1 - Kucharik, C. J. A1 - Brye, K. R. AB - Agricultural land management can decrease soil organic carbon (SOC) and nitrogen (N) storage and adversely affect soil structure, but the actual impact can be confounded by the soil moisture regime. Wet or poorly drained soils tend to slow the process of organic matter oxidation and promote C storage, whereas comparatively drier or well-drained soils tend to promote organic matter turnover and C release. Therefore, the effects of land management, time since last disturbance, and soil moisture regime on near-surface soil bulk density (BD), SOC and total N (TN), and soil C:N ratios were evaluated across southern Wisconsin using a database generated during a 7-year period. Soil samples from the top 25 cm were collected from 169 sites consisting of prairie restorations and remnant prairies, Conservation Reserve Program land, agriculture (row crops and pasture), wetlands, and forests. Across all sites, soils with a udic soil moisture regime had lower (35%) native SOC, lower (31%) TN, greater (47%) BD, and lower (5.4%) soil C:N ratio than those with an aquic moisture regime. Agricultural (6.0 kg m(-2)) and restoration (5.8 kg m(-2)) sites had 30 and 32.3%, respectively, less SOC than native sites on udic soils, but agricultural (9.0 kg m(-2)) and restoration (8.8 kg m(-2)) sites with an aquic moisture regime shared similar SOC values with native sites under both udic (8.6 kg m(-2)) and aquic (10.6 kg m(-2)) moisture regimes. A 24.8% loss of native SOC attributed to agricultural land management occurred on aquic soils compared with a 33.6% loss on udic soils, and those effects were still present in prairie restorations. An apparent buffering capacity of wetter aquic soils on losses of C and N needs to be considered in quantifying soil C and N sequestration potential. VL - 178 UR - http://dx.doi.org/10.1097/ss.0000000000000015 IS - 9 ER - TY - JOUR T1 - What is the influence on water quality in temperate eutrophic lakes of a reduction of planktivorous and benthivorous fish? A systematic review protocol JF - Environmental Evidence Y1 - 2013 A1 - Bernes, C. A1 - Carpenter, S. R. A1 - Gardmark, A. A1 - Larsson, P. A1 - Persson, L. A1 - Skov, C. A1 - Van Donk, E. AB - BACKGROUND:In lakes that have become eutrophic due to sewage discharges or nutrient runoff from land, problems such as algal blooms and oxygen deficiency often persist even when nutrient supplies have been reduced. One reason is that phosphorus stored in the sediments can exchange with the water. There are indications that the high abundance of phytoplankton, turbid water and lack of submerged vegetation seen in many eutrophic lakes may represent a semi-stable state. For that reason, a shift back to more natural clear-water conditions could be difficult to achieve.In some cases, though, temporary mitigation of eutrophication-related problems has been accomplished through biomanipulation: stocks of zooplanktivorous fish have been reduced by intensive fishing, leading to increased populations of phytoplankton-feeding zooplankton. Moreover, reduction of benthivorous fish may result in lower phosphorus fluxes from the sediments. An alternative to reducing the dominance of planktivores and benthivores by fishing is to stock lakes with piscivorous fish. These two approaches have often been used in combination.The implementation of the EU Water Framework Directive has recently led to more stringent demands for measures against eutrophication, and a systematic review could clarify whether biomanipulation is efficient as a measure of that kind.METHODS:The review will examine primary field studies of how large-scale biomanipulation has affected water quality and community structure in eutrophic lakes or reservoirs in temperate regions. Such studies can be based on comparison between conditions before and after manipulation, on comparison between treated and non-treated water bodies, or both. Relevant outcomes include Secchi depth, concentrations of oxygen, nutrients, suspended solids and chlorophyll, abundance and composition of phytoplankton, zooplankton and fish, and coverage of submerged macrophytes. VL - 2 UR - http://www.environmentalevidencejournal.org/content/2/1/9 IS - 1 ER - TY - JOUR T1 - Embodied phosphorus and the global connections of United States agriculture JF - Environmental Research Letters Y1 - 2012 A1 - Graham K MacDonald A1 - Elena M Bennett A1 - Stephen R Carpenter AB - Agricultural phosphorus (P) use is intricately linked to food security and water quality.Globalization of agricultural systems and changing diets clearly alter these relationships, yettheir specific influence on non-renewable P reserves is less certain. We assessed P fertilizer usedfor production of food crops, livestock and biofuels in the US agricultural system, explicitlycomparing the domestic P use required for US food consumption to the P use embodied in theproduction of US food imports and exports. By far the largest demand for P fertilizer throughout theUS agricultural system was for feed and livestock production (56% of total P fertilizer use,including that for traded commodities). As little as 8% of the total mineral P inputs to US domesticagriculture in 2007 (1905 Gg P) was consumed in US diets in the same year, while larger fractionsmay have been retained in agricultural soils (28%), associated with different post-harvest losses(40%) or with biofuel refining (10%). One quarter of all P fertilizer used in the US was linked toexport production, primarily crops, driving a large net P flux out of the country (338 Gg P).However, US meat consumption relied considerably on P fertilizer use in other countries to producered meat imports. Changes in domestic farm management and consumer waste could together reduce the Pfertilizer required for US food consumption by half, which is comparable to the P fertilizerreduction attainable by cutting domestic meat consumption (44%). US export-oriented agriculture,domestic post-harvest P losses and global demand for meat may ultimately have an important influenceon the lifespan of US phosphate rock reserves. VL - 7 SN - 1748-9326 UR - http://stacks.iop.org/1748-9326/7/i=4/a=044024 IS - 4 ER - TY - JOUR T1 - General Resilience to Cope with Extreme Events JF - Sustainability Y1 - 2012 A1 - Carpenter, S. R. A1 - Arrow, K. J. A1 - Barrett, S. A1 - Biggs, R. A1 - Brock, W. A. A1 - Crepin, A. S. A1 - Engstrom, G. A1 - Folke, C. A1 - Hughes, T. P. A1 - Kautsky, N. A1 - Li, C. Z. A1 - McCarney, G. A1 - Meng, K. A1 - Maler, K. G. A1 - Polasky, S. A1 - Scheffer, M. A1 - Shogren, J. A1 - Sterner, T. A1 - Vincent, J. R. A1 - Walker, B. A1 - Xepapadeas, A. A1 - de Zeeuw, A. AB - Resilience to specified kinds of disasters is an active area of research and practice. However, rare or unprecedented disturbances that are unusually intense or extensive require a more broad-spectrum type of resilience. General resilience is the capacity of social-ecological systems to adapt or transform in response to unfamiliar, unexpected and extreme shocks. Conditions that enable general resilience include diversity, modularity, openness, reserves, feedbacks, nestedness, monitoring, leadership, and trust. Processes for building general resilience are an emerging and crucially important area of research. VL - 4 SN - 2071-1050 UR - http://dx.doi.org/10.3390/su4123248 IS - 12 ER -