Development of scenarios for land cover, population density, impervious cover, and conservation in New Hampshire, 2010&amp;#8211;2100

Thorn, Alexandra M.; Wake, Cameron P.; Grimm, Curt; Mitchell, Clayton R.; Mineau, Madeleine M.; Ollinger, Scott V.

doi:10.5751/es-09733-220419

Cited by 16 publications

(23 citation statements)

References 37 publications

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“…We next describe the integrated terrestrial-aquatic model that projects aquatic environmental indicators, including scenarios, parameterizations, and data sets needed to project aquatic indicators to 2100. Finally, to understand how aquatic and terrestrial processes control the projected environmental conditions, we evaluate model sensitivity to a suite of climate and land-cover change (Thorn et al 2017).…”

Section: Methodsmentioning

confidence: 99%

“…By 2100, population increases by 170% in the Backyard/High scenario and declines by 5% in the Small Community Food/Low scenario. The increase in agricultural land relative to population under the Small Community Food/Low scenario (~1.0 acres per person in 2100 compared with 0.2 in 2010) increases the potential for per capita local food production compared with the contemporary period (Thorn et al 2017). The Maple Presence indicator, which primarily represents the geographic distribution of suitable habitat for Acer saccharum , declines from 49% of total forest cover in the present day to 27% and 31% in the Backyard/High emission and Small Community Food/Low emission scenarios, respectively.…”

Section: Regional Framework For Land Climate and Water Indicators Tmentioning

confidence: 99%

“…Changes in the land indicators (Table 2; Agricultural Cover per person and Forest Cover) directly reflect the land-cover scenarios (Thorn et al 2017) and have important direct ecosystem service implications. Briefly, in the Backyard scenario, watershed forest cover declines from 80% in 2010 to 60% in 2100, to accommodate increased rural and suburban development (Fig.…”

Section: Regional Framework For Land Climate and Water Indicators Tmentioning

confidence: 99%

“…The model was first applied to historical conditions (2000)(2001)(2002)(2003)(2004)(2005)(2006)(2007)(2008)(2009)(2010)(2011)(2012)(2013)(2014)(2015) to test against field observations using downscaled reanalysis meteorological observations and current land cover. Meteorological forcing for future scenarios used statistically downscaled climate data from , and land cover from Thorn et al (2017). A detailed summary of the model input data for contemporary and future scenarios is described in Appendix 2.…”

Section: Coupling Of Terrestrial and Aquatic Modelsmentioning

confidence: 99%

“…Candidate indicators had relevance to climate, land, and water domains. Terrestrial indicators were based on land-cover scenarios (Thorn et al 2017) and the Northern Research Station Climate Change Atlas . Climate indicators were based the Geophysical Fluid Dynamics Laboratory (GFDL) CM2.1 global climate model (GCM) simulations using the SRES A1Fi (higher) and B1 (lower) emissions scenarios (Nakicenvoic and Swart 2000) that were statistically downscaled using the asynchronous regional regression model (Stoner et al 2012, Wake et al 2014.…”

Section: Environmental Indicatorsmentioning

confidence: 99%

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A coupled terrestrial and aquatic biogeophysical model of the Upper Merrimack River watershed, New Hampshire, to inform ecosystem services evaluation and management under climate and land-cover change

Samal¹,

Wollheim²,

Zuidema³

et al. 2017

E&S

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ABSTRACT. Accurate quantification of ecosystem services (ES) at regional scales is increasingly important for making informed decisions in the face of environmental change. We linked terrestrial and aquatic ecosystem process models to simulate the spatial and temporal distribution of hydrological and water quality characteristics related to ecosystem services. The linked model integrates two existing models (a forest ecosystem model and a river network model) to establish consistent responses to changing drivers across climate, terrestrial, and aquatic domains. The linked model is spatially distributed, accounts for terrestrial-aquatic and upstreamdownstream linkages, and operates on a daily time-step, all characteristics needed to understand regional responses. The model was applied to the diverse landscapes of the Upper Merrimack River watershed, New Hampshire, USA. Potential changes in future environmental functions were evaluated using statistically downscaled global climate model simulations (both a high and low emission scenario) coupled with scenarios of changing land cover (centralized vs. dispersed land development) for the time period of 1980-2099. Projections of climate, land cover, and water quality were translated into a suite of environmental indicators that represent conditions relevant to important ecosystem services and were designed to be readily understood by the public. Model projections show that climate will have a greater influence on future aquatic ecosystem services (flooding, drinking water, fish habitat, and nitrogen export) than plausible changes in land cover. Minimal changes in aquatic environmental indicators are predicted through 2050, after which the high emissions scenarios show intensifying impacts. The spatially distributed modeling approach indicates that heavily populated portions of the watershed will show the strongest responses. Management of land cover could attenuate some of the changes associated with climate change and should be considered in future planning for the region.

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Section: Methodsmentioning

confidence: 99%

Section: Regional Framework For Land Climate and Water Indicators Tmentioning

confidence: 99%

Section: Regional Framework For Land Climate and Water Indicators Tmentioning

confidence: 99%

Section: Coupling Of Terrestrial and Aquatic Modelsmentioning

confidence: 99%

Section: Environmental Indicatorsmentioning

confidence: 99%

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A coupled terrestrial and aquatic biogeophysical model of the Upper Merrimack River watershed, New Hampshire, to inform ecosystem services evaluation and management under climate and land-cover change

Samal¹,

Wollheim²,

Zuidema³

et al. 2017

E&S

Self Cite

View full text Add to dashboard Cite

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Quantifying the impacts of climate change and land use/cover change on runoff in the lowerConnecticut River Basin

Wang

Stephenson

2018

Hydrological Processes

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Climate change and land use and cover change (LUCC) have had great impacts on watershed hydrological processes. Although previous studies have focused on quantitative assessment of the impacts of climate change and human activities on decreasing run‐off change, few studies have examined regions that have significant increasing run‐off due to both climate variability and land cover change. We show that annual run‐off had a significant increasing trend from 1956 to 2014 in the U.S. lower Connecticut River Basin. Abrupt change point years of annual run‐off for four subbasins are detected by nonparametric Mann–Kendall–Sneyers test and reconfirmed by the double mass curve. We then divide the study period into 2 subperiods at the abrupt change point year in the early 1970s for each subbasin. The Choudhury–Yang equation based on Budyko hypothesis was used to calculate precipitation and potential evapotranspiration, and landscape elasticities of run‐off. The results show that the difference in mean annual run‐off between 2 subperiods for each subbasin ranged from 102 to 165.6 mm. Climate variations were the primary drivers of increasing run‐off in this region. Quantitative contributions of precipitation and potential evapotranspiration in all subbasins are 106.5% and −3.6% on average, respectively. However, LUCC contributed both positively and negatively to run‐off: −18.6%, −13.3%, and 10.1% and 9.9% for 4 subbasins. This may be attributed to historical LUCC occurring after the abrupt change point in each subbasin. Our results provide critical insight on the hydrological dynamics of north‐east tidal river systems to communities and policymakers engaged in water resources management in this region.

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Spatially explicit residential and working population assumptions for projecting and assessing natural capital and ecosystem services in Japan

et al. 2018

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In scenario studies of biodiversity and ecosystem services, the population distribution is one of the key driving forces. In this study, we developed a coupling method for narrative scenarios and spatially explicit residential and working population designs for all of Japan as a common data set for ecosystem scenario analysis implemented by 5-year project entitled "Predicting and Assessing Natural Capital and Ecosystem Services (PANCES)". Four narrative scenarios were proposed by the PANCES project by using two axes as major uncertainties: the population distribution and the capital preference. The residential population and the working population in primary industries were calculated using a gravity-based allocation algorithm in a manner consistent with the storylines of the PANCES scenarios. By using the population distribution assumption by scenario, the population was overlaid with the natural capital and the supply potential of ecosystem services. The results supported to understand the gaps between natural capital and maintainability, the potential of ecosystem services and realizability. The spatially explicit population distribution data products are expected to help design the nature conservation strategy and governance option in terms of both social system and ecological system.

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Development of scenarios for land cover, population density, impervious cover, and conservation in New Hampshire, 2010–2100

Cited by 16 publications

References 37 publications

A coupled terrestrial and aquatic biogeophysical model of the Upper Merrimack River watershed, New Hampshire, to inform ecosystem services evaluation and management under climate and land-cover change

A coupled terrestrial and aquatic biogeophysical model of the Upper Merrimack River watershed, New Hampshire, to inform ecosystem services evaluation and management under climate and land-cover change

Quantifying the impacts of climate change and land use/cover change on runoff in the lowerConnecticut River Basin

Spatially explicit residential and working population assumptions for projecting and assessing natural capital and ecosystem services in Japan

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