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1. An agent-based model reveals lost person behavior based on data from wilderness search and rescue

   https://doi.org/10.1038/s41598-022-09502-4  

   Hashimoto, Amanda; Heintzman, Larkin; Koester, Robert; Abaid, Nicole (April 2022, Scientific Reports)

   Abstract Thousands of people are reported lost in the wilderness in the United States every year and locating these missing individuals as rapidly as possible depends on coordinated search and rescue (SAR) operations. As time passes, the search area grows, survival rate decreases, and searchers are faced with an increasingly daunting task of searching large areas in a short amount of time. To optimize the search process, mathematical models of lost person behavior with respect to landscape can be used in conjunction with current SAR practices. In this paper, we introduce an agent-based model of lost person behavior which allows agents to move on known landscapes with behavior defined as independent realizations of a random variable. The behavior random variable selects from a distribution of six known lost person reorientation strategies to simulate the agent’s trajectory. We systematically simulate a range of possible behavior distributions and find a best-fit behavioral profile for a hiker with the International Search and Rescue Incident Database. We validate these results with a leave-one-out analysis. This work represents the first time-discrete model of lost person dynamics validated with data from real SAR incidents and has the potential to improve current methods for wilderness SAR. 

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2. Environmental conditions lead to shifts in individual communication, which can cause cascading effects on soundscape composition

   https://doi.org/10.1002/ece3.9359  

   Pandit, Meelyn M.; Bridge, Eli S.; Ross, Jeremy D. (October 2022, Ecology and Evolution)

   Abstract Climate change is increasing aridity in grassland and desert habitats across the southwestern United States, reducing available resources and drastically changing the breeding habitat of many bird species. Increases in aridity reduce sound propagation distances, potentially impacting habitat soundscapes, and could lead to a breakdown of the avian soundscapes in the form of loss of vocal culture, reduced mating opportunities, and local population extinctions. We developed an agent‐based model to examine how changes in aridity will affect both sound propagation and the ability of territorial birds to audibly contact their neighbors. We simulated vocal signal attenuation under a variety of environmental scenarios for the south, central semi‐arid prairies of the United States, ranging from contemporary weather conditions to predicted droughts under climate change. We also simulated how changes in physiological conditions, mainly evaporative water loss (EWL), would affect singing behavior. Under contemporary and climate change‐induced drought conditions, we found that significantly fewer individuals successfully contacted all adjacent neighbors than did individuals in either the contemporary or predicted climate change conditions. We also found that at higher sound frequencies and higher EWL, fewer individuals were able to successfully contact all their neighbors, particularly in drought and climate change drought conditions. These results indicate that climate change‐mediated aridification may alter the avian soundscape, such that vocal communication no longer effectively functions for mate attraction or territorial defense. As climate change progresses, increased aridity in current grasslands may favor shifts toward low‐frequency songs, colonial resource use, and altered songbird community compositions. 

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3. Projecting Urbanization and Landscape Change at Large Scale Using the FUTURES Model

   https://doi.org/10.3390/land8100144  

   Van Berkel, Derek; Shashidharan, Ashwin; Mordecai, Rua; Vatsavai, Raju; Petrasova, Anna; Petras, Vaclav; Mitasova, Helena; Vogler, John; Meentemeyer, Ross (October 2019, Land)

   Increasing population and rural to urban migration are accelerating urbanization globally, permanently transforming natural systems over large extents. Modelling landscape change over large regions, however, presents particular challenges due to local-scale variations in social and environmental factors that drive land change. We simulated urban development across the South Atlantic States (SAS), a region experiencing rapid population growth and urbanization, using FUTURES—an open source land change model that uses demand for development, local development suitability factors, and a stochastic patch growing algorithm for projecting alternative futures of urban form and landscape change. New advances to the FUTURES modelling framework allow for high resolution projections over large spatial extents by leveraging parallel computing. We simulated the adoption of different urban growth strategies that encourage settlement densification in the SAS as alternatives to the region’s increasing sprawl. Evaluation of projected patterns indicate a 15% increase in urban lands by 2050 given a status quo development scenario compared to a 14.8% increase for the Infill strategy. Status quo development resulted in a 3.72% loss of total forests, 2.97% loss of highly suitable agricultural land, and 3.69% loss of ecologically significant lands. An alternative Infill scenario resulted in similar losses of total forest (3.62%) and ecologically significant lands (3.63%) yet consumed less agricultural lands (1.23% loss). Moreover, infill development patterns differed qualitatively from the status quo and resulted in less fragmentation of the landscape. 

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4. Indigenous peoples and salmon stewardship: a critical relationship

   https://doi.org/10.5751/ES-11972-260116  

   Carothers, Courtney; Black, Jessica; Langdon, Stephen J; Donkersloot, Rachel; Ringer, Danielle; Coleman, Jesse; Gavenus, Erika R; Justin, Wilson; Williams, Mike; Christiansen, Freddie; et al (January 2021, Ecology and Society)

   ABSTRACT. Indigenous Peoples and salmon in the lands now called Alaska have been closely entwined for at least 12,000 years. Salmon continue to be central to the ways of life of Alaska Natives, contributing to physical, social, economic, cultural, spiritual, psychological, and emotional well-being. Salmon have also become important to Alaskan settlers. Our research and advisory team conducted a synthesis of what is known about these diverse human–salmon relationships, drawing on 865 published scientific studies; Indigenous knowledge; state, federal, and tribal data; archival materials; oral histories; and cross-cultural dialogs at working group meetings. Two important socio-cultural dimensions of salmon–people systems emerged from this synthesis as fundamentally important but largely invisible outside of Indigenous communities and the social science disciplines that work closely with these communities: (1) the deep relationships between Indigenous Peoples and salmon and (2) the pronounced inequities that threaten these relationships and stewardship systems. These deep relationships are evident in the spiritual, cultural, social, and economic centrality of salmon across time and cultures in Alaska. We describe Indigenous salmon stewardship systems for the Tlingit, Ahtna, and Central Yup'ik. The inequities in Alaska's salmon systems are evident in the criminalization and limitation of traditional fishing ways of life and the dramatic alienation of Indigenous fishing rights. The loss of fish camps and legal battles over traditional hunting and fishing rights through time has caused deep hardship and stress. Statewide, the commodification and marketization of commercial fishing rights has dispossessed Indigenous communities from their human and cultural rights to fishing ways of life; as a result, many rural and Indigenous youth struggle to gain access to fishing livelihoods, leaving many fishing communities in a precarious state. These deep relationships and relatively recent fractures have motivated a concerted effort by a group of committed Indigenous and western scholars to better understand the root causes and opportunities for redress, as well as to document the breadth of research that has already been conducted, in an effort to improve the visibility of these often-overlooked dimensions of our salmon systems. 

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5. Mapping and modeling the impact of climate change on recreational ecosystem services using machine learning and big data

   https://doi.org/10.1088/1748-9326/ac65a3  

   Manley, Kyle; Egoh, Benis N (April 2022, Environmental Research Letters)

   Abstract The use of recreational ecosystem services is highly dependent on the surrounding environmental and climate conditions. Due to this dependency, future recreational opportunities provided by nature are at risk from climate change. To understand how climate change will impact recreation we need to understand current recreational patterns, but traditional data is limited and low resolution. Fortunately, social media data presents an opportunity to overcome those data limitations and machine learning offers a tool to effectively use that big data. We use data from the social media site Flickr as a proxy for recreational visitation and random forest to model the relationships between social, environmental, and climate factors and recreation for the peak season (summer) in California. We then use the model to project how non-urban recreation will change as the climate changes. Our model shows that current patterns are exacerbated in the future under climate change, with currently popular summer recreation areas becoming more suitable and unpopular summer recreation areas becoming less suitable for recreation. Our model results have land management implications as recreation regions that see high visitation consequently experience impacts to surrounding ecosystems, ecosystem services, and infrastructure. This information can be used to include climate change impacts into land management plans to more effectively provide sustainable nature recreation opportunities for current and future generations. Furthermore, our study demonstrates that crowdsourced data and machine learning offer opportunities to better integrate socio-ecological systems into climate impacts research and more holistically understand climate change impacts to human well-being. 

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