Jennifer Sunday Department of Biology, McGill University Detecting range shifts requires repeated surveys across space and long durations of time. As such, our key datasets have been opportunistic, often coarse in spatial and temporal grain, and difficult to synthesize coherently. Yet the promise of range shift detections remains that systematic observations at high spatial…
AE Bates3, MI Duncan1,2, NC James2, Professor Warren Potts1 1Department of Ichthyology and Fisheries Science, Rhodes University, Grahamstown, South Africa, 2South African Institute of Aquatic Biodiversity, Grahamstown, South Africa, 3Department of Ocean Sciences, Memorial University of Newfoundland, St. John’s, Canada Anthropogenic induced climate change is modulating the redistribution of species across the globe at accelerated…
Mr Peter Soroye1, Dr Tim Newbold2, Dr Jeremy Kerr1 1University Of Ottawa, Ottawa, Canada, 2University College London, London, United Kingdom Bumblebee (Bombus) species across North America and Europe are declining in range size and abundance across their ranges, linked in part to rapid recent climate change. Niche theory and physiology suggest that species’ physiological limits…
Ms Samantha Twiname1, Dr Eva Plaganyi2, Dr Alistair Hobday3,4, Dr Quinn Fitzgibbon1, Professor Chris Carter1, Professor Gretta Pecl1,4 1Institute for Marine and Antarctic Studies, Taroona, Australia, 2CSIRO Oceans and Atmosphere, Brisbane, Australia, 3CSIRO Oceans and Atmosphere, Hobart, Australia, 4Centre for Marine Socioecology, Hobart, Australia Species redistribution’s are one of the most commonly documented changes in…
Madeleine A. Rubenstein1, Shawn L. Carter1, Mitchell J. Eaton2, Jeremy S. Littell3, Abigail J. Lynch1, Brian W. Miller4, Toni Lyn Morelli5, Adam J. Terando2, Laura M. Thompson1, Sarah R. Weiskopf1 1National Climate Adaptation Science Center, US Geological Survey, Reston, United States, 2Southeast Climate Adaptation Science Center, US Geological Survey, Raleigh, USA, 3Alaska Climate Adaptation Science…
Dr Lilian Sales1, Bruno Ribeiro2, Mathias Pires1, Colin Chapman3, Rafael Loyola2 1University of Campinas, Campinas, Brazil, 2Federal University of Goiás, , Brazil, 3McGill University, Montreal, Canada Climate change will redistribute the global biodiversity in the Anthropocene. As the climate changes, species might move from one place to another, to stay within preferred environments. However, the…
Dr Josep M Serra Diaz1 1Agroparistech, Nancy, France, 2BIOCHANGE- Center for Biodiversity Dynamics in a Changing World, Aarhus, Denmark Range shifts are taking place in a multitude of organisms, but attributing and predicting range shifts for tree species is a difficult task due to their passive dispersal and long generation times. Shits in tree species…
Dr Samuel Pironon1, Mr. Ian Ondo1, Ms. Eleanor Hammond-Hunt1, Dr. Tiziana Ulian1, Professor Kathy Willis2 1Royal Botanic Gardens Kew, Richmond, United Kingdom, 2University of Oxford, Oxford, United Kingdom Climate change impacts biodiversity and the associated goods and services humans rely on. Thus, it also has profound effects on human societies across the world. Understanding and…
Miss Farrah Powell1,2,4, Dr. Erik Franklin3,1, Dr. Camilo Mora1 1Department of Geography and Environment, University of Hawaii at Manoa, Honolulu, United States, 2Department of Geography, University of California Santa Barbara, Santa Barbara, United States, 3Hawaii Institute of Marine Biology, School of Ocean and Earth Science and Technology, University of Hawaii at Manoa, Kaneohe, United States,…
Prof Petr Pysek1, Prof Wayne Dawson2, Dr Franz Essl3, Prof Holger Kreft4, Dr Jan Pergl1, Prof Mark van Kleunen5, Dr Patrick Weigelt4, Dr Marten Winter6 1Czech Academy Of Sciences, Institute Of Botany, Pruhonice, Czech Republic, 2School of Biological and Biomedical Sciences, Durham University, Durham, United Kingdom, 3Division of Conservation, Vegetation and Landscape Ecology, University of…
Sunday May 14, 2023
9 am - 4 pm
Lead organizer: Dave Klinges, University of Florida, dklinges9@gmail.com
Co-organizers: Mike Kearney, University of Melbourne, m.kearney@unimelb.edu.au; Ilya Maclean, i.m.d.maclean@exeter.ac.uk; Rebecca Senior, Durham University, rebecca.senior@durham.ac.uk
Understanding the impacts of global change on organisms and ecosystems requires data and models that represent ecologically-relevant conditions. Microclimates have long been studied in ecology, and a recent resurgence of interest has produced a proliferation of fine-resolution, large-extent databases, along with models that predict microclimate and organismal responses. This hands-on coding workshop will overview the application of microclimatic information in ecology and introduce several R packages, and may be of interest to any who seek to use quantitative methods in climate change ecology. We will cater to conference attendees with novice or intermediate modeling experience, and there is no prerequisite for familiarity with climate or biophysical modeling.
After this workshop, participants will be equipped with the tools and knowledge to employ cutting-edge climate and biophysical modeling techniques. Participants will be provided in advance instructions to install the necessary packages, the R scripts to be used, and the corresponding data (no requirement to bring your data). Participants are expected to be familiar with base R/RStudio, and we will follow tidyverse conventions.
Sunday May 14, 2023
9 am - 5 pm
Important Note: This workshop is a two part workshop with Part 1 workshop being led by Mireia Valle. In the early afternoon of Sunday, Part 2 will be led by Saras Windecker (University of Melbourne) and David Uribe-Rivera (CSIRO Australia) and provide an overview of model-based data integration for modeling species’ distributions.
SDM Part 1
Lead organizer: Mireia Valle, AZTI, Marine Research, Basque Research and Technology Alliance (BRTA), mvalle@azti.es
Co-organizers: Leire Citores, AZTI, Marine Research, Basque Research and Technology Alliance (BRTA), lcitores@azti.es; Maite Erauskin , AZTI, Marine Research, Basque Research and Technology Alliance (BRTA), merauskin@azti.es; Leire Ibaibarriaga, AZTI, Marine Research, Basque Research and Technology Alliance (BRTA), libaibarriaga@azti.es; Guillem Chust, AZTI, Marine Research, Basque Research and Technology Alliance (BRTA), gchust@azti.es
Species distribution models (SDMs) are widely used as a tool for understanding species spatial ecology. They link species occurrence or abundance with environmental features of the location, via statistical modelling. According to ecological niche theory, species response curves are unimodal with respect to environmental gradients. While a variety of statistical methods have been developed for species distribution modelling, a general problem with most of these habitat modelling approaches is that the estimated response curves can display biologically implausible shapes which do not respect ecological niche theory. This is because species response curves are fit statistically with any assumption or restriction, which sometimes do not respect the ecological niche theory. To better understand species response to environmental changes, SDMs should consider theoretical background such as the ecological niche theory and pursue the unimodality of the response curve with respect to environmental gradients. At this short course you will learn to build SDMs under the ecological niche theory framework. We will use shape-constrained generalized additive models (SC-GAMs) that allow imposing concavity constraints in the linear predictor scale and avoid overfitting. SC-GAMs are based on the same statistical framework as GLMs and GAMs regression methods, but they allow us to incorporate monotonicity and concavity shape-constraints in the component functions of the linear predictor of the GAMs. Imposing concavity constraints should be an effective alternative to fitting nonsymmetric parametric response curves, while retaining the unimodality constraint, required by ecological niche theory, for direct variables and limiting factors. We will guide you building SC-GAMs from the beginning retrieving the occurrence data and environmental data from global public datasets. We will clean raw data removing outliers and select the environmental variables using a step-forward function. The course is intended to anyone who wants to broaden their knowledge of SDMs and improve their model’s realism. We will follow a R tutorial developed in AZTI. R is a programming language widely used by data scientists and R basic knowledge is required to follow the course.
Sunday May 14, 2023
9 am - 4 pm
Workshop leads: Prof. Rob Fletcher (Professor) University of Florida, Andrew Marx (Data scientist, University of Florida), Maru Iezzi (Postdoctoral Associate, University of Florida), Alex Baecher (PhD student, University of Florida)
Required materials:
1) Install R on your computer (if you haven’t already!).
3) Make sure to install / update the following R packages: samc, raster, terra, gdistance, sf, tidyverse, leaflet, htmlwidgets, Matrix
4) We will provide other materials over email (code, data, literature).
This 1 day workshop will distill the basic principles of connectivity modeling and its relevance to predicting movement and species redistribution with environmental change. Participants will be introduced to a circuit theoretic approach as well as a new framework utilizing spatial-absorbing markov chains (SAMC) and how to apply this analytical tool to study landscape connectivity and how it may alter global biodiversity redistribution under rapid environmental change. This workshop will explore how best to model connectivity of both habitat- and climate-analogs. Along the way, we will discuss core principles in defining a species range such as adaptive potential, connectivity and climate exposure, and morphological and physiological traits that vary from contracting to leading edge of a species range. We will also discuss the common problems, assumptions, and oversights occurring in published predictions of species range redistribution.
| Time | Topic |
|---|---|
| 9:00-9:10 | Welcome and Introductions |
Backfround and Motivation
| Time | Topic |
|---|---|
| 9:10-10:00 | Connectivity and species on the move |
| 10:00-10:15 | The state of connectivity modeling using R and other software |
| 10:15-10:30 | Coffee break / discussion |
Markov chains, connectivity, and the SAMC framework
| Time | Topic |
|---|---|
| 10:30-11:00 | An introduction to the SAMC and the samc package |
| 11:00-11:15 | Relationships with other connectivity frameworks |
| 11:15-11:30 | R activity—contrasting the SAMC and circuit theory |
| 11:30-12:00 | Lunch break |
Building a connectivity model with the SAMC
| Time | Topic |
|---|---|
| 12:00-12:30 | An introduction to the SAMC and the samc package |
| 12:30-1:00 | Building and tuning a SAMC model |
| 1:00-1:30 | Spatial networks and the SAMC |
| 1:30-1:45 | Coffee break / discussion |
Advanced topics
| Time | Topic |
|---|---|
| 1:45-2:00 | Modeling dispersal kernels with the SAMC |
| 2:00-2:30 | Movement ecology and the SAMC |
| 2:30-3 | Dynamic models for connectivity and species redistribution |
| 3-3:30 | Scaling models to large regions |
| 3:30-4:00 | Discussion of applications and conclusions |
Friday May 19th
1pm - 6pm
Introductory meeting during the week over lunch (TBD)
Lead organizer: Dirk Nikolaus Karger, Swiss Federal Institute for Forest, Snow, and Landscape Research WSL.
In order to predict the future response of species to climate change, climate prediction data are essential. With the release of the Coupled Model Intercomparison Project Phase 6 (CMIP6), a large amount of new data has become available. CMIP6 includes a much larger number of climate models, socio-economic scenarios and experiments than its predecessor, CMIP5. However, these data are generally too coarse compared to the spatial detail needed for most ecological studies. Many applications that study the impact of climate on species do not require the full range of variables, models, or SSPs that CMIP6 can provide, but rather a high resolution of 1 km. Furthermore, they often rely on only a limited number of so-called bioclimatic variables, which describe averages or variations in climate over long periods of time. The CHELSA data portal already offers such downscaled CMIP6 data. However, due to the large number of possible combinations, it is very difficult to provide pre-processed, downscaled CMIP6 data for all climate and SSP models. In addition, data are only available for a limited number of time periods, which do not always coincide with the time periods required for some studies.
In this workshop, we will provide an overview of the chelsa-cmip6 Python module, which allows the creation of custom, downscaled CMIP6 bioclimate data for any region. The chelsa-cmip6 package allows you to specifically select the desired geographic extent, climate model, GCM, and time period to facilitate easy delivery of state-of-the-art climate data for ecological climate research.
After this workshop, you will be able to produce your own future 1km bioclimatic data based on the Delta Change method. The workshop will cover the following aspects.
Theory:
Practical exercise:
Prerequisites: Although chelsa-cmip6 is written in Python, no real knowledge of Phyton is required to use it, but some basic knowledge of Python may be beneficial to take full advantage of the module. However, you should know how to use the terminal or command line interpreter of your computer.
Sunday May 14, 2023
9 am - 5 pm
Important Note: This workshop is a two part workshop with Part 1 workshop being led by Mireia Valle. In the early afternoon of Sunday, Part 2 will be led by Saras Windecker (University of Melbourne) and David Uribe-Rivera (CSIRO Australia) and provide an overview of model-based data integration for modeling species’ distributions.
SDM Part 2
Workshop Leads: Saras Windecker, University of Melbourne, sm.windecker@unimelb.edu.au
David Uribe-Rivera, Commonwealth Scientific and Industrial Research Organisation, de.uribe.r@gmail.com
To make the most accurate prediction of a species’ distribution it is important to make use of all relevant data. Although opportunistically collected species records are more readily abundant, they also contain lower quality information and are more likely to be biased. Standardised surveys may suffer less observation bias, but they are expensive to conduct and are therefore more likely to have limited spatial extent. Combining opportunistic and standardised data not only gives more information to a model, but also provides a chance for structured survey data to help correct biases in opportunistic data. Model-based data integration allows us to explicitly model the ecological (species’ occupancy/abundance) and observational processes (detection/sampling effort) simultaneously, propagating information contained in each while accounting for appropriate biases. In this skills showcase we will explain the concepts behind model-based data integration, demonstrate its implementation in a Bayesian framework for modeling species’ distributions, and practice with a number of exercises. Our examples will use broad spatial-scale presence-only data and spatial abundance data from structured surveys, and will illustrate how Point process models can be used to facilitate this integration. We expect that participants will leave more confident in the theory and execution of integrated models.