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Explicit memories, also known as declarative memories, are consciously remembered, recalled, and reported. Studying for a chemistry exam involves material that will become part of explicit memory. There are two types of explicit memory: episodic and semantic.
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Forecasting species range dynamics with process-explicit models: matching methods to applications.

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Process-explicit models offer robust species distribution predictions by incorporating ecological processes. Evaluating these models is crucial for effective ecological problem-solving and management decisions.

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Area of Science:

  • Ecology
  • Environmental Science
  • Computational Biology

Background:

  • Species distribution models (SDMs) traditionally rely on correlative approaches, implicitly capturing ecological processes.
  • There is increasing interest in process-explicit models that directly incorporate factors like physiology, dispersal, demography, and biotic interactions.
  • Process-explicit models are hypothesized to provide more reliable predictions, especially under novel environmental conditions.

Purpose of the Study:

  • To review and assess the strengths, limitations, and current applications of various process-explicit models.
  • To determine the suitability of different process-explicit models for common species distribution modeling applications.
  • To identify barriers hindering the adoption of process-explicit models and propose solutions.

Main Methods:

  • Literature review of process-explicit species distribution models.
  • Analysis of model performance across four key applications: regulatory planning, extinction risk assessment, climate refugia identification, and invasive species management.
  • Identification of challenges and opportunities for implementing process-explicit models in ecological research and management.

Main Results:

  • A range of process-explicit models exist, each with distinct advantages and disadvantages.
  • The suitability of specific models varies depending on the ecological application and management objectives.
  • Significant barriers, including technical, data-related, and evaluation challenges, impede the widespread use of these advanced models.

Conclusions:

  • Process-explicit models hold significant promise for advancing ecological understanding and informing conservation and management.
  • More rigorous evaluation of model predictions is essential to guide future methodological development and ensure the effective application of these tools.
  • Overcoming identified barriers is critical for realizing the full potential of process-explicit modeling in addressing pressing environmental challenges.