生态系统与生态学杂志

抽象的

A Note on Phylogenetic Patterns of Biodiversity

Chang Kuang

The threats to biodiversity in the world today are numerous and expanding quickly. Approaches that combine bioinformatics, extensive phylogeny reconstruction, utilization of digital specimen data, and complex post-tree analysis (such as niche modelling, niche diversification, and other ecological analyses) are necessary to address these biodiversity concerns. Incomparable opportunities for mobilizing and integrating vast amounts of biological data are now available thanks to recent advancements in phylogenetics, emerging cyber infrastructure, and new data sources. This has led to the identification of complex patterns and the development of novel research hypotheses. These findings are significant because the global biodiversity data that are now being gathered and examined are intrinsically complicated. We refer to the systematics, ecology, and evolution-related research that is being made possible by the ongoing integration and development of the biodiversity tools outlined here as “biodiversity science.” To speed up research in these fields, new training that combines data science expertise with domain knowledge in biodiversity is also required. The future of global biodiversity depends on integrative biodiversity science. We cannot simply respond to the ongoing threats to biodiversity; instead, we must anticipate them. Using an integrative, multifaceted, big data approach, researchers can now project biodiversity and provide vital information for the general public, land managers, policy makers, urban planners, and agriculture, as well as for scientists.