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Geodiversity data for Europe.

M Toivanen1, T Maliniemi1, J Hjort1

  • 1Geography Research Unit, University of Oulu, 90014 Oulu, Finland.

Philosophical Transactions. Series A, Mathematical, Physical, and Engineering Sciences
|February 11, 2024
PubMed
Summary
This summary is machine-generated.

This study introduces new European geodiversity data, quantifying geological, soil, landform, and water diversity. The findings reveal a significant link between geodiversity and plant species richness, supporting its use in ecological research.

Keywords:
biodiversitygeological diversitygeomorphological diversitygeorichnesshydrological diversitypedological diversity

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Area of Science:

  • Earth Sciences
  • Ecology
  • Environmental Science

Background:

  • Geodiversity, a key component of nature's diversity, is poorly understood regarding its large-scale spatial distribution and relationship with biodiversity.
  • Existing geodiversity assessments often lack comprehensive data across extensive geographical areas.

Purpose of the Study:

  • To present novel European geodiversity data at 1km and 10km resolutions.
  • To quantitatively assess terrestrial geodiversity (georichness) using a grid-based approach.
  • To evaluate the data's utility by correlating it with national geodiversity data and species richness.

Main Methods:

  • Developed European geodiversity data incorporating geological, pedological, geomorphological, and hydrological diversity.
  • Assessed geodiversity quantitatively as georichness using a grid-based methodology.
  • Correlated European georichness with Finnish national geodiversity data and vascular plant species richness in Finland and Switzerland.

Main Results:

  • European georichness showed positive correlations with national geodiversity data in Finland at both 1km (r=0.37) and 10km (r=0.59) resolutions.
  • Significant positive correlations were found between georichness and vascular plant species richness in Finland (r=0.34) and Switzerland (r=0.26).
  • The data provide insights into abiotic diversity and establish a scalable geodiversity assessment method.

Conclusions:

  • The presented European geodiversity data are robust and suitable for large-scale geodiversity-biodiversity research.
  • The data have broad applicability beyond ecological studies, offering insights into abiotic diversity across various scales and regions.
  • This work establishes a quantitative, worldwide applicable method for large-scale geodiversity assessment.