Simple Summary The innovative concept of environmental DNA has found its foot in aquatic
ecosystems but remains an unexplored area of research concerning terrestrial ecosystems …

Environmental DNA (eDNA) degradation influences the effectiveness of eDNA‐based
biodiversity monitoring, but the factors that determine the rate of decay of eDNA in terrestrial …

Biomonitoring is vital for establishing baseline data that is needed to identify and quantify
ecological change and to inform management and conservation activities. However …

Environmental (e) DNA has rapidly become a powerful biomonitoring tool, particularly in
aquatic ecosystems. This approach has not been as widely adopted in terrestrial …

Terrestrial vertebrates are experiencing worldwide population declines and species
extinctions. To effectively conserve remaining populations and species, rapid, cost‐effective …

Globally, the diversity of arthropods and the plants upon which they rely are under
increasing pressure due to a combination of biotic and abiotic anthropogenic stressors …

Environmental DNA (eDNA) approaches to monitoring biodiversity in terrestrial
environments have largely focused on sampling water bodies, potentially limiting the …

In recent years, the analysis of environmental DNA (eDNA) has significantly improved,
allowing for high‐resolution species identification and possible biomass quantification from …

Tree hollows are essential for many vertebrate species, providing both nesting sites and
shelter. Globally, old hollow‐bearing trees are in decline resulting in many dependent …

Environmental DNA holds significant promise as a non-invasive tool for tracking terrestrial
biodiversity. However, in non-homogenous terrestrial environments, the continual …