Accounting for among-sampler variability improves confidence in fuel moisture content field measurements
Kerryn Little
A * , Laura J. Graham A B and Nicholas Kettridge A
A
B
Abstract
Direct fuel moisture content measurements are critical for characterising spatio-temporal variations in fuel flammability and for informing fire danger assessments. However, among-sampler variability (systematic differences in measurements between samplers) likely contributes to fuel moisture measurement variability in most field campaigns.
We assessed the magnitude of among-sampler variability in plot-scale Calluna vulgaris fuel moisture measurements.
Seventeen individuals collected samples from six fuel layers hourly from 10:00 hours to 18:00 hours. We developed mixed effects models to estimate the among-sampler variability.
Fuel moisture measurements were highly variable between individuals sampling within the same plot, fuel layer, and time of day. The importance of among-sampler variability in explaining total measured fuel moisture variance was fuel layer dependent. Among-sampler variability explained the greatest amount of measurement variation in litter (58%) and moss (45%) and was more important for live (19%) than dead (4%) Calluna.
Both consideration of samplers within the experimental design and incorporation of sampler metadata during statistical analysis will improve understanding of spatio-temporal fuel moisture dynamics obtained from field-based studies.
Accounting for among-sampler variability in fuel moisture campaigns opens opportunities to utilise sampling teams and citizen science research to examine fuel moisture dynamics over large spatio-temporal scales.
Keywords: Calluna vulgaris, citizen science, diurnal, ecological field studies, fuel moisture dynamics, heathland, measurement error, mixed effects models, spatiotemporal variation, wildfire.
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