Sampling re-design increases power to detect change in the Great Barrier Reef's inshore water quality

Monitoring programs are fundamental to understanding the state and trend of aquatic ecosystems. Sampling designs are a crucial component of monitoring programs and ensure that measurements evaluate progress toward clearly stated management objectives, which provides a mechanism for adaptive manageme...

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Veröffentlicht in:	PloS one 2022-07, Vol.17 (7), p.e0271930
Hauptverfasser:	Lloyd-Jones, Luke R, Kuhnert, Petra M, Lawrence, Emma, Lewis, Stephen E, Waterhouse, Jane, Gruber, Renee K, Kroon, Frederieke J
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptive management Aquatic ecosystems Australia Biology and Life Sciences Coral Reefs Design Earth Sciences Ecology and Environmental Sciences Ecosystem Ecosystems Environmental monitoring Environmental Monitoring - methods Evaluation Management Marine parks Methods Monitoring Natural resource management Objectives Physical Sciences Resampling Research and Analysis Methods Sampling Sampling designs Statistical sampling Trends Water Water monitoring Water Quality Water quality management Water quality monitoring
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creator	Lloyd-Jones, Luke R Kuhnert, Petra M Lawrence, Emma Lewis, Stephen E Waterhouse, Jane Gruber, Renee K Kroon, Frederieke J
description	Monitoring programs are fundamental to understanding the state and trend of aquatic ecosystems. Sampling designs are a crucial component of monitoring programs and ensure that measurements evaluate progress toward clearly stated management objectives, which provides a mechanism for adaptive management. Here, we use a well-established marine monitoring program for inshore water quality in the Great Barrier Reef (GBR), Australia to investigate whether a sampling re-design has increased the program's capacity to meet its primary objectives. Specifically, we use bootstrap resampling to assess the change in statistical power to detect temporal water quality trends in a 15-year inshore marine water quality data set that includes data from both before and after the sampling re-design. We perform a comprehensive power analysis for six water quality analytes at four separate study areas in the GBR Marine Park and find that the sampling re-design (i) increased power to detect trends in 23 of the 24 analyte-study area combinations, and (ii) resulted in an average increase in power of 34% to detect increasing or decreasing trends in water quality analytes. This increase in power is attributed more to the addition of sampling locations than increasing the sampling rate. Therefore, the sampling re-design has substantially increased the capacity of the program to detect temporal trends in inshore marine water quality. Further improvements in sampling design need to focus on the program's capability to reliably detect trends within realistic timeframes where inshore improvements to water quality can be expected to occur.
doi_str_mv	10.1371/journal.pone.0271930
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subjects	Adaptive management Aquatic ecosystems Australia Biology and Life Sciences Coral Reefs Design Earth Sciences Ecology and Environmental Sciences Ecosystem Ecosystems Environmental monitoring Environmental Monitoring - methods Evaluation Management Marine parks Methods Monitoring Natural resource management Objectives Physical Sciences Resampling Research and Analysis Methods Sampling Sampling designs Statistical sampling Trends Water Water monitoring Water Quality Water quality management Water quality monitoring
title	Sampling re-design increases power to detect change in the Great Barrier Reef's inshore water quality
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