Abstract
Water clarity is a key factor for the health of marine ecosystems. The Australian Great Barrier Reef (GBR) is located on a continental shelf, with >35 major seasonal rivers discharging into this 344,000 km2 tropical to subtropical ecosystem. This work investigates how river discharges affect water clarity in different zones along and across the GBR. For each day over 11 years (2002–2013) we calculated ‘photic depth’ as a proxy measure of water clarity (calibrated to be equivalent to Secchi depth), for each 1 km2 pixel from MODIS-Aqua remote sensing data. Long-term and seasonal changes in photic depth were related to the daily discharge volumes of the nearest rivers, after statistically removing the effects of waves and tides on photic depth. The relationships between photic depths and rivers differed across and along the GBR. They typically declined from the coastal to offshore zones, and were strongest in proximity to rivers in agriculturally modified catchments. In most southern inner zones, photic depth declined consistently throughout the 11-year observation period; such long-term trend was not observed offshore nor in the northern regions. Averaged across the GBR, photic depths declined to 47% of local maximum values soon after the onset of river floods, and recovery to 95% of maximum values took on average 6 months (range: 150–260 days). The river effects were strongest at latitude 14.5°–19.0°S, where river loads are high and the continental shelf is narrow. Here, even offshore zones showed a >40% seasonal decline in photic depth, and 17–24% reductions in annual mean photic depth in years with large river nutrients and sediment loads. Our methodology is based on freely available data and tools and may be applied to other shelf systems, providing valuable insights in support of ecosystem management.
Highlights
The ecology of marine ecosystems is strongly governed by water clarity
This study presents a conceptual and statistical methodology to examine the influence of environmental drivers on marine water clarity
The use of remote sensing data was effective for determining the drivers of Great Barrier Reef (GBR) water clarity, and suited given the large size and geographic and hydrodynamic complexity of this region
Summary
The ecology of marine ecosystems is strongly governed by water clarity (turbidity, or transparency). Reduced water clarity leads to a significant loss in light, affecting photosynthetic organisms such as corals and seagrasses (Anthony and Hoegh-Guldberg, 2003; Collier et al, 2012). Low water clarity limits the depth distribution of seagrasses and coral reefs to shallow waters, with a daily average of 4e8 mol photons mÀ2 dayÀ1 (~6e8% of surface irradiance) considered to be a typical minimum light requirement for ecosystem maintenance (Gattuso et al, 2006). Reduced water clarity is often related to increasing concentrations of suspended particles and their associated nutrients, which benefit filter- and deposit-feeding animals. The nutrients associated with reduced water clarity can lead to shifts from corals to macroalgae, and at more severe conditions, macroalgae are replaced by heterotrophic filter feeders (Birkeland, 1988; De'ath and Fabricius, 2010). Water clarity can even affect coral reef fishes, including their larval settlement, gill structures, and predator-prey interactions (Wenger et al, 2011, 2013; Hess et al, 2015)
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