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Griffith University

Environmental Pollution 7421ENV

Semester 2 2011 Online

Primary Convenor: Dr Andrew Chan

Essay Assignment

Due date: 14 Oct 2011

Length: 3000 words

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 1

(W2) Critically evaluate key potential stressors associated with coastal agriculture and review scientific evidence that evaluate impact of pollutants on the Great Barrier Reef Marine Park.

The Great Barrier Reef Marine Park (GBRMP) stretches from Bundaberg to Cape

York Peninsula covering 2300 kilometres and an area of 344,400 square kilometers. It is the worlds largest reef system; one of its great natural wonders and represents 17% of the worlds coral communities (Department of Employment, Economic

Development and Innovation, 2010, p. 5). Along the Queensland coast there are 38 major catchments that impact the waters of the GBRMP. A critical review of the current scientific literature will explore the impacts of pollutants from coastal agriculture on the GBRMP. Whilst an overview of the entire GBRMP is necessary for an understanding of the impacts of these pollutants, specific examples will be drawn from the southern section of the marine park, including the Fitzroy River and Keppel

Bay. The future health and survival of the Great Barrier Reef (GBR) ecosystem is linked to environmental sound management decisions by relevant stakeholders that consider and mitigate their impacts to ecological appropriate levels.

To achieve this, a holistic approach to understanding the GBR ecosystem is crucial.

Land use and varying climatic zones in the GBR catchments are intrinsically linked to the marine environment, and catchments are one of the main mechanisms through which pollutants move into the GBRMP. The catchments that drain into the GBR cover 424,000 square km (

Land Use and the Great Barrier Reef

, 2003, p .2).

Figure 1: The diagram below outlines the coastal catchments along the Queensland coast.

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 2

(The Outlook Report, 2009)

These catchments include a variety of agricultural areas that range over regions described as dry and wet depending upon the seasonal rainfall. This large bioregion and the differing climates results in a variety of agricultural based activities and impacts on the reef due to differing farming practices and land use.

Figure 2: The major agricultural based activities of the GBR catchment.

(The Outlook Report, 2009)

In the southern section of the reef the weather may be considered dry tropics while further north (above Townsville) it is considered wet tropics with a greater rainfall; this results in different dynamics to catchment systems and corresponding impacts / stressors.

The Great Barrier Reef Marine Park Authority (GBRMPA) undertakes an assessment of the reef every five years. The last assessment in 2009 provides an overview of the reef’s health and identifies areas of concern. The report holds a high degree of credibility due to the number of scientists involved in its development, peer review and input from reference groups. The report identifies climate change, declining water quality from catchment run off, loss of coastal habitats from coastal development and remaining impacts from fishing and illegal fishing as priority issues affecting the resilience of the reef. The report further highlights inshore reefs as declining due to water quality and climate change (Australian Government, 2009, p. 6). Both of these impacts are associated with agriculture and its practices / management.

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 3

To evaluate the key potential stressors associated with coastal agriculture the following framework / overview will be used:

1.

Reduced water quality.

Increased sedimentation leading to turbidity (water quality) – major cause is a change in land practices.

2.

Agricultural based fertilizers.

Increased nutrients – nitrogen and potassium associated with fertilizers and sediments (Australian Government, 2009, p. 62)

3.

Pollutants from pesticides and herbicides.

This leads to mangrove dieback and increasing algae on coral reefs (Australian

Government, 2009, p. 7)

4.

Increase in greenhouse gases related to agricultural based activities.

Coastal agricultural activities contribute to increased greenhouse gases although at a minor global level. The changes in land use / land clearing (release of carbon dioxide), methane from livestock, and use of fossil fuels contributes to increased stresses related to coral bleaching and ocean acidification due to higher than historically average temperatures.

Research suggests that agricultural impacts are greater than urban-based impacts

(although there is a growing population within the GBR catchment and these pressures are likely to increase (

Land Use and the Great Barrier Reef

, 2003, p.

2). Therefore, informed decision making, support and appropriate management based upon scientific understanding / best practice will support the future of the Great

Barrier Reef. The Queensland Governments Reef Water Quality Protection Plan released in 2009 provides specific goals and targets to non-point of source pollution

(Department of the Premier and Cabinet, 2009). This plan had extensive research and input from a variety of government and non-government sources and has clear goals and water quality targets. It provides a plan with specific goals and targets to improve the GBR water quality in the future.

1. STRESSOR – REDUCED WATER QUALITY FROM SEDIMENTS

Changing land practices related to agriculture in the GBRMP catchments has resulted in increased sedimentation in the GBR waters. On average, 70 billion cubic metres of water leaves catchments and enters the reef system. Most of this runoff is during the summer wet season. The two general climatic zones, “the wet and the dry” function very differently. In the wet region there are numerous floods each year whereas in the dry river systems floods occur on average once per decade (

Land Use and the

Great Barrier Reef

, 2003, p .2). Thus the climate and the resulting agriculture lead to different impacts. The Great Barrier Reef Outlook Reports states that over the past

150 years sediment inflow on the GBR has increase four to five times and five to ten for some catchments (Australian Government - Information sheet Outlook Reports,

2009).

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 4

Sediments have increase due to land clearing, approximately half of the GBR catchments are cleared and most of the clearing is within the Fitzroy and Burdekin catchments. Droughts and the resulting loss of grass cover and clearing of vegetation increase erosion. Furthermore, the riparian vegetation acts as a natural filter. Some of this vegetation has been lost. This is a key issue within these catchment and various organisations such as the Fitzroy Basin Association and Landcare are working with landholders to educate and support reforestation of key land areas. The two large dry river systems, the Fitzroy and the Burdekin account for 64% of the catchment area of the GBR (Land Use and the Great Barrier Reef, 2003, p. 2). The major land use is open range cattle grazing on native and cleared pasture (refer to Figure 2). This represents 75% of the land use of the GBR catchment area. Sugarcane represents approximately 1% of the GBR catchment, however it is a major source of pollution. It is interesting to note that CRC research (Land Use and the Great Barrier Reef, 2003) estimates that 95% of the sediment entering the reef is derived from 13% of the

Burdiken catchment. These identified “hotspots” mean that targeting mitigation work can occur with environmental benefits being achieved in an effective way.

In terms of freshwater impacts from river systems the general plumes of water moves north and stays along the coast. Thus the greatest impact from the GBR catchment is inshore reefs within about 20 kilometers of the coast (

Land Use and the Great

Barrier Reef

, 2003, p. 4) With the GBR lagoon most of the sediment is deposited close to the river mouths and carried north and deposited in large bays such as

Bowling Green Bay. The impact of sediments on the GBR includes increased water turbidity, reducing light for photosynthecitic organisms, covering corals and algae and can make surfaces less suitable for juvenile organisms to settle. Thus the stress to the ecology of the reef is widespread and not isolated. Further impacts include fine sediments that can smother coral and cause them to use additional energy to remove the sediment. In addition it has been shown that sediments can cause changes to coral population structure, colony size, growth, recruitment, reproduction and survival

(Water Quality Guidelines for the Great Barrier Reef Marine Park, Revised Edition,

2010, p. 27). This is further demonstrated by Schaffelke, Waterhouse and Christie

(2002) with their review on water quality issues influencing the habitat quality of dugong protection areas. Their review identifies high risk dugong protection areas and explores potential impacts of degraded water quality on an endangered marine mammal.

A recent case study is the Fitzroy River Flood in 2011. Significant time and resources were contributed to gain a greater understanding of how floods impact the health of catchments and ecosystems. Proceeding the last major flood in 1991 there was significant coral mortality in Keppel Bay. The floods events in the dry tropics are decadal events and during the 2011 flood it was estimated that between 23 November

2010 and 1 February, 2011 the total suspended solids that passed the end of catchment monitoring system was 6302000 tonnes. This drains into Keppel Bay. This will have a significant impact upon Keppel Bay and various coral reefs have suffered high mortality rate to surface corals as a result of this flood event (A focus on the Fitzroy in Flood, 2011).

An example of positive action is the Department of Environment and Resource

Management and its report on Establishing Environmental Values, Water Quality

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 5

Guidelines and Water Quality Objectives for Fitzroy Basin Water (2010). This document has extensive consultation to identify high value areas, provide clear guidelines for water quality objectives. Through the Fitzroy Basin Association it has an action to reduce sediment (and related nutrients) from agricultural activities by

750,000 tonnes per annum within 10 years and to increase ground cover (Department of Resource Management, 2010). These appear to be significant actions and worthy goals that will support the GBRMP.

In order to combat increased sedimentation and declining water quality the Reef

Water Quality Protection Plan has two water quality targets that support improved water quality relating to sediments. This includes, by 2013, there will be a minimum of 50% late dry season groundcover on dry tropical grazing land and by 2020, there will be a minimum 20 % reduction in sediment load at the end of catchments. In addition the plan has 4 specific targets related to land management. (Reef Water

Quality Protection Plan, 2009). This plan and associated targets and actions represent a positive step, however it is the accumulative impacts that will continue to impact upon the reef and addressing water quality is a key action of the GBRMPA and State and National Government documentation. Addressing water quality is aimed at supporting the reefs reliance when faced with multiple pressure such as urban development, climate change and industry stressors.

Given to scale, magnitude and complexity of the issue this plan appears vital and realistic, however it will need every effort to ensure targets are met as many in the agricultural industries may see these additional measures as a time and financial cost, thus education and the cost / benefits to the agricultural industry need to be evident.

2. STESSOR - AGRICULTURAL BASED NUTRIENTS

Historically, nutrients within the GBR have been low. This was due to high vegetation coverage on the land and vegetation acting as a natural filter using many of the nutrients in the catchment systems. The increase in sediments entering the GBR is linked with increased nutrients, namely phosphorous and nitrogen entering river systems and eventually the GBR. Again the different climatic regions have differing characteristics. Dry topic river systems are generally more turbid (3000mg per litre) and much of the nitrogen and phosphorus are carried attached to fine sediment.

Whereas the wet tropic river systems tend to carry less suspended sediment at levels around 500 mg per litre and thus carry less nutrients. It has been estimated that 40% of nitrogen and 80% of phosphorus are carried with fine sediments thus the issue of sediments and nutrients entering the GBR is interrelated (Land Use and the Great

Barrier Reef, 2003, p. 3).

Brodies et al. (2003) estimates that there has been an increase of 4.3 times the natural export for nitrogen and an increase of 6.1 times for phosphorus. His research aims to identify sources of pollution and aims to establish effective targeting of management action to achieve results. Based upon the research there are recommendations of targeted management actions.

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 6

The increased nutrients provide opportunities for some organisms such as phytoplankton to bloom. A common measure is chlorophyll a. A link between crown of thorn starfish outbreaks and extreme rainfall and thus nutrients has also been suggested. This provides an example of an imbalanced system creating opportunities for some species (Water Quality Guidelines for the Great Barrier Reef Marine Park,

Revised Ed. 2010). This theory is supported by the work of Brodie et al. (2004) who examines if increased nutrient inputs are responsible for crown of thorns starfish

(COTS) outbreaks. His research found that larval development, growth and survival of COTS increase almost 10 fold with doubled concentrations of large phyto-plankton which are now doubled that of previous times.

In order to understand if management actions are having an impact, monitoring and collecting data is crucial. However, monitoring the GBR is a challenging task due to it size and remote locations. Modern technology is providing an excellent opportunity to establish detailed information and to observe tends to water quality. The Reef Rescue

Monitoring Program: using remote sensing for GBR wide water quality Final Report

2009 / 10 provides a valuable insight into the power of satellite technology to provide detail information on a broad scale. This report monitors concentrations of chlorophyll a, total suspended solids, water clarity, and dissolved organic matter. The report also makes a comparison to the water quality guidelines and any exceedance of these. There are many benefits to satellite monitoring including whole of marine system monitoring, cost effectiveness and the ability to monitor individual events to gain a deeper understanding into the GBR ecology. Whilst this technology is improving it will aid mangers in monitoring and decision making to support the health of the reef (Vittorio et al, 2010). This monitoring differs from traditional monitoring and will support evaluating impacts on the GBR.

In additional to monitoring the GBRMPA has established Water Quality Guidelines for the Great Barrier Reef Marine Park (revised edition 2010). This provides guidance for sediment, nutrients and pesticides that aim to support protection and maintenance of ecosystems. At times these guidelines are exceeded.

3. POLLUTANTS FROM LAND BASED PESTICIDEDS AND HERBICIDES

Pesticide use has increased in areas under crop cultivation within the GBR catchment and there are now seven main herbicides used. These include diuron, atrazine, ametryn, simazine, hexazinone, 2,4-D and tebuthiuron with the first three being most likely to reach marine environments (Water Quality Guidelines for the Great Barrier

Reef Marine Park, Revised Edition, 2010, p. 29). The concentrations found in a body of water are impacted by numerous factors such as proximity to system, intensity and methods of application, breakdown rates, temperature, and history of flushing events.

These factors add complexity to there use.

Species within the GBRMP that are sensitive to herbicides include corals, sea grass, mangroves and algae. Due to significant areas of the GBR catchment being utilized for agricultural purposes the stressor from pesticides and herbicides are increasing with increase land being used for agricultural purposes and increase use of agricultural based chemicals.

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 7

An extensive monitoring program is conducted by the National Research Centre for

Environmental Toxicology and in 2010 a report was release outlining 5 years of monitoring for pesticides and herbicides in the GBRMP. This type of extensive monitoring provides important data to determine successes of management action within the agriculture industry. The report highlighted the significant stressors that organic chemicals (pesticides / herbicides) are having in the Mackay / Whitsunday region. Most of this impact comes from the sugar cane industry (Kennedy et al. 2010).

Herbicides, including diuron and atrazine and 2,4-D are used in the sugar industries.

The industry has grown substantially and the use of herbicides has increased in the magnitude 3 to 7 times in the past 30 to 40 years. Sea grass communities are often found inshore and the impacts of herbicides could impact sea grass communities close to river systems. The impact of herbicides may also be considerable upon sea grasses, which often occur in the inshore zone and are important food sources for dugong and green turtles. Haynes et al. carried out trails to determine the impact of diuron on sea grass and reports that at all concentration diuron showed some degree of toxicity which was demonstrated in a decline in photosynthetic capacity. His studies indicate that herbicide concentrations present a risk to inshore sea grasses within the GBR.

Haynes also alerts to the combined pressures of other stressors at the same time and how these combined stressors will impact organisms is unknown (Haynes, 2000).

Lewis et al. (2009) Herbicides: A new threat to the Great Barrier Reef states that little is known about pesticide residues. Thus further research is required in this field. It is known that relatively low levels of herbicides residues can decrease marine plant and coral productivity. The major concern is that this will increase pressures on an ecosystem, which already has existing pressures. Lewis predicts that the mixture of herbicides residues in river discharges has the capacity to produce cumulative chronic effects on sensitive species that may cause a change in community structure of mangrove, sea grass and coral reef ecosystems. It may also lead to decreased biodiversity. Lewis acknowledges the work being done by government agencies and suggests “moderate optimism for the long-term resilience of the GBR (Lewis, 2009).

Further evidence to support the damaging impacts of herbicides includes the work of

Dukes et al. (2004) who correlated severe and widespread dieback of mangroves in the Mackay region to the use of herbicides, in particular diuron. He further states that the likely consequences of this dieback include declines in water quality, nutrient and sediment deposition and further dispersal of toxic chemicals.

To analyse all pesticides and herbicides is beyond the scope, so Diuron will be discussed as an example of herbicides used. Recently diuron has undergone an environmental assessment (July 2011) by the Australian Government – Australian

Pesticides and Veterinary Medicines Authority. This report reviewed many international reviews and the use of diuron appears to be more restricted or being phased out or phased out in other counties. It suggests that Queensland use of diuron has increased considerably (Australian Pesticides and Veterinary Medicines

Authority, 2011, p. 7) In addition the Water Quality Guidelines for the Great Barrier

Reef Marine Park, Revised Edition (2010) sets trigger values of 0.9, 1.6 and 2.3 ug/L for protection of 99, 95 and 90 of species respectively. It has a half life that varies from 5 to 372 days (Water Quality Guidelines for the Great Barrier Reef Marine Park,

Revised Edition, 2010, p. 71). As greater understanding of the impact of herbicides

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 8

and pesticides grows and best practice models increase, there may be a decrease in these chemicals entering the GBR. There is much more to be learnt in regards to the impacts of agricultural chemicals, however clear evidence is available that they are a stressor to marine ecosystems.

4. AGRICULUTRAL BASED CLIMATE CHANGE IMPACTS

The threat of climate change and warming waters posses a significant threat to the

GBR in terms of coral bleaching and ocean acidification. Whilst the issue is a global in nature and a solution must involve many other nations, it is the combined impact of all greenhouse gasses causing impacts. Although the agriculture sector within the

GBR catchment is only a very small percentage of emissions. Agriculture is 20% of national emissions (Environmental Pollution Course Materials), due to the scale of the threat, improvements in decreasing emissions (efficiency options) would support the

GBR future. In terms of agricultural impact these include the use of fossil fuels, methane from livestock and clearing / burning of vegetation. Further actions or improved management practices could reduce negative impacts from these practices.

Research indicates that the inshore southern section of the GBR is most vulnerable to the impacts of climate change. With the GBR facing degraded water quality, corals are less able to recover from bleaching and corals exposed to excess nutrients and sediments have greater recovery times after mortality events (Johnston, N, et al.

2008). Furthermore, there is evidence to support decreased coral growth in more acidic waters. In addition climate change related to warmer waters, there may be increased intensity of rainfall events leading to increased erosion and sediments on the reef.

The GBRMPA has set a guideline trigger level for sea temperature at an increase of 1 degree above long term average maximum (Water Quality Guidelines for the Great

Barrier Reef Marine Park, Revised Edition 2010, p. 29). If these values are exceeded the GBR faces significant challenges to its ecology.

Positive actions to address related climate change issues include the Queensland

Government action to reduce land clearing. Queensland had some of the highest rates of land clearing in the world and this has multiple impacts to the GBR. Furthermore,

The Australian Governments action to introduce a carbon tax is an initiative to reduce carbon dioxide emission. This measure is critical in reducing emissions to support the future health of the GBRMP.

CONCLUSION

The Great Barrier Reef faces significant challenges for its long term survival. The

GBRMPA Outlook Report (2009) gives a poor rating to its future health. GBRMPA acknowledge climate change, as the most significant threat to the GBR and a global solution and actions must be made to mitigate this threat to the GBR. Australia should make a reasonable and fair contribution to reduce greenhouse gases or it faces degraded natural assets including the GBR. In contrast, water quality is within the scope of our direct management and this provides an opportunity to act with greater impact. Agriculture is a major contributor to decreased water quality and its key

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 9

related stresses of sedimentation, additional nutrients and increased pesticides and herbicides. These must be mitigated to ensure the long-term survival of the GBR.

Addressing water quality also gives the reef an improved resilience to combat the impacts of climate change. Actions taken by GBRMPA reflect sound environmental management practices including the precautionary and holistic and integrated principles (Environmental Pollution Study Guide), albeit their effectives to deal with climate change, water quality and overall outlook is rated poor.

Agriculture, with support needs to change its practices to reduce sedimentation, reduce nutrients and reduce our reliance upon pesticides and herbicides. This requires significant changes, education, and willingness for the agricultural industry to strive for detailed goals and targets. While significant and ongoing progress has been made, the impacts coastal agriculture is having are significant and require rapid action with a long-term approach to make improvements. Continued monitoring is also crucial to determine successes or areas for more drastic actions.

If key Government Agencies and the agricultural industry can foster positive partnerships and a shared vision that includes continued positive actions, research and education it will give the GBR its best opportunity for survival as it faces numerous and significant threats. Landowners and stakeholders must embrace a willingness to act and change to ensure high water quality water enters to GBR. This will support to

GBR ecosystem and give its best chance of survival for the long term. This will benefit us ecologically, economically and socially so this great natural resource is there for future generations.

Lee Fisher Student No. s2168732 Environmental Pollution Sem 2, 2011 10

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