Saltwater crocodiles are slowly returning to Bali and Java. Can we learn to live alongside them?

 Shutterstock Brandon Michael Sideleau, Charles Darwin University

On January 4 this year, a three-metre saltwater crocodile heaved itself out of the water and up the beach. Nothing unusual about that – except this croc was on Legian Beach, one of Bali’s most popular spots. The emaciated reptile later died.

Only four months later, a large crocodile killed a man who was spearfishing with friends in Lombok’s Awang Bay, about 100 kilometres east of Bali. Authorities caught it and transferred it to captivity.

You might not associate crocodiles with Bali. But the saltwater crocodile once roamed most of Indonesia’s waters, and attacks are still common in some regions. I have been collecting records of crocodilian attacks since 2010, as the creator of the worldwide database CrocAttack. What’s new is that they’re beginning to return to areas where they were wiped out.

Does this mean tourists and residents should be wary? It’s unlikely these islands can host anywhere near the same population densities as the wide, fish-filled rivers of Australia’s tropical north. And in Bali, it’s unlikely we’ll see any crocodile recovery because of the importance of beaches to tourism and a high human population.

This 4.6-metre saltwater crocodile was captured in Lombok after the fatal attack in May. Bali Reptile Rescue, CC BY-ND

What happened to Indonesia’s crocodiles?

Saltwater crocodiles (Crocodylus porosus) are also known as estuarine crocodiles, as they prefer to live in mangrove-lined rivers. They’re the largest living reptile, reaching up to seven metres in length – far larger than Indonesia’s famous Komodo dragon, which tops out at three metres.

Historically, crocodiles lived throughout the Indonesian archipelago. We have records of attacks on humans in Bali from the early 20th century and across much of Java until the 1950s. Even Indonesia’s capital, Jakarta, had crocodiles resident in many rivers running through the city.

Crocodiles in Bali and Lombok were killed off by the mid-20th century, and later across Java. But they survived in more remote parts of the island nation.

Salties are now being regularly sighted in Indonesia’s densely populated island of Java, including in seas off Jakarta. At least 70 people are killed by crocs every year across the archipelago, with the highest numbers of attacks being reported from the Bangka-Belitung islands off Sumatra and the provinces of East Kalimantan, East Nusa Tenggara, and Riau.

Are crocodiles returning in numbers?

These incidents means numbers are increasing. But recovery may not be as significant as it seems.

On many Indonesian islands, there’s very limited mangrove habitat suitable for crocodiles, and many creeks and rivers may be naturally too small for more than a small number of them. Even a small population recovery could quickly fill up the croc capacity of estuaries and creeks. These crocodiles are the most territorial of all crocodilians. Dominant males push out smaller male crocodiles, who set out in search of new habitat.

To date, Indonesia’s crocodile surveys reveal mostly small and low-density populations. But even the arrival of a single crocodile into human territory can spark conflict – and threaten the conservation of the species.

Worldwide, saltwater crocodiles are listed as a species of least concern on the IUCN Red List of Threatened Species, thanks to their full population recovery in parts of northern Australia after hunting was banned in the early 1970s. But in Cambodia, Thailand, and Vietnam the species is extinct.

Even in sparsely populated northern Australia, there’s still conflict between humans and crocs, though this conflict is comparatively rare. In Indonesia, the problem is compounded by a massive human population which puts pressure on crocodile habitat.

Where are Bali’s crocs coming from?

You might look at a map and think crocodiles moving back into Bali are coming from Australia. But there is currently no evidence of significant crocodile movement between Australia and Indonesia. It would be a brave crocodile to swim more than 1,000 kilometres from Australia to Bali.

What we are likely witnessing is a crocodile exodus from nearby areas, though we would need to do genetic analysis to prove it. That’s because the surviving croc population centres are much closer than Australia. For Bali and Lombok, crocodiles are likely migrating from the islands to the east, such as Flores, Lembata, Sumba and Timor.

The most likely source of Java’s crocodile arrivals is southern Sumatra, which is less than 30km from Java at its nearest. This area has long been prone to crocodile attacks.

What does this mean for residents and tourists?

Earlier this month, a relatively large crocodile was photographed basking on a large fish trap in West Lombok, less than 50km from the tourist hotspot of the Gili Islands.

The spike in sightings and attacks suggests we’re going to have to find ways of living alongside these reptiles. The coastal waters and estuaries of Lombok and western Java are now likely home to a small resident population.

What can be done to prevent attacks? First, people have to know that crocs are back. Increasing crocodile awareness and caution is vital to save lives.

Some researchers believe attacks on us and our livestock get more likely if mangroves have been destroyed or fishing grounds fished out. Protecting crocodile habitat and prey species can both secure the future of the species and cut the risk of attacks.

Does it mean you should cancel your next Bali trip? No. While restoration efforts have brought back tracts of mangroves along some coastlines in Bali, the sheer popularity of the island means it’s unlikely any crocodile population will ever be reestablished there.

But we could well see crocodiles slowly return to less populated parts of Java and Lombok. While that may fill us with anxiety, they’re a vital part of the ecosystem. Crocodiles are meant to be there.

Brandon Michael Sideleau, PhD student studying human-saltwater crocodile conflict, Charles Darwin University

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Read More........→October 30, 2023

Analyzing ways to help golden eagle populations weather wind-energy growth

"We are taking basic information about golden eagle ecology in the Anthropocene and developing it into predictive frameworks for how to protect them," says Eric Lonsdorf, Emory assistant professor of environmental sciences.

By Carol Clark: Wind energy is a major component of the U.S. clean-energy goals. Already one of the fastest growing and lowest-cost sources of electricity in the country, it is poised for even more rapid growth, according to the U.S. Department of Energy.

Wind power, however, does not come without trade-offs, including some negative impacts on wildlife. Throughout the United States, for example, it’s been estimated that as many as three golden eagles per wind farm are killed each year by wind turbines.

“Renewable energy sources, including wind energy, are critical for us to achieve a net-zero emissions future,” says Eric Lonsdorf, assistant professor of environmental sciences at Emory University. “We need to address conflicts between renewable energy and wildlife conservation so that we can combat climate change while also limiting damage to biodiversity.”

Lonsdorf and colleagues are developing data-driven methods to determine how much effort is needed to save golden eagles in order to offset the impact of wind turbines on their populations.

The Journal of Wildlife Management recently published their latest model for calculating the benefit of one mitigation strategy — removal of large, road-killed animals that can lead to golden eagles getting hit by cars.

Quantifying the benefits of natural capital:

Lonsdorf is an expert in natural capital, or the quantifiable benefits that nature provides humans. He translates ecological principles and data into computer models that enable industry leaders and policymakers to better manage natural resources.

Co-authors of the current study include James Gerber and Deepak Ray, from the University of Minnesota; Steven Slater, from HawkWatch International; and Taber Allison, from the Renewable Energy Wildlife Institute.

The U.S. Fish and Wildlife Service (FWS) monitors golden eagle populations, which are protected through the Bald and Golden Eagle Protection Act and the Migratory Bird Treaty Act. Threats to golden eagles include loss of habitat and prey.

Additional threats that are directly linked to human activities include illegal shootings, electrocution at power poles, lead poisoning from consuming parts of bullets in the entrails of deer carcasses discarded at the site of hunters’ kills, collisions with cars at sites where the birds are scavenging roadkill and collisions with the blades of a wind turbine.

Across the western United States, hundreds of wind turbines have gone up in sage-brush flats that are part of golden eagles’ core habitat, and many more turbines are planned. In order to meet the permit requirements of the FWS, wind-energy companies must agree to mitigate their impact on the animals by offsetting the predicted number of golden eagles that will fly into their turbines each year.

Currently, the only offset strategy approved by the FWS for wind-energy companies is to retrofit power poles to prevent golden eagles from becoming electrocuted.

Adding empirical data:

For the past five years, Lonsdorf and his colleagues have combined their expertise to develop a range of potential offset strategies for golden eagle fatalities.

Their current paper — an updated model for golden eagle mortality due to vehicle collisions based on data from Wyoming — considered myriad factors such as the population density for golden eagles in the region, the number and size of deer roadkill carcasses expected and the traffic volume on the roads. The model also incorporated observational evidence of eagle-carcass roadside interactions obtained by motion-triggered cameras, data that was lacking in a previous model the researchers created.

The addition of this empirical data allowed the researchers to make estimates for how long a golden eagle typically spends at a carcass, how the decay rate of the carcass affects the number of visits from eagles and the effects of seasonality on the scavenging behavior of the eagles.

The model results suggest that carcass relocation is a viable golden eagle mitigation strategy that could save up to seven golden eagles annually in some Wyoming counties. On average, the model indicates that the prompt removal of four roadside carcasses would save at least one golden eagle.

The researchers can make a user-friendly version of the prediction framework available to the FWS and wind-energy companies if the FWS decides to approve carcass removal as an eagle mortality offset strategy. “We’re taking basic information about golden eagle ecology in the Anthropocene and developing it into predictive frameworks for how to protect them,” Lonsdorf says. “As wind energy continues to grow, more mitigation strategies will likely be needed. Our goal is to provide scientific evidence for a portfolio of methods to help accomplish a zero-net loss of golden eagles from wind-energy facilities.”eScienceCommons: Analyzing ways to help golden eagle populations we

Read More........→October 14, 2023

South Africa’s great white sharks are changing locations – they need to be monitored for beach safety and conservation

South Africa is renowned for having one of the world’s biggest populations of great white sharks (Carcharodon carcharias). Substantial declines have been observed, however, in places where the sharks normally gather on the coast of the Western Cape province. Sharks congregate at these locations to feed, interact socially, or rest.

In Cape Town, skilled “shark spotters” documented a peak of over 300 great white shark sightings across eight beaches in 2011, but have recorded no sightings since 2019. These declines have sparked concerns about the overall conservation status of the species.

Conserving great white sharks is vital because they have a pivotal role in marine ecosystems. As top predators, they help maintain the health and balance of marine food webs. Their presence influences the behaviour of other marine animals, affecting the entire ecosystem’s structure and stability.

Marine biologists like us needed to know whether the decline in shark numbers in the Western Cape indicated changes in the whole South African population or whether the sharks had moved to a different location.

To investigate this problem, we undertook an extensive study using data collected by scientists, tour operators and shore anglers. We examined the trends over time in abundance and shifts in distribution across the sharks’ South African range.

Our investigation revealed significant differences in the abundance at primary gathering sites. There were declines at some locations; others showed increases or stability. Overall, there appears to be a stable trend. This suggests that white shark numbers have remained constant since they were given protection in 1991.

Looking at the potential change in the distribution of sharks between locations, we discovered a shift in human-shark interactions from the Western Cape to the Eastern Cape. More research is required to be sure whether the sharks that vanished from the Western Cape are the same sharks documented along the Eastern Cape.

The stable population of white sharks is reassuring, but the distribution shift introduces its own challenges, such as the risk posed by fisheries, and the need for beach management. So there is a need for better monitoring of where the sharks are.

Factors influencing shark movements

We recorded the biggest changes between 2015 and 2020. For example, at Seal Island, False Bay (Western Cape), shark sightings declined from 2.5 sightings per hour in 2005 to 0.6 in 2017. Shifting eastward to Algoa Bay, in 2013, shore anglers caught only six individual sharks. By 2019, this figure had risen to 59.

The changes at each site are complex, however. Understanding the patterns remains challenging.

These predators can live for more than 70 years. Each life stage comes with distinct behaviours: juveniles, especially males, tend to stay close to the coastline, while sub-adults and adults, particularly females, venture offshore.

Environmental factors like water temperature, lunar phase, season and food availability further influence their movement patterns.

Changes in the climate and ocean over extended periods might also come into play.

As adaptable predators, they target a wide range of prey and thrive in a broad range of temperatures, with a preference for 14–24°C. Their migratory nature allows them to seek optimal conditions when faced with unfavourable environments.

Predation of sharks by killer whales

The movement complexity deepens with the involvement of specialist killer whales with a taste for shark livers. Recently, these apex predators have been observed preying on white, sevengill and bronze whaler sharks.

Cases were first documented in 2015 along the South African coast, coinciding with significant behavioural shifts in white sharks within Gansbaai and False Bay.

Although a direct cause-and-effect link is not firmly established, observations and tracking data support the notion of a distinct flight response among white sharks following confirmed predation incidents.

More recently, it was clear that in Mossel Bay, when a killer whale pod killed at least three white sharks, the remaining sharks were prompted to leave the area.

Survival and conservation of sharks

The risk landscape for white sharks is complex. A study published in 2022 showed a notable overlap of white sharks with longline and gillnet fisheries, extending across 25% of South Africa’s Exclusive Economic Zone. The sharks spent 15% of their time exposed to these fisheries.

The highest white shark catches were reported in KwaZulu-Natal, averaging around 32 per year. This emphasised the need to combine shark movement with reliable catch records to assess risks to shark populations.

As shark movement patterns shift eastward, the potential change in risk must be considered. Increased overlap between white sharks, shark nets, drumlines (baited hooks) and gillnets might increase the likelihood of captures.

Beach safety and management adaptation

Although shark bites remain a low risk, changing shark movements could also influence beach safety. The presence of sharks can influence human activities, particularly in popular swimming and water sports areas. Adjusting existing shark management strategies might be necessary as distributions change.

Increased signage, temporary beach closures, or improved education about shark behaviour might be needed.

In Cape Town, for example, shark spotters have adjusted their efforts on specific beaches. Following two fatal shark incidents in 2022, their programme expanded to Plettenberg Bay. Anecdotal evidence highlights additional Eastern Cape locations where surfers and divers encounter more white sharks than before.

Enhanced monitoring and long-term programmes

Further research is required to understand the factors behind the movements of sharks and their impact on distribution over space and time. Our study underscores the importance of standardising data collection methods to generate reliable abundance statistics across their entire range. Other countries suffer from the same problem.

Additionally, we propose establishing long-term monitoring programmes along the Eastern Cape and continuing work to reduce the number of shark deaths.

Sarah Waries, a master’s student and CEO of Shark Spotters in Cape Town, contributed to this article.

Alison Kock, Marine Biologist, South African National Parks (SANParks); Honorary Research Associate, South African Institute for Aquatic Biodiversity (SAIAB), South African Institute for Aquatic Biodiversity; Alison Towner, Marine biologist, Rhodes University; Heather Bowlby, Research Lead, Fisheries and Oceans Canada; Matt Dicken, Adjunct Professor of Marine Biology, Nelson Mandela University, and Toby Rogers, PhD Candidate, University of Cape Town

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Read More........→September 21, 2023