Boris Johnson overstates Morrison’s climate ambition, as Australia-UK trade agreement reached

British Prime Minister Boris Johnson put Scott Morrison on the spot when he told their joint news conference he thought the Australian PM had “declared for net zero by 2050”.

When Johnson made the statement a journalist interjected to point out Morrison’s policy was to get to net zero “preferably” by 2050.

Johnson pressed on to say this was “a great step forward when you consider[…] the situation Australia is in. It’s a massive coal producer. It’s having to change the way things are orientated, and everybody understands that.

"You can do it fast. In 2012 this country had 40% of its power from coal. It’s now less than 2%, going down the whole time. […] I’m impressed by the ambition of Australia. Obviously we’re going to be looking for more the whole time, as we go into COP26 in November.”

The net zero moment came as the two stood together to announce they had reached an in-principle agreement on a free trade deal between Britain and Australia – the first such deal the United Kingdom has done post Brexit.

Johnson had been asked whether he wanted Australia to go beyond its present 2030 emissions reduction target.

Morrison has been under strong pressure from both Johnson and United States President Joe Biden to embrace the 2050 target. But he has so far not done so, despite edging towards it. His position is to get to net zero “as soon as possible, preferably by 2050.”

Formally embracing the target would threaten a fight within the Nationals that could destabilise the party’s leader Michael McCormack.

Nationals Senate leader Bridget McKenzie warned this week:

“There is no agreement with the second party of this Coalition government on any target date for zero emissions. In fact it would fly in the face of the Nationals public policy commitment.”

The free trade agreement, which still has details to be finalised, would reduce barriers on the mobility of workers between the two countries as well on trade in goods and services.

The deal would promote more exchange of young people, allowing them to stay and work in each country for three years instead of two. This arrangement would apply to people up to age 35 rather than 30, as at present.

The federal government says Australian producers and farmers would “receive a significant boost by getting greater access to the UK market” while Australian consumers would “benefit from cheaper products, with all tariffs eliminated within five years, and tariffs on cars, whisky, and the UK’s other main exports eliminated immediately” the agreement started.

Australia would within five years place less onerous conditions on British backpackers, who presently have to spend a set time working in agriculture, or other sectors of labour shortage in regional Australia, to get an extension of their visa.

A separate agriculture visa would be established for UK and Australian visa holders, to get more two way traffic (for example, of shearers) in the agricultural sector.

Over 10 to 15 years the UK would liberalise Australian imports of beef and sheep meat, with shorter periods for sugar and dairy products.

The agricultural sectors in both Britain and Australia expressed concerns when the agreement was being negotiated. In Australia farmers have been worried about the possibility of losing labour if the conditions on backpackers were scrapped.

Johnson said the deal would be good for British car manufacturers and the export of British financial and other services, and he hoped for the agricultural sectors on both sides.

On agriculture “we’ve had to negotiate very hard. […] This is a sensitive sector for both sides, and we’ve got a deal that runs over 15 years and contains the strongest possible provisions for animal welfare.”

The removal of the farm work requirement would make it easier for British people and young people to go and work in Australia, he said.

Morrison said the deal would open the pathway to Britain’s entry into the The Comprehensive and Progressive Agreement for Trans-Pacific Partnership (CPTPP).

He also indicated it was “enormously helpful” in the context of the difficulties with China. “Where you have challenges with one trading partner from time to time, then the ability to be able to diversify your trade into more and more countries is incredibly important.”

Morrison and Johnson discussed the final points of the agreement in principle over a dinner meeting at 10 Downing Street. Their talks also included climate change.

Michelle Grattan, Professorial Fellow, University of Canberra

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

Australia needs construction waste recycling plants — but locals first need to be won over

Strong community opposition to a proposed waste facility in regional New South Wales made headlines earlier this year. The A$3.9 million facility would occupy 2.7 hectares of Gunnedah’s industrial estate. It’s intended to process up to 250,000 tonnes a year of waste materials from Sydney.

Much of this is construction waste that can be used in road building after processing. Construction of the plant will employ 62 people and its operation will create 30 jobs. Yet every one of the 86 public submissions to the planning review objected to the project.

Residents raised various concerns, which received widespread local media coverage. They were concerned about water management, air quality, noise, the impact of hazardous waste, traffic and transport, fire safety and soil and water. For instance, a submission by a local businessman and veterinary surgeon stated:

“The proposed facility is too close to town, residences and other businesses […] Gunnedah is growing and this proposed development will be uncomfortably close to town in years to come.”

The general manager of the applicant said descriptions such as “toxic waste dump” were far from accurate.

“It’s not a dump […] Its prime focus is to reclaim, reuse and recycle.”

He added: “[At present] the majority of this stuff goes to landfill. What we’re proposing is very beneficial to the environment, which is taking these resources and putting them back into recirculation. The reality is the population is growing, more waste is going to get generated and the upside is we’re much better processing and claiming out of it than sending it to landfill.”

Read more: We create 20m tons of construction industry waste each year. Here's how to stop it going to landfill

Why are these facilities needed?

According to the latest data in the National Waste Report 2020, Australia generated 27 million tonnes of waste (44% of all waste) from the construction and demolition (C&D) sector in 2018-19. That’s a 61% increase since 2006-07. This waste stream is the largest source of managed waste in Australia and 76% of it is recycled.

However, recycling rates and processing capacities still need to increase massively. The environmental impact statement for the Gunnedah project notes Sydney “is already facing pressure” to dispose of its growing construction waste. Most state and national policies – including the NSW Waste Avoidance and Resource Recovery Strategy 2014-2021, NSW Waste and Resource Recovery Infrastructure Strategy and 2018 National Waste Policy – highlight the need to develop infrastructure to effectively manage this waste.

Read more: The 20th century saw a 23-fold increase in natural resources used for building

Why, then, do people oppose these facilities?

Public opposition to new infrastructure in local neighbourhoods, the Not-in-My-Back-Yard (NIMBY) attitude, is a global phenomenon. Australia is no exception. We have seen previous public protests against waste facilities being established in local areas.

The academic literature reports the root causes of this resistance are stench and other air pollution, and concerns about impacts on property values and health. Factors that influence individuals’ perceptions include education level, past experience of stench and proximity to housing.

What are the other challenges of recycling?

Our research team at RMIT University explore ways to effectively manage construction and demolition waste, with a focus on developing a circular economy. Our research shows this goal depends heavily on the development of end markets for recycled products. Operators then have the confidence to invest in recycling construction and demolition waste, knowing it will produce a reasonable return.

Read more: The planned national waste policy won't deliver a truly circular economy

A consistent supply of recycled material is needed too. We believe more recycling infrastructure needs to be developed all around Australia. Regional areas are the most suitable for this purpose because they have the space and a need for local job creation.

To achieve nationwide waste recycling, however, everyone must play their part. By everyone, we mean suppliers, waste producers, waste operators, governments and the community.

Today we are facing new challenges such as massive urbanisation, shortage of virgin materials, increasing greenhouse gas emissions and bans on the export of waste. These challenges warrant new solutions, which include sharing responsibility for the waste we all generate.

Read more: A crisis too big to waste: China's recycling ban calls for a long-term rethink in Australia

What can be done to resolve public concerns?

Government has a key role to play in educating the public about the many benefits of recycling construction and demolition waste. These benefits include environmental protection, more efficient resource use, reduced construction costs, and job creation.

Government must also ensure communities are adequately consulted. A local news report reflected Gunnedah residents’ concern that the recycling facility’s proponent had not contacted them. They initiated the contact. One local said:

“I do understand the short-term financial gains a development like this will bring to the community, but also know the financial and environmental burden they will cause.”

Feedback from residents triggered a series of consultation sessions involving all parties.

A robust framework for consulting the community, engaging stakeholders and providing information should be developed to accompany any such development. Community education programs should be based on research.

For instance, research indicates that, unlike municipal waste recycling facilities, construction and demolition waste management facilities have negligible to manageable impact on the environment and residents’ health and well-being. This is due to the non-combustible nature of most construction materials, such as masonrt.

Such evidence needs to be communicated effectively to change negative community attitudes towards construction and demolition waste recycling facilities. At RMIT, through our National Construction & Demolition Waste Research and Industry Portal, we continue to play our part in increasing public awareness of the benefits.

Read more: With the right tools, we can mine cities

Salman Shooshtarian, Research Fellow, RMIT University and Tayyab Maqsood, Associate Dean and Head of of Project Management, RMIT University

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

An act of God, or just bad management? Why trees fall and how to prevent it

The savage storms that swept Victoria last week sent trees crashing down, destroying homes and blocking roads. Under climate change, stronger winds and extreme storms will be more frequent. This will cause more trees to fall and, sadly, people may die.

These incidents are sometimes described as an act of God or Mother Nature’s fury. Such descriptions obscure the role of good management in minimising the chance a tree will fall. The fact is, much can be done to prevent these events.

Trees must be better managed for several reasons. The first, of course, is to prevent damage to life and property. The second is to avoid unnecessary tree removals. Following storms, councils typically see a spike in requests for tree removals – sometimes for perfectly healthy trees.

A better understanding of the science behind falling trees – followed by informed action – will help keep us safe and ensure trees continue to provide their many benefits.

Why trees fall over

First, it’s important to note that fallen trees are the exception at any time, including storms. Most trees won’t topple over or shed major limbs. I estimate fewer than three trees in 100,000 fall during a storm.

Often, fallen trees near homes, suburbs and towns were mistreated or poorly managed in preceding years. In the rare event a tree does fall over, it’s usually due to one or more of these factors:

1. Soggy soil

In strong winds, tree roots are more likely to break free from wet soil than drier soil. In arboriculture, such events are called windthrow.

A root system may become waterlogged when landscaping alters drainage around trees, or when house foundations disrupt underground water movement. This can be overcome by improving soil drainage with pipes or surface contouring that redirects water away from trees.

You can also encourage a tree’s root growth by mulching around the tree under the “dripline” – the outer edge of the canopy from which water drips to the ground. Applying a mixed-particle-size organic mulch to a depth of 75-100 millimetres will help keep the soil friable, aerated and moist. But bear in mind, mulch can be a fire risk in some conditions.

Root systems can also become waterlogged after heavy rain. So when both heavy rain and strong winds are predicted, be alert to the possibility of falling trees.

Read more: Why there's a lot more to love about jacarandas than just their purple flowers

2. Direct root damage

Human-caused damage to root systems is a common cause of tree failure. Such damage can include roots being:

• cut when utility services are installed
• restricted by a new road, footpath or driveway
• compacted over time, such as when they extend under driveways.

Trees can take a long time to respond to disturbances. When a tree falls in a storm, it may be the result of damage inflicted 10-15 years ago.

3. Wind direction

Trees anchor themselves against prevailing winds by growing roots in a particular pattern. Most of the supporting root structure of large trees grows on the windward side of the trunk.

If winds come from an uncommon direction, and with a greater-than-usual speed, trees may be vulnerable to falling. Even if the winds come from the usual direction, if the roots on the windward side are damaged, the tree may topple over.

The risk of this happening is likely to worsen under climate change, when winds are more likely to come from new directions.

4. Dead limbs

Dead or dying tree limbs with little foliage are most at risk of falling during storms. The risk can be reduced by removing dead wood in the canopy.

Trees can also fall during strong winds when they have so-called “co-dominant” stems. These V-shaped stems are about the same diameter and emerge from the same place on the trunk.

If you think you might have such trees on your property, it’s well worth having them inspected. Arborists are trained to recognise these trees and assess their danger.

Read more: The years condemn: Australia is forgetting the sacred trees planted to remember our war dead

Trees are worth the trouble

Even with the best tree management regime, there is no guarantee every tree will stay upright during a storm. Even a healthy, well managed tree can fall over in extremely high winds.

While falling trees are rare, there are steps we can take to minimise the damage they cause. For example, in densely populated areas, we should consider moving power and communications infrastructure underground.

By now, you may be thinking large trees are just too unsafe to grow in urban areas, and should be removed. But we need trees to help us cope with storms and other extreme weather.

Removing all trees around a building can cause wind speeds to double, which puts roofs, buildings and lives at greater risk. Removing trees from steep slopes can cause the land to become unstable and more prone to landslides. And of course, trees keep us cooler during summer heatwaves.

Victoria’s spate of fallen trees is a concern, but removing them is not the answer. Instead, we must learn how to better manage and live with them.

Read more: Here are 5 practical ways trees can help us survive climate change

Gregory Moore, Doctor of Botany, The University of Melbourne

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

Peatlands worldwide are drying out, threatening to release 860 million tonnes of carbon dioxide every year

Peatlands, such as fens, bogs, marshes and swamps, cover just 3% of the Earth’s total land surface, yet store over one-third of the planet’s soil carbon. That’s more than the carbon stored in all other vegetation combined, including the world’s forests.

But peatlands worldwide are running short of water, and the amount of greenhouse gases this could set loose would be devastating for our efforts to curb climate change.

Specifically, our new research in Nature Climate Change found drying peatlands could release an additional 860 million tonnes of carbon dioxide into the atmosphere every year, by around 2100. To put this into perspective, Australia emitted 539 million tonnes in 2019.

To stop this from happening, we need to urgently preserve and restore healthy, water-logged conditions in peatlands. These thirsty peatlands need water.

Peatlands are like natural archives

Peatlands are found across the world: the arctic tundra, coastal marshes, tropical swamp forests, mountainous fens and blanket bogs on subantarctic islands.

They’re characterised by having water-logged soil filled with very slowly decaying plant material (the “peat”) that accumulated over tens of thousands of years, preserved by the low-oxygen environment. This partially decomposed plant debris is locked up in the soils as organic carbon.

Read more: Peat bogs: restoring them could slow climate change – and revive a forgotten world

Peatlands can act like natural archives, letting scientists and archaeologists reconstruct past climate, vegetation, and even human lives. In fact, an estimated 20,500 archaeological sites are preserved under or within peat in the UK.

As unique habitats, peatlands are home for many native and endangered species of plants and animals that occur nowhere else, such as the white-bellied cinclodes (Cinclodes palliatus) in Peru and Australia’s giant dragonfly (Petalura gigantea), the world’s largest. They can also act as migration corridors for birds and other animals, and can purify water, regulate floods, retain sediments and so on.

But over the past several decades, humans have been draining global peatlands for a range of uses. This includes planting trees and crops, harvesting peat to burn for heat, and for other land developments.

For example, some peatlands rely on groundwater, such as portions of the Greater Everglades, the largest freshwater marsh in the United States. Over-pumping groundwater for drinking or irrigation has cut off the peatlands’ source of water.

Together with the regional drier climate due to global warming, our peatlands are drying out worldwide.

What happens when peatlands dry out?

When peat isn’t covered by water, it could be exposed to enough oxygen to fuel aerobic microbes living within. The oxygen allows the microbes to grow extremely fast, enjoy the feast of carbon-rich food, and release carbon dioxide into the atmosphere.

Some peatlands are also a natural source of methane, a potent greenhouse gas with the warming potential up to 100 times stronger than carbon dioxide.

But generating methane actually requires the opposite conditions to generating carbon dioxide. Methane is more frequently released in water-saturated conditions, while carbon dioxide emissions are mostly in unsaturated conditions.

Read more: Emissions of methane – a greenhouse gas far more potent than carbon dioxide – are rising dangerously

This means if our peatlands are getting drier, we would have an increase in emissions of carbon dioxide, but a reduction in methane emissions.

So what’s the net impact on our climate?

We were part of an international team of scientists across Australia, France, Germany, Netherlands, Switzerland, the US and China. Together, we collected and analysed a large dataset from carefully designed and controlled experiments across 130 peatlands all over the world.

In these experiments, we reduced water under different climate, soil and environmental conditions and, using machine learning algorithms, disentangled the different responses of greenhouse gases.

Our results were striking. Across the peatlands we studied, we found reduced water greatly enhanced the loss of peat as carbon dioxide, with only a mild reduction of methane emissions.

The net effect — carbon dioxide vs methane — would make our climate warmer. This will seriously hamper global efforts to keep temperature rise under 1.5℃.

This suggests if sustainable developments to restore these ecosystems aren’t implemented in future, drying peatlands would add the equivalent of 860 million tonnes of carbon dioxide to the atmosphere every year by 2100. This projection is for a “high emissions scenario”, which assumes global greenhouse gas emissions aren’t cut any further.

Protecting our peatlands

It’s not too late to stop this from happening. In fact, many countries are already establishing peatland restoration projects.

For example, the Central Kalimantan Peatlands Project in Indonesia aims to rehabilitate these ecosystems by, for instance, damming drainage canals, revegetating areas with native trees, and improving local socio-economic conditions and introducing more sustainable agricultural techniques.

Likewise, the Life Peat Restore project aims to restore 5,300 hectares of peatlands back to their natural function as carbon sinks across Poland, Germany and the Baltic states, over five years.

But protecting peatlands is a global issue. To effectively take care of our peatlands and our climate, we must work together urgently and efficiently.

Read more: People, palm oil, pulp and planet: four perspectives on Indonesia's fire-stricken peatlands

Yuanyuan Huang, Research Scientist , CSIRO and Yingping Wang, Chief research scientist, CSIRO

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