Monday, November 01, 2021

Study led by NUS researchers reveals climate change increases fluvial sediment in the high mountains of Asia


The findings have far reaching implications for the region’s hydropower, food and environmental security

Peer-Reviewed Publication

NATIONAL UNIVERSITY OF SINGAPORE

High Mountain Asia (HMA), which refers to the Tibetan Plateau and the surrounding high Asian mountains, is home to the world’s third-largest ice reservoir and the origin of many of Asia’s large rivers. In fact, these rivers are crucial lifelines for a third of the world’s population. The rivers in HMA are experiencing increased runoff and sediment fluxes from amplified climate change, glacier melt and permafrost thaw.

To examine the impact of these phenomena on HMA, Professor Lu Xixi and Dr Dongfeng Li from the Department of Geography at the National University of Singapore (NUS) Faculty of Arts and Social Sciences led an international team of researchers to conduct a new analysis of observations of headwater rivers in the area. The study revealed that fluvial sediment loads have been increasing substantially, even much faster than river water discharge. This is due to the recent warmer and wetter climate, and has important implications for water quality, hydropower development and maintenance, and for the riverine carbon cycle.

Dr Li, Research Fellow from the NUS Department of Geography and the study’s lead author, said “Climate change is accelerating glacier retreat and permafrost thaw, resulting in the previously frozen landscapes becoming more erodible. Our study shows that emerging process, such as glacier retreat and permafrost thaw, will enhance the transport of sediments from slopes to river systems, especially when regional extreme rainstorms are also increasing. This has significant knock-on effects on the region’s hydropower, food and environmental security, potentially affecting millions of people in HMA and downstream regions.”

The results of the study were published today in Science Magazine.

 

Analysing flow and sediment load data in HMA headwaters

The project was done in collaboration with some of the world’s renowned scientists in the field of sediment transport including Associate Professor Irina Overeem, Prof Jaia Syvitski and Prof Albert Kettner from the University of Colorado, Boulder (CU-Boulder); Prof Des Walling from the University of Exeter; Prof Bodo Bookhagen from the University of Potsdam; and Prof Yinjun Zhou from the Changjiang River Scientific Research Institute, Wuhan, China.

The team collated and analysed available flow and sediment load data from rivers in HMA over a period of six decades to investigate changes in runoff and sediment flux in response to a warmer and wetter climate. To exclude the potential impact of human activities, 28 quasi-pristine headwater basins were selected. The team then studied the sensitivity of sediment flux to changing temperature and precipitation in HMA using observational data and a climate elasticity model.

Based on the study, the team estimated that the present-day fluvial sediment flux from HMA is nearly two billion metric tons per year, and could more than double by 2050 under an extreme climate change scenario.

“The cascade of impacts of climate change, first by planetary warming, then by amplified changes in alpine temperature and precipitation patterns, followed by melt and release of sediment from glaciers and frozen landscapes, and subsequently by increased sediment transport by rivers, demonstrates how planet Earth is being altered through our continued use of fossil fuels,” stated Prof Syvitski who is also former Chair of the International Geosphere-Biosphere Programme.

The team further reasoned that the increasing sediment loads have profound impacts on the maintenance of downstream hydropower reservoirs. “The increasing sediment inflow to reservoirs will decrease the storage capacity of the reservoirs, and thus reduce their expected lifespans. As a result, all reservoir services like water supply, irrigation, hydropower generation, and flood control will be negatively impacted”, said Prof Lu, Principal Investigator of the study.

Prof Overeem added, “Since the 1950s, amplified warming in the HMA headwaters has increased sediment loads at an average rate of 32 per cent for every one degree of warming. Thaw of this landscape now has already triggered profound change in soil erosion and sediment delivery to the rivers. Glaciers are known to be efficient sediment producers, but this study suggests that the role of permafrost thaw in longer-term climate and sediment cycles may be more important than previously thought.”.

The team noted that increased sediment concentrations will likely negatively impact water quality and aquatic ecosystems. Fine suspended sediment particle is an important vector for the transport of phosphorus and most heavy metals, such as mercury, chromium, arsenic, and lead. Thus, climate change is likely to increase sediment-associated nutrient and contaminant fluxes. Furthermore, suspended sediment is a key vector for organic carbon transport; and the precise role of erosion and sediment delivery in mobilising organic carbon from permafrost landscapes and delivering it to the fluvial system remains uncertain. The team shared that more observations were needed to assess the positive feedback between climate warming, permafrost degradation, and carbon cycling.

The researchers also added that a substantial proportion of the increased sediment could be temporarily deposited in the river system, wide alluvial valleys and river floodplains, aggrading riverbeds, potentially triggering river avulsions and increasing the risks of flooding, particularly during the monsoon season. However, increases in sediments are not always bad. Riverine sediments can be used as soils for local agriculture practices in the high mountain regions, and are important materials for construction and coastal protection structures in small island countries such as Singapore. For example, one billion tons of sediment can be used for the construction of two great walls of China.

“These unique long-term riverine datasets of many of the headwater rivers of the high-mountains of Asia made it possible to determine how the landscape is rapidly transforming under an amplified climate change. This amplified climate change is also observed at the polar regions, where unfortunately long-term river datasets are sparse. However, it would be very interesting to see how the landscape responds at those polar regions, if there are similarities and what the downstream implications could be for the communities and the environment,” said Prof Albert Kettner, Research Professor from the Institute of Arctic and Alpine Research at CU-Boulder.

Dr Li commented, “This study sheds light on the importance and potential implications of the marked increases in recent and future sediment fluxes that have not been fully recognised by scientific communities nor have they been fully taken into account in the assessment of potential changes in the global carbon cycle. We hope this will encourage more observations on fluvial sediment in the world’s cold environments.”

The next step for the research team is to develop a dynamic sediment transport model suitable for cold environments. This would help to better understand the seasonality of future fluvial sediment in a rapidly warming world.

 

Climate change: We're acting, but are we making a difference?

climate
Credit: Pixabay/CC0 Public Domain

It's a big question: Is the world doing enough to adapt to the effects of climate change?

According to University of Delaware disaster researcher A.R. Siders, there are no easy answers, but scientists are looking at this problem from a variety of angles.

One approach, reported in Nature Climate Change on Thursday, Oct. 28, analyzed academic studies to create a first-of-its-kind data repository documenting how much adaptation is occurring globally and to explore whether these efforts have been effective. Siders, an assistant professor in the Joseph R. Biden, Jr. School of Public Policy and Administration and the Department of Geography and Spatial Sciences, co-authored the study with an international group of colleagues.

The study revealed growing evidence that people and organizations are responding to  change with a wide range of actions, but noted that far fewer studies explore whether these adaptation actions actually reduce risks associated with climate change.

As  prepare for the United Nations Climate Change Conference (COP26) that begins next week, UDaily connected with Siders, whose expertise lies in climate change adaptation, to learn about the study.

Q: How did this study come about?

Siders: The global climate change agreement adopted at the 2015 Paris climate conference (COP21)—termed the Paris Agreement—calls for what's known as a "global stocktake" of adaptation to determine if society is doing enough to adapt to climate change. This is an enormous task and currently no good datasets exist to identify adaptation actions across the world at scale. So, a group of 126 global scientists and researchers, including me, got together to see if we could answer this question through the lens of academic studies.

We screened approximately 48,000 scientific journal articles on climate change and adaptation and filtered that down to 1,682  that document adaptation actions around the world. We analyzed those papers to figure out how much adaptation is happening, what types of adaptations are occurring and whether there is any evidence that these adaptation actions are reducing risks associated with climate change. The result is a massive database of all these studies that can help us begin to quantify and document global adaptation actions that are occurring and their effects.

Q: What did you learn?

Siders: We found that all over the world, in almost every sector, people are taking action to adapt to climate change, and that's really encouraging. Less encouraging is that the actions people are taking tend to be fragmented, representing small adjustments to business-as-usual rather than the type of transformation that may be needed. For example, in response to warmer temperatures, farmers are planting crops earlier and people are using air conditioning when it's hot. This raises a concern about whether what we're doing is enough to deal with the [expected] effects of climate change.

Q: How can we measure whether our adaptation efforts will be enough?

Siders: We expect that climate change will make life harder in a lot of ways. It's going to make it too hot to grow crops; there will be more droughts, heat waves, floods. Using floods as an example, the question becomes does elevating your home one foot actually make you safer from the floods or did you need to elevate three feet? Does building a floodwall actually reduce losses in the next hurricane or does it just push those losses somewhere else? This is difficult to assess but that's what we want to know, including how long these actions are effective … will elevating three feet be enough to keep you safe for the next decade or the next century? Scientists are working on ways to assess whether adaptation is enough, but right now, there isn't a uniform approach or tool for measuring how well adaptation actions reduce risks related to climate change. Complicating matters, whether we're doing 'enough' depends on how bad  is going to get, which depends on whether we cut emissions, so it's a whole feedback cycle.

Q: How do we address this lack of data about adaptation actions and their effects?

Siders: If we start identifying what tools are out there, then we can start seeing which ones could apply to other situations. For example, can a tool that addresses flood risk in the Solomon Islands also be used to address drought in Arizona? This new data set is a first step in gathering evidence, including how researchers are currently measuring risk reduction and how they are measuring and defining successful adaptation. For instance, do we only count risk reduction, meaning whether or not it kept you safer, or do we also account for whether it hurt or helped the economy, the environment or culture? These are questions that need answers.

Q: Where do you hope to see this work lead?

Siders: The goal of this paper is to provide some of the evidence that can inform the Intergovernmental Panel on Climate Change's (IPCC) sixth assessment report. We know the data doesn't tell the whole story because it only looks at academic studies, not government reports, nonprofit reports, etc. But it is one data set that didn't exist before that we hope can be used as a baseline, now and in the future. Already, the project has led to a lot of spin-off papers. I was involved in papers on equity and adaptation, heat adaptation, and I'm working on other papers related to policy tools, ocean adaptation, climate migration and climate heritage using this database.

We hope to inspire new research into gap areas where we just don't have enough information or studies to be able to say conclusively what's happening, say, in under-researched regions of the world or under different warming levels or timespans. Hopefully, this is just the beginning of data that can help governments and practitioners make evidence-based decisions that take global efforts into account.Climate change: England must 'adapt or die,' agency warns

More information: Lea Berrang-Ford et al, A systematic global stocktake of evidence on human adaptation to climate change, Nature Climate Change (2021). DOI: 10.1038/s41558-021-01170-y

Journal information: Nature Climate Change 

Provided by University of Delaware 

Exploring the rise of emissions in the shadow of global climate negotiations

emissions
Credit: Unsplash/CC0 Public Domain

This November, world leaders will meet once again to negotiate and discuss measures to address the global climate crisis. The question is, will COP26 in Glasgow make any difference? A recently published research article identifies key reasons behind the world's 30-year record of failure to bring down global emissions.

"One common thread in the reviewed literature is power in its various forms," says Isak Stoddard, a doctoral student at the Department of Earth Sciences and one of the lead authors of the article.

On 31 October, representatives of almost 200 countries will gather in Glasgow, Scotland, for the 2021 United Nations Climate Change Conference, also known as COP26. On the agenda once again is the issue of reducing  to limit global warming to well below 2 degrees Celsius as enshrined in the 2015 Paris Agreement. However, any hopes that the world might be moving towards phasing out  and aligning itself with such commitments have been clouded by recent reports of increased emissions.

The reasons behind the continued rise in  were recently explored in a study published in the journal Annual Review of Environment and Resources. Lead authors of the study are Isak Stoddard and Kevin Anderson, visiting professor at Uppsala University's Department of Earth Sciences and former Zennström Professor of Climate Change Leadership. Together with 21 other researchers, including two from Uppsala University, they have sought explanations in nine key areas of knowledge: international  governance, the vested interests of the fossil-fuel industry, geopolitics and militarism, economics and financialisation, mitigation modeling, energy supply systems, inequity, high-carbon lifestyles, and social imaginaries (collective images of how we might live).

Power is a common thread

The conclusion reached by the researchers is that a common, and thus far marginalized, perspective lies in the central role that power has played.

"Behind the delay in  reductions are everything from geopolitical, military and industrial interests and modes of thought to the assumptions on which research and knowledge production are based in fields such as economics, energy and climate. This has contributed to a 60 percent rise in global carbon dioxide emissions since 1990, despite decades of international negotiations, research and all sorts of attempts to take action," says Isak Stoddard

Stoddard also sees the research community as part of the problem, given that its knowledge production has served to strengthen societal structures and interests that have contributed to creating and maintaining the emissions crisis.

"Researchers are part of a community that produces knowledge about climate issues. It's a matter of which questions we ask, and don't ask, as researchers and how we adapt our message to what we deem possible or acceptable within our current political and economic system."

Positioning within unsustainable societal systems

Other factors that have played an important role in the trajectory of emissions have to do with issues of inequity, as well as lock-ins to fossil-fuel dependent and energy-intensive lifestyles and visions of the future.

"We can also see that a large number of actors who previously viewed the challenge of climate change as a threat to their operations have begun to position themselves more proactively. While this may appear gratifying, one of the main conclusions of the article is that we need to understand  as part of a much greater problem and as an acute symptom of a highly unsustainable societal development, largely driven by powerful vested interests that constantly need to be questioned," says Isak Stoddard.

Is there any hope for improved conditions for progress during COP26?

"There is definitely value in holding such discussions between countries at this level. That said, our study has shown that, even if there has been criticism of the design of the United Nations Framework Convention [on Climate Change], deadlocks have generally been the result of strategic geopolitical considerations that have been decided long before the negotiations take place. The changes we need to see must also happen from the ground up and, of course, in different ways in all of the various societies and cultures around the world."A successful COP26 is essential for Earth's future. Here's what needs to go right

More information: Isak Stoddard et al, Three Decades of Climate Mitigation: Why Haven't We Bent the Global Emissions Curve? Annual Review of Environment and Resources (2021). DOI: 10.1146/annurev-environ-012220-011104

Provided by Uppsala University 

How mining companies can better protect workers from injury and death

mining
Credit: CC0 Public Domain

New research from Edith Cowan University (ECU) has identified some key causes of workplace fatalities in the Western Australian mining and resources sector, which could assist companies to reduce the number of workers injured on the job.

The study was comprised of two phases. First, researchers surveyed more than 2000 mining company employees from 2017-2019 to gain their perceptions of workplace  and injury risk.

They used a questionnaire based on Professor Michael Quinlan's 2014 book 'Ten Pathways to Death and Disaster,' which outlines common risk factors for catastrophic work incidents.

Researchers then compared the questionnaire results to actual workplace fatalities to see if the way people perceived the injury risk at their workplace aligned with the results of the incidents.

The study identified four of Quinlan's pathways were regularly associated with WA mining deaths and are therefore a priority for action:

  • Pathway 1: Design, engineering, technical and maintenance flaws
  • Pathway 4: Failures in safety management systems
  • Pathway 5: Failures in Auditing
  • Pathway 9: Poor management—worker communication and trust

ECU Ph.D. candidate Tanya Jenke said the study could form as a blueprint for mining companies to ensure their worksites were as safe as possible.

"We aimed to assist the West Australian mining industry in learning from past fatalities and to provide direction for controlling fatality risks in the future," she said.

"The simplicity of the Ten Pathways makes them a valuable risk communication tool, and could readily be used to commence discussions, for example at safety meetings, or implemented in a reporting tool to allow companies to learn about safety matters more effectively.

"It could also be used as a self-audit tool or an internal company assessment to benchmark against the findings published in this study."

Leadership is crucial

In most cases,  with leadership roles, such as superintendents and managers, scored their organization's performance higher than employees in frontline positions.

Ms Jenke said this suggested communication and cultural issues, which could have serious ramifications.

"It highlights potentially dangerous gaps between employee expectations of management—such as prioritizing worker safety—and reality," she said.

"Additionally, those in leadership roles perceived a better worker relationship compared to employees in the front line. Mining organizations need to ensure systems and processes are in place to foster a collaborative and transparent work environment."

The office vs. the site

The study also noted significant differences in responses from those based in Perth and workers in other regions of WA, with regional respondents attributing lower scores than their city-based counterparts.

"This possibly indicates a disconnect between operating site and head office," Ms Jenke said.

"It may illustrate a difference between work as planned by the corporate office, versus work as done by the operations."

A rethink on reporting

Though the study recommends how mining companies should prioritize safety, Ms Jenke said organizations should address all 10 pathways, as they were developed from fatalities.

She said while some pathways did not appear in any WA mining fatality reports, it was likely due to how incidents were reported.

"We suggest that this may be a result of data on these pathways is not captured as part of the Fatality Register assessment and that they are contributing to fatalities," Ms Jenke said.

"Given that four pathways were most prominent in the DMIRS Fatalities Register and the remaining six were not, it is argued the type of information required for reporting does not require an organization to publicly address all ten pathways.

"It is recommended that reporting include a mechanism for addressing all ten pathways, so that other organizations can effectively learn from past fatal incidents."

The reearch was published in Safety Science.

Descriptions of the Ten Pathways

Pathway 1: Design, engineering, technical and maintenance flaws

The flaws in engineering, design and maintenance were mostly the result of poor decision making by management and were often known or should have been identified well before the fatal incident.

Pathway 2: Prior warnings or causes for alarm ignored

In many of the fatal incidents, Quinlan observed that clear warnings and causes for alarm were ignored. For example, prior to the Beaconsfield collapse the stress and seismicity of two previous rock falls were not properly managed or investigated to identify the root cause. In many cases, employees or supervisors had expressed their safety concerns prior to the fatal incident.

Pathway 3: Failures in risk assessment

Quinlan stated a causal factor of many of the fatal incidents was a failure to undertake risk assessments or undertake them accurately. Effective risk assessments are based on informed knowledge of the hazard, evaluation of the effectiveness of risk treatments and control measures, and monitoring and review of the situation to detect change in risk.

Pathway 4: Failures in management systems and hazard management plans

Quinlan reported that Work Health and Safety management systems which focus on behavioral change, Lost Time Injuries and poorly selected Key Performance Indicators can lead to complacency when it comes to major hazards. Furthermore, the catastrophic risk increases when well-documented procedures are not implemented and when there are major changes to work design, for example the increased use of contractors.

Pathway 5: Failures in auditing

Auditing ensures that Work Health and Safety Management Systems are designed and implemented effectively and identifies areas for improvement. Auditing needs to be rigorous across all parts of the Work Health and Safety Management System. Quinlan considered overly routinized audits that do not act on information may overlook catastrophic hazards.

Pathway 6: Economic pressures compromising safety

This  highlights the failure to control the influence of personal financial incentives and pressure on individuals to contribute to the production expectations. Quinlan stated that financial pressures such as the use of incentive- or bonus-based regimes are commonly found to undermine safety.

Pathway 7: Failures in regulatory oversight and inspection

The failure of the Regulator to provide feedback to an organization on their compliance with legislation and safety performance was found by Quinlan to be a common catastrophic incident pathway.

Pathway 8: Worker and others expressing concern prior to the incident

In most investigations it seemed to Quinlan to be remarkable how seldom workers were asked their views on safety at the mine, including evidence of concerns both prior to and pertaining to the incident. Quinlan found failure to heed well-founded concerns was a common pathway of mine fatalities.

Pathway 9: Poor management—worker communication and trust

This pathway concerns the flow of critical information to and from the workers as well as the willingness to act on that information. Quinlan found ineffective communication and trust may result in a variety of poor outcomes including mixed messages, inconsistent messages and lack of engagement with the work force which undermines their participation.

Pathway 10: Emergency and rescue resources and procedures

Effective emergency management procedures play a critical role in mitigating the escalation of an incident. Failure to develop and implement effective emergency management systems endanger lives including safeguarding rescue personnel.

Gold mine workers face risk of death in the community more than double that of non-miners

More information: Tanya Jenke et al, Fatality risk management: Applying Quinlan's Ten Pathways in Western Australia's mining industry, Safety Science (2021). DOI: 10.1016/j.ssci.2021.105494
Provided by Edith Cowan University 
How mining companies can better protect workers from injury and death

New Editch Cowan University research has identified some key causes of workplace fatalities in the mining and resources sector, which could assist companies to reduce the number of workers injured on the job.

Peer-Reviewed Publication

EDITH COWAN UNIVERSITY

Mining company injuries. 

IMAGE: RESEARCHERS HAVE IDENTIFIED AREAS MINING COMPANIES CAN FOCUS ON TO REDUCE ON-SITE ACCIDENTS. view more 

CREDIT: UNSPLASH

New research from Edith Cowan University (ECU) has identified some key causes of workplace fatalities in the Western Australian mining and resources sector, which could assist companies to reduce the number of workers injured on the job. 

The study was comprised of two phases. First, researchers surveyed more than 2000 mining company employees from 2017-2019 to gain their perceptions of workplace safety and injury risk.  

They used a questionnaire based on Professor Michael Quinlan’s 2014 book ‘Ten Pathways to Death and Disaster’, which outlines common risk factors for catastrophic work incidents.   

Researchers then compared the questionnaire results to actual workplace fatalities to see if the way people perceived the injury risk at their workplace aligned with the results of the incidents. 

The study identified four of Quinlan’s pathways were regularly associated with WA mining deaths and are therefore a priority for action: 

  • Pathway 1: Design, engineering, technical and maintenance flaws 

  • Pathway 4: Failures in safety management systems  

  • Pathway 5: Failures in Auditing  

  • Pathway 9: Poor management – worker communication and trust   

 

ECU PhD candidate Tanya Jenke said the study could form as a blueprint for mining companies to ensure their worksites were as safe as possible. 

“We aimed to assist the West Australian mining industry in learning from past fatalities and to provide direction for controlling fatality risks in the future,” she said. 

“The simplicity of the Ten Pathways makes them a valuable risk communication tool, and could readily be used to commence discussions, for example at safety meetings, or implemented in a reporting tool to allow companies to learn about safety matters more effectively. 

“It could also be used as a self-audit tool or an internal company assessment to benchmark against the findings published in this study.” 

 

Leadership is crucial 

In most cases, survey respondents with leadership roles, such as superintendents and managers, scored their organization’s performance higher than employees in frontline positions.  

Ms Jenke said this suggested communication and cultural issues, which could have serious ramifications.  

“It highlights potentially dangerous gaps between employee expectations of management – such as prioritising worker safety - and reality,” she said. 

“Additionally, those in leadership roles perceived a better worker relationship compared to employees in the front line.  Mining organisations need to ensure systems and processes are in place to foster a collaborative and transparent work environment.” 

 

The office v the site 

The study also noted significant differences in responses from those based in Perth and workers in other regions of WA, with regional respondents attributing lower scores than their city-based counterparts. 

“This possibly indicates a disconnect between operating site and head office,” Ms Jenke said. 

“It may illustrate a difference between work as planned by the corporate office, versus work as done by the operations.” 

 

A rethink on reporting  

Though the study recommends how mining companies should prioritise safety, Ms Jenke said organizations should address all 10 pathways, as they were developed from fatalities. 

She said while some pathways did not appear in any WA mining fatality reports, it was likely due to how incidents were reported. 

“We suggest that this may be a result of data on these pathways is not captured as part of the Fatality Register assessment and that they are contributing to fatalities,” Ms Jenke said. 

“Given that four pathways were most prominent in the DMIRS Fatalities Register and the remaining six were not, it is argued the type of information required for reporting does not require an organisation to publicly address all ten pathways. 

“It is recommended that reporting include a mechanism for addressing all ten pathways, so that other organisations can effectively learn from past fatal incidents.” 

‘Fatality risk management: Applying Quinlan’s Ten Pathways in Western Australia’s mining industry’ was published in Safety Science. 

More research is being undertaken to look at employees’ perceptions on their organization’s ; those looking to take part in the project can complete an online survey, which will provide access to the latest edition of Safety Science and Ms Jenke’s full paper. 

To take part, click on the above link.

 

Quinlan Ten Pathways  

Pathway 

Description of Pathway 

Pathway 1:  Design, engineering, technical and maintenance flaws  

The flaws in engineering, design and maintenance were mostly the result of poor decision making by management and were often known or should have been identified well before the fatal incident. 

Pathway 2: Prior warnings or causes for alarm ignored  

In many of the fatal incidents, Quinlan observed that clear warnings and causes for alarm were ignored. For example, prior to the Beaconsfield collapse the stress and seismicity of two previous rock falls were not properly managed or investigated to identify the root cause. In many cases, employees or supervisors had expressed their safety concerns prior to the fatal incident. 

Pathway 3: Failures in risk assessment  

Quinlan stated a causal factor of many of the fatal incidents was a failure to undertake risk assessments or undertake them accurately. Effective risk assessments are based on informed knowledge of the hazard, evaluation of the effectiveness of risk treatments and control measures, and monitoring and review of the situation to detect change in risk. 

Pathway 4:  Failures in management systems and hazard management plans 

Quinlan reported that Work Health and Safety management systems which focus on behavioural change, Lost Time Injuries and poorly selected Key Performance Indicators can lead to complacency when it comes to major hazards. Furthermore, the catastrophic risk increases when well-documented procedures are not implemented and when there are major changes to work design, for example the increased use of contractors. 

Pathway 5:  Failures in auditing 

Auditing ensures that Work Health and Safety Management Systems are designed and implemented effectively and identifies areas for improvement.  Auditing needs to be rigorous across all parts of the Work Health and Safety Management System.  Quinlan considered overly routinized audits that do not act on information may overlook catastrophic hazards. 

Pathway 6: Economic pressures compromising safety 

This pathway highlights the failure to control the influence of personal financial incentives and pressure on individuals to contribute to the production expectations.  Quinlan stated that financial pressures such as the use of incentive- or bonus-based regimes are commonly found to undermine safety. 

Pathway 7:  Failures in regulatory oversight and inspection 

The failure of the Regulator to provide feedback to an organisation on their compliance with legislation and safety performance was found by Quinlan to be a common catastrophic incident pathway. 

Pathway 8:  Worker and others expressing concern prior to the incident 

In most investigations it seemed to Quinlan to be remarkable how seldom workers were asked their views on safety at the mine, including evidence of concerns both prior to and pertaining to the incident. Quinlan found failure to heed well-founded concerns was a common pathway of mine fatalities. 

Pathway 9:  Poor management – worker communication and trust 

This pathway concerns the flow of critical information to and from the workers as well as the willingness to act on that information.  Quinlan found ineffective communication and trust may result in a variety of poor outcomes including mixed messages, inconsistent messages and lack of engagement with the work force which undermines their participation. 

Pathway 10: Emergency and rescue resources and procedures 

Effective emergency management procedures play a critical role in mitigating the escalation of an incident.  Failure to develop and implement effective emergency management systems endanger lives including safeguarding rescue personnel. 

 

- ends - 

A proactive approach to removing space junk

Waste of space
University of Utah mechanical engineering professor Jake J. Abbott has discovered a
 method of manipulating orbiting space debris with the use of spinning magnets, allowing 
agencies more dexterous movement in clearing out space junk or repairing satellites. 
Credit: Dan Hixson/University of Utah College of Engineering

Space has become a trash heap.

According to NASA, there are more than 27,000 pieces of   bigger than the size of a softball currently orbiting Earth, and they are traveling at speeds of up to 17,500 mph, fast enough for a small chunk to damage a satellite or spacecraft like an intergalactic cannonball.

Consequently, cleaning up this space junk will be an important task if agencies are to shoot more rockets and satellites into orbit. University of Utah mechanical engineering professor Jake J. Abbott is leading a team of researchers that has discovered a method to manipulate orbiting debris with spinning magnets. With this technology, robots could one day gently maneuver the scrap to a decaying orbit or further out into space without actually touching it, or they could repair malfunctioning objects to extend their life.

Their research is detailed in the paper, "Dexterous magnetic manipulation of conductive non-magnetic objects," published this month in the science journal, Nature. The co-authors include U graduate students Lan Pham, Griffin Tabor and Ashkan Pourkand, former graduate student Jacob L. B. Aman, and U School of Computing associate professor Tucker Hermans.

The concept involves moving metallic, non-magnetized objects in space with spinning magnets. When the  is subjected to a changing magnetic field, electrons circulate within the metal in circular loops, "like when you swirl your cup of coffee and it goes around and around," says Abbott.

The process turns the piece of debris into essentially an electromagnet that creates torque and force, which can allow you to control where the debris goes without physically grabbing it.

While the idea of using these kinds of magnetic currents to manipulate objects in space is not new, what Abbott and his team have discovered is that using multiple  sources in a coordinated fashion allows them to move the objects in six degrees of movement, including rotating them. Before, it was only known how to move them in one degree of movement, like just pushing them.

"What we wanted to do was to manipulate the thing, not just shove it but actually manipulate it like you do on Earth," he says. "That form of dexterous manipulation has never been done before."

With this , scientists for example could stop a damaged satellite from wildly spinning in order to repair it, something that would not have been possible before.

"You have to take this crazy  floating in space, and you have to get it into a position where it can be manipulated by a ," Abbott says. "But if it's spinning out of control, you could break the robot arm doing that, which would just create more debris."

This method also allows scientists to manipulate objects that are especially fragile. While a robot arm could damage an object because its claw applies force to one part of it, these magnets would apply a gentler force to the entire object so no one section is harmed.

To test their research, the team used a series of magnets to move a copper ball on a plastic raft in a tank of water (the best way to simulate slow-moving objects in microgravity). The magnets moved the sphere not only in a square, but they also rotated the ball.

Abbott says this newly discovered process could be used with a spinning magnet on a robotic arm, a stationary magnet that creates spinning magnetic fields, or a spinning super-conductive electromagnet like those used in MRI scanners.

Abbott believes this principle of manipulating non-magnetic metallic objects with magnets could also have applications beyond the clearing of space debris.

"I'm starting to open my mind to what potential applications there are," he says. "We have a new way to apply a force to an object for precise alignment without touching it."

But for now, this idea could immediately be applied to help fix the problem of  orbiting the Earth.

"NASA is tracking thousands of space debris the same way that air traffic controllers track aircraft. You have to know where they are because you could accidentally crash into them," Abbott says. "The U.S. government and the governments of the world know of this problem because there is more and more of this stuff accumulating with each passing day."Crashing Chinese rocket highlights growing dangers of space debris

More information: Lan N. Pham et al, Dexterous magnetic manipulation of conductive non-magnetic objects, Nature (2021). DOI: 10.1038/s41586-021-03966-6

Journal information: Nature 

Provided by University of Utah