Saturday, July 03, 2021

 Same dance, different species: How natural selection drives common behavior of lizards

A surprising study on the behavior of unrelated lizards demonstrates how evolution can lead to different species learning the same skills

UNIVERSITY OF NEW SOUTH WALES

Research News

A surprising study by UNSW on the behaviour of unrelated lizards in very different parts of the world has demonstrated how evolution can lead to different species learning the same skills.

The study in Ecology Letters documents how the Anolis lizard species in the Caribbean, and the Draco lizard species in Southeast Asia, have solved the challenge of communicating with one another to defend territories and attract mates.

It found males from both species perform elaborate head bob and push up displays, and rapidly extend and retract their often large and conspicuously coloured dewlap, or throat fan, specifically in habitats with lots of wind-blown vegetation or low light.

The lizards occupy the same range of rainforest and grassland habitats, and therefore face the same problems when it comes to communicating to a potential mate or enemy in visually 'noisy' environments.

Remarkably, they have evolved the same strategy to cope with the same selection problems, lead author Dr Terry Ord from the Evolution & Ecology Research Centre at the UNSW School of Biological, Earth and Environmental Sciences says.

According to his research, this scenario of two unrelated lizards displaying similar behaviour shows that natural selection directs evolution towards the same common set of adaptive outcomes over and over again.

"The surprise is that lizards in both groups have evolved remarkably similar displays for communication, but they also tailor the production of those displays according to the prevailing conditions experienced at the time of display," Dr Ord says.

"That is, increasing the speed or the length of time they spend displaying the movements as the viewing conditions deteriorate.

"Really there should be essentially innumerable ways these lizards could have adapted their displays to remain effective, and there is strong evolutionary predictions that would lead us to expect this as well."

Dr Ord says what this study shows is that natural selection driving similarities between different species.

Formally, this is known as convergent evolution -- the independent origin of similar adaptations, he says.

"It seemed that these types of convergent, common adaptations are outcomes that would only really occur among species that are closely-related in some capacity," he says.

"The reason for this is a bit complicated and it rests on the fact that adaptations build on characteristics that a species already possesses."

"So, the longer species have evolved independently of each other, the less likely they would evolve the same adaptive solutions if they were exposed to the same change in the environment."

But what this study highlights, he says, is what many evolutionary ecologists have argued - that natural selection is an extremely powerful process that can override the "baggage" of past history to produce the same adaptations.

"So if arm-waving is the most effective solution to some change in the environment, then natural selection would ultimately lead to its evolution rather than a more subtle (less effective) modification to an existing vocal call," he says.

"Evolutionary biologists are excited about convergent evolution because it gives us multiple examples of the same adaptation evolving time and time again in very different animals.?

"So it tells us what the challenges are faced by these animals and how they have solved it in terms of evolutionary adaptation."

The study documents this independent evolution of common communication strategies amongst groups that have evolved separately from each other for hundreds of millions of years.

Dr Ord says the striking similarities in communication strategies for maintaining an effective communication system in noisy conditions has evolved in various forms in many insects, fish, frogs, birds and mammals.

"For example, increasing the volume of calls when there's lots of acoustic background noise, or extending the length of those calls or even vibrational signals by spiders and such," Dr Ord says .

"The fact that many other groups of animals have also evolved thesesame adaptive strategies is even more extraordinary."

Read the study in Ecology Letters.

 THE LOVE DRUG

UMass Amherst research pinpoints role of dopamine in songbird's brain plasticity

Neurotransmitter shown to be a key driver in sensory processing

UNIVERSITY OF MASSACHUSETTS AMHERST

Research News

IMAGE

IMAGE: LUKE REMAGE-HEALEY IS A PROFESSOR OF PSYCHOLOGICAL AND BRAIN SCIENCES AT UMASS AMHERST. view more 

CREDIT: UMASS AMHERST

Neuroscientists at the University of Massachusetts Amherst have demonstrated in new research that dopamine plays a key role in how songbirds learn complex new sounds.

Published in the Journal of Neuroscience, the finding that dopamine drives plasticity in the auditory pallium of zebra finches lays new groundwork for advancing the understanding of the functions of this neurotransmitter in an area of the brain that encodes complex stimuli.

"People associate dopamine with reward and pleasure," says lead author Matheus Macedo-Lima, who performed the research in the lab of senior author Luke Remage-Healey as a Ph.D. student in UMass Amherst's Neuroscience and Behavior graduate program. "It's a very well-known concept that dopamine is involved in learning. But the knowledge about dopamine in areas related to sensory processing in the brain is limited. We wanted to understand whether dopamine was playing a role in how this brain region learns new sounds or changes with sounds."

Studying vocal learning in songbirds provides insight into how spoken language is learned, adds behavioral neuroscientist Remage-Healey, professor of psychological and brain sciences. "It's not just the songbird that comes up with this strategy of binding sounds and meaning using dopamine. There's something parallel here that we ¬- as humans - are interested in."

The research team conducted a range of experiments in vitro and in vivo, poking neurons under the microscope and in the brains of live birds that were watching videos and hearing sounds. Ultimately, the scientists obtained anatomical, behavioral and physiological evidence to support their hypothesis about the role of dopamine.

Using antibodies, the researchers showed that dopamine receptors are present in many types of neurons in the songbird auditory brain ¬- they can be inhibitory or excitatory and may also contain an enzyme that produces estrogens. "Dr. Remage-Healey's research has shown that in the auditory brain of songbirds of both sexes, neurons produce estrogen in social situations, like when listening to birdsong or seeing another bird. We think that dopamine and estrogens might be working together in the sound learning process, but this work focused on dopamine because there was still so much we didn't know about how dopamine affected the songbird brain," explains Macedo-Lima, now a postdoctoral associate at the University of Maryland.

Macedo-Lima developed a test, similar to the well-known Pavlov's dog experiment, in which the birds sat alone in a chamber and were presented with a random sound followed immediately by a silent video of other birds. "We wanted to focus on the association between a meaningless sound - a tone - and the behaviorally relevant thing, which is another bird on video," he says.

The researchers looked at the birds' auditory brain regions after this sound-video pairing, using a gene marker known to be expressed when a neuron goes through change or plasticity. "We found this very interesting increase in this gene expression in the left hemisphere, the ventral part of the auditory region, in dopamine receptor-expressing neurons, reflecting the learning process, and paralleling human brain lateralization for speech learning," Macedo-Lima says.

To show the effect of dopamine on the basic signaling of neurons, the researchers used a whole cell patch clamp technique, controlling and measuring the currents the neurons received. They found in a dish that dopamine activation decreases inhibition and increases excitation.

"This one modulator is tuning the system in a way that ramps down the stop signals and ramps up the go signals," Remage-Healey explains. "That's a simple yet powerful control mechanism for how animals are potentially encoding sound. It's a neurochemical lever that can change how stimuli are registered and passed on in this part of the brain."

The team then painlessly probed the brain cells of live birds. "What happened when we delivered dopamine was exactly as we were predicting from the whole cell data," Macedo-Lima says. "We saw that inhibitory neurons fired less when we delivered the dopamine agonist, while the excitatory neurons fired more."

The same effect occurred when the birds were played birdsong from other songbirds - the excitatory neurons responded more and the inhibitory neurons responded less when dopamine activation occurred. "We were happy to replicate what we saw in a dish in a live animal listening to actual relevant sounds," Macedo-Lima says.

Dopamine activation also made these neurons unable to adapt to new songs presented to the animal, which strongly corroborates the hypothesis of dopamine's role in sensory learning. "We currently don't know how dopamine affects sensory learning in most animals," Macedo-Lima says, "but this research gives many clues about how this mechanism could work across vertebrates that need to learn complex sounds, such as humans."

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Color and flavor -- pigments play a role in creating tasty tomatoes

Researchers from the University of Tsukuba and the University of Florida show that the pigments that color tomatoes also affect their flavor

UNIVERSITY OF TSUKUBA

Research News

Ibaraki, Japan - The flavor of a tomato is an interaction between its taste and aroma. Now, researchers from Japan and the United States have revealed that the pigments that determine the colors of tomatoes also affect their flavor.

In a study published this month, researchers from University of Tsukuba developed a new method to rapidly measure the pigment profiles of tomatoes and used the technique to explore how pigments affect the taste and aroma of different tomato varieties.

The color of tomatoes is produced by combinations of different types of pigments, including carotenoids and chlorophylls. These pigments can also affect the accumulation of flavor-related compounds such as sugars, which affect the taste of tomatoes, and volatile organic compounds (VOCs), which determine the aroma. As tomato fruits ripen from green to red, the amounts of pigments and flavor-related compounds change but until now the relationship between color and flavor has been unclear.

"Pigments like carotenoids have no taste," says lead author Professor Miyako Kusano, "but they are precursors for compounds called apocarotenoid-VOCs (AC-VOCs) which produce the fruity/floral smell of tomatoes and increase the perception of sweetness--characteristics that appeal to consumers."

Traditional methods for identifying and measuring pigments can be slow, so the researchers developed a simple method to rapidly analyze large numbers of samples. Using the new technique, the team measured the amounts of carotenoids and chlorophylls in 157 different varieties of tomato and then analyzed the flavors of each variety to find the links between pigments and flavor.

The results showed that tomato varieties with an abundance of chlorophyll also had a high sugar content, contributing to a sweet taste. They also found that the carotenoid profiles of the fruit reflected the appearance of the fruit, as well as AC-VOC levels.

"The pigment profile of one of the orange-colored varieties called "Dixie Golden Giant" was particularly interesting," explains Professor Kusano. "It had very high levels of AC-VOCs, but the carotenoid content wasn't that high. We discovered that the pigment prolycopene was abundant in this variety, which explained the high AC-VOC levels."

The carotenoid content of fruit is influenced by growing conditions, like temperature and amount of light. By looking at the pigment profiles and AC-VOC content of fruits in different environments, it may be possible to find ways of improving AC-VOC production, which is good for both consumers and producers.

Given its speed, the new method developed by the team is a powerful tool for analyzing pigment concentrations in large numbers of samples and could also be used for other fruits and vegetables.

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The article, "High-throughput chlorophyll and carotenoid profiling reveals positive associations with sugar and apocarotenoid volatile content in fruits of tomato varieties in modern and wild accessions," was published in Metabolites at DOI: 10.3390/metabo11060398.

This work was funded by the "Sustainable Food Security Research Project" in the form of an operational grant from the National University Corporation and The Yanmar Environmental Sustainability Support Association, Japan. This work was also supported by the JSPS KAKENHI Grant Number 19K05711 and by a grant from the National Science Foundation (IOS 1855585). The authors declare no competing interests.

 

Solving a long-standing mystery about the desert's rock art canvas

DOE/SLAC NATIONAL ACCELERATOR LABORATORY

Research News

Wander around a desert most anywhere in the world, and eventually you'll notice dark-stained rocks, especially where the sun shines most brightly and water trickles down or dew gathers. In some spots, if you're lucky, you might stumble upon ancient art - petroglyphs - carved into the stain. For years, however, researchers have understood more about the petroglyphs than the mysterious dark stain, called rock varnish, in which they were drawn.

In particular, science has yet to come to a conclusion about where rock varnish, which is unusually rich in manganese, comes from.

Now, scientists at the California Institute of Technology, the Department of Energy's SLAC National Accelerator Laboratory and elsewhere think they have an answer. According to a recent paper in Proceedings of the National Academy of Sciences, rock varnish is left behind by microbial communities that use manganese to defend against the punishing desert sun.

The mystery of rock varnish is old, said Usha Lingappa, a graduate student at Caltech and the study's lead author. "Charles Darwin wrote about it, Alexander von Humboldt wrote about it," she said, and there is a long-standing debate about whether it has a biological or inorganic origin.

But, Lingappa said, she and her colleagues didn't actually set out to understand where rock varnish comes from. Instead, they were interested in how microbial ecosystems in the desert interact with rock varnish. To do so, they deployed as many techniques as they could come up with: DNA sequencing, mineralogical analyses, electron microscopy, and - aided by Stanford Synchroton Radiation Lightsource (SSRL) scientist Samuel Webb - advanced X-ray spectroscopy methods that could map different kinds of manganese and other elements within samples of rock varnish.

"By combining these different perspectives, maybe we could draw a picture of this ecosystem and understand it in new ways," Lingappa said. "That's where we started, and then we just stumbled into this hypothesis" for rock varnish formation.

Among the team's key observations was that, while manganese in desert dust is usually in particle form, it was deposited in more continuous layers in varnish, a fact revealed by X-ray spectroscopy methods at SSRL that can tell not only what chemical compounds make up a sample but also how they are distributed, on a microscopic scale, throughout the sample.

That same analysis showed that the kinds of manganese compounds in varnish were the result of ongoing chemical cycles, rather than being left out in the sun for millennia. That information, combined with the prevalence of bacteria called Chroococcidiopsis that use manganese to combat the oxidative effects of the harsh desert sun, led Lingappa and her team to conclude that rock varnish was left behind by those bacteria.

For his part, Webb said that he always enjoys a manganese project - "I've been a mangaphile for a while now" - and that this project arrived at the perfect time, given advances in X-ray spectroscopy at SSRL. Improvements in X-ray beam size allowed the researchers to get a finer-grained picture of rock varnish, he said, and other improvements ensured that they could get a good look at their samples without the risk of damaging them. "We're always tinkering and fine-tuning things, and I think it was the right time for a project that maybe 5 or 10 years ago wouldn't really have been feasible."

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The research was supported by the National Science Foundation, the National Institutes of Health and the National Aeronautics and Space Administration. SSRL is a DOE Office of Science user facility.

Citation: Usha F. Lingappa et al., Proceedings of the National Academy of Sciences, 22 June 2021 (10.1073/pnas.2025188118)

1541 NORTH AMERICAN HISTORY OF INVASION

After routing de Soto, Chickasaws repurposed Spanish objects for everyday use

FLORIDA MUSEUM OF NATURAL HISTORY

Research News

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IMAGE: FLORIDA MUSEUM ARCHAEOLOGIST CHARLES COBB HOLDS AN AXE HEAD KNOWN AS A CELT, ONE OF MORE THAN 80 METAL OBJECTS LIKELY FROM THE DE SOTO EXPEDITION. TO CREATE THIS DISTINCT... view more 

CREDIT: JEFF GAGE/FLORIDA MUSEUM OF NATURAL HISTORY

GAINESVILLE, Fla. --- Archaeologists have unearthed a rare trove of more than 80 metal objects in Mississippi thought to be from Hernando de Soto's 16th-century expedition through the Southeast. Many of the objects were repurposed by the resident Chickasaws as household tools and ornaments, an unusual practice at a time when European goods in North America were few and often reserved for leaders.

The researchers believe Spaniards left the objects behind while fleeing a Chickasaw attack that followed frayed relations between the two groups in 1541. The victors took advantage of the windfall of spoils - axe heads, blades, nails and other items made of iron, lead and copper alloy - modifying many of them to suit local uses and tastes. Chickasaw craftspeople turned pieces of Spanish horseshoes into scrapers, barrel bands into cutting tools and bits of copper into jingling pendants.

The sheer abundance of objects from the site, an area of northeastern Mississippi known as Stark Farms, is one of the factors that makes the find unique, said Charles Cobb, the study's lead author and Florida Museum of Natural History Lockwood Chair in Historical Archaeology.

"Typically, we might find a handful of European objects in connection with a high-status person or some other special context," Cobb said. "But this must have been more of an open season - a pulse of goods that became widely available for a short period of time."

If the researchers' diagnosis is correct, Stark Farms is only the second place to yield convincing archaeological evidence of direct contact with de Soto's expedition, after the historic site of the Apalachee capital of Anhaica in present-day Tallahassee, Cobb said.

'Unconquered and unconquerable'

By the time de Soto arrived in Mississippi in 1540, the conquistador had trekked through the Southeast for more than a year with about 600 people, hundreds of horses and pigs and heavy equipment in tow. A shrewd man with a reputation for bloodshed, de Soto was previously a key figure in the Spanish destruction of the Inca Empire in South America and came to Florida with an eye to further increase his wealth. Finding little gold, he pressed deeper into the interior, alternately befriending and warring with the Native Americans he encountered.

The Spaniards began on a friendly, if aloof, footing with the Chickasaws, whose leader, known as Chikasha Minko, gave them a modest village in which to spend the winter. But tensions rose as the months dragged on: De Soto executed two Chickasaws and cut off the hands of another accused of stealing pigs. The Chickasaws, who farmed maize in the region's rich prairie soil, also must have grown tired of providing food and shelter for such a large encampment of uninvited guests, Cobb said.

With spring drawing near, de Soto demanded that Chikasha Minko provide him with hundreds of Chickasaws to carry the Spaniards' equipment to their next destination. According to Spanish accounts of the expedition, the conversation did not go well.

Shortly afterwards, the Chickasaws launched a surprise attack under the cover of night, torching the Spanish camp and killing at least a dozen men, as well as many horses and pigs. The retreating Spaniards set up another camp about a mile away, where they were assaulted a second time. Better prepared, they fought back, but soon picked up and headed north, having lost much of their livestock, clothing and goods.

Meanwhile, the Chickasaws collected from the battlefield dozens of prized metal objects, usually reserved by the Europeans for strategic trades or as gifts to smooth relationships with local leaders.

"It's kind of like inflation," Cobb said. "You don't want too much stuff to get out or that gift will be devalued. That's what makes this site unusual."

After the Chickasaws sent the Spanish packing, the region remained largely free of European presence for nearly 150 years.

"This research shows how Chickasaws adapted to invasion by alien intruders and secured their reputation as unconquered and unconquerable," said study co-author Brad Lieb, director of Chickasaw archaeology for the Chickasaw Nation's Heritage Preservation Division. "The findings are remarkable in their success in addressing a baseline event in Chickasaw cultural history - the first encounter with Hernando de Soto and the Spanish invaders."



CAPTION

Chickasaws worked Spanish metal into tools and ornaments that reflected local uses and tastes, such as these brass pendants. If the researchers' diagnosis is correct, Stark Farms, Mississippi is only the second place to yield convincing archaeological evidence of direct contact with de Soto's expedition.

CREDIT

Jeff Gage/Florida Museum of Natural History


CAPTION

Europeans rarely traded or gifted military items. The presence of objects such as this palm-sized cannonball, lead shot and a ramrod tip at Stark Farms is one reason Cobb and his colleagues believe many of the items were spoils collected after the 1541 battle between the Spaniards and Chickasaws.

CREDIT

Jeff Gage/Florida Museum of Natural History

History confirmed by metal detectors

When Cobb, Lieb and their colleagues first arrived at Stark Farms in 2015, they weren't just looking for traces of de Soto. The Chickasaw Nation, removed from its traditional homeland to Oklahoma by the U.S. Department of War in 1837, had commissioned the team to identify and preserve ancestral sites and provide Chickasaw university students the opportunity to reconnect with their heritage through an archaeology fieldwork program.

The team focused on studying the environmental factors in the movements of Native Americans across the landscape, where radiocarbon dates showed people had lived since the 14th or 15th century. Curious about early residents' potential interactions with outsiders, the researchers brought metal detectors, a speedy way of finding objects of European origin. The first day they deployed the detectors, the machines began pinging. Soon, the team was uncovering dozens of items, including a small cannon ball, a mouth harp and what could be a Spanish bridle bit, emblazoned with a golden cross.

"We couldn't believe it," Cobb said. "There was a lot of serendipity for sure."

The style and type of objects, as well as their location, aligned with Spanish accounts of the de Soto expedition and the 1541 battle at Chikasha, the main Chickasaw town. But the researchers found no evidence of a burned village or the remains of horses and pigs. Cobb said the site was likely a village near Chikasha, whose inhabitants visited the site of the conflict and brought items back to their households. They may also have acquired some of the objects during the previous winter through under-the-table trading with Spanish soldiers.

The Chickasaws generally relied on bone, cane or stone as raw materials for their cutting and scraping tools, making the haul of metal a particular boon. While some of the objects retain their original form, the Chickasaws painstakingly reworked others into more familiar shapes. They bent metal back and forth until it broke and ground down and smoothed edges, modifying tools to mimic the design of their traditional Chickasaw counterparts.

"One of the most stunning things we've found is an exact iron replica of a Native American stone celt, or axe head," Cobb said. "I've never seen anything like this in the Southeast before."

Among the more sobering finds were chain links, pulled apart with sharpened edges. "The Spanish brought reams of chain with them to shackle Native Americans as captives and porters," Cobb said. "This is evidence of some of the first examples of European enslavement of people in what is now the U.S."

The refashioned items from Stark Farms represent a stage of Native American experimentation and improvisation with foreign items that largely faded by the late 1700s and 1800s, as they folded European materials and technology more completely into their own.

"In the 1500s, a thimble might be turned into a bangle. By the late 1700s, a thimble is a thimble," Cobb said. "You tend to see a more regular adoption of goods over time."

Spanish survivors did their own repurposing

De Soto failed to establish any permanent settlements in the Southeast, joining a line of ill-fated expeditions that demonstrated the precariousness of Europeans' early attempts to dominate the region. He succumbed to a fever on the banks of the Mississippi River in 1542, and his remaining band of men made rafts and floated south to Mexico where they found passage back to Spain.

There, they undertook a repurposing effort of their own: Having failed to find fame and fortune in the Americas, they sold their stories, many of which became bestselling books, Cobb said.

"There was a thriving industry in explorer and survival tales, which is probably one of the reasons why some of these individuals provided their accounts. From that perspective, it was very modern."

The objects will be repatriated to the Chickasaw Nation for permanent curation and exhibits.

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James Legg, Steven Smith and Chester DePratter of the South Carolina Institute of Archaeology and Anthropology and Edmond Boudreaux of the University of Mississippi also co-authored the study. The Chickasaw Nation reviewed the study for consistency with its histories.

The Chickasaw Nation and its Chickasaw Explorers Program co-led and funded the research. Portions of the fieldwork were also funded by the National Geographic Society.

 

A globally important microbial process hidden on marine particles

UNIVERSITY OF COPENHAGEN - FACULTY OF SCIENCE

Research News

How on Earth?

It has puzzled scientists for years whether and how bacteria, that live from dissolved organic matter in marine waters, can carry out N2 fixation. It was assumed that the high levels of oxygen combined with the low amount of dissolved organic matter in the marine water column would prevent the anaerobic and energy consuming N2 fixation.

Already in the 1980s it was suggested that aggregates, so-called "marine snow particles", could possibly be suitable sites for N2 fixation, but this was never proven.

Until now..

In a new study, researchers from the University of Copenhagen demonstrate, by use of mathematical models, that microbial fixation of nitrogen can take place on these aggregates of live and dead organisms in the marine plankton. The study has just been published in the prestigious Nature Communications.

Marine snow

Marine snow consists of debris from diverse organisms in the water column.

Picture shows marine snow from the Sargasso Sea. Photo: L. Riemann

-- "Our work took almost two years, but it was definitely worth the effort, since the results are quite a breakthrough. In close collaboration with our research collaborators at the Center for Ocean Life at DTU Aqua and in the USA, we managed to create a model mimicking conditions on marine snow particles. With this model, we show that a marine particle can become densely colonized by bacteria. This growth of bacteria causes extensive respiration leading to low oxygen concentrations on the particle, which ultimately allows for the anaerobic process of N2 fixation", explains first-author and postdoc at the Department of Biology, University of Copenhagen, Subhendu Chakraborty.

With their model the researchers could also show the depth distribution of N2 fixation in the marine water column. They found, that among other things, the N2 fixation is dependent on the size, density and sinking speed of the marine snow particles. Moreover, they demonstrated that their modelled rates were comparable to actual rates measured in marine waters.

Marine water sampler

Marine water samples are often taken with bottles attached to a so-called rosette, as seen here. Photo: L.asse Riemann

-- "This comparison gave us confidence in the model", says corresponding author Lasse Riemann, Professor at the Department of Biology. He continues: "We are very proud of our study, because it provides the first explanation of how marine-snow-associated N2 fixation can take place. Furthermore, the results indicate that this process is important for the global marine nitrogen cycling and thereby for plankton growth and productivity".

The researchers hope their study will inspire future work on microbial life on marine particles, due to its seemingly pivotal role in the cycling of many nutrients in the ocean.

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Global network transforming tropical forest research

UNIVERSITY OF LEEDS

Research News

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IMAGE: TREE MEASURING, SALONGA NATIONAL PARK, DEMOCRATIC REPUBLIC OF CONGO. view more 

CREDIT: SIMON LEWIS, UNIVERSITY OF LEEDS

A huge global network of researchers is working together to take the pulse of our global tropical forests.

ForestPlots.net, which is co-ordinated from the University of Leeds, brings together more than 2,500 scientists who have examined millions of trees to explore the effect of climate change on forests and biodiversity.

A new research paper published in Biological Conservation explains the origins of the network, and how the power of collaboration is transforming forest research in Africa, South America and Asia.

The paper includes 551 researchers and outlines 25 years of discovery in the carbon, biodiversity and dynamics of tropical forests.

Professor Oliver Phillips, of Leeds' School of Geography, said "Our new paper shows how we are linking students, botanists, foresters and policy-makers with the ForestPlots.net technology developed at Leeds.

"This drives a new model of collective research. This is helping to transform scientific understanding of how tropical forests work - and how they are helping to slow climate change.

"In this new synthesis we outline how this collaboration has been built, and trace the exciting potential of collaborative science that reaches across the world's tropical forests to embrace colleagues from all countries and backgrounds."

ForestPlots.net provides a unique place to measure, monitor, and understand the world's forests, and especially the tropical forests.

Established in 2009, it has grown fast to track 5,138 plots in 59 countries, with a network of 2,512 people.

The collaboration, funded by UK NERC and the Royal Society, aims to promote cooperation across countries and continents, and enable partners to access, analyse and manage the information from their long-term plots.

Professor Phillips said: "Our core approach links long-term, grassroots researchers to generate robust large-scale results.

"This global, diverse community is measuring thousands of forests tree-by-tree in long-term plots.

"By connecting tropical researchers together and valuing the key role of the data originator in scientific discovery, our Social Research Network model of research seeks to support the key workers who make 21st century big data science possible."

ForestPlots.net hosts data from many individual researchers and networks including AfriTRON, ECOFOR, PPBio, RAINFOR, TROBIT and T-FORCES.

Working together equitably, the network has shown that long-term monitoring of forests on-the-ground is irreplaceable, making scientific discoveries across the globe.

Through large scale analysis, ForestPlots.net researchers discover where and why forest carbon and biodiversity respond to climate change, and how they help control it with a billion tonne annual carbon sink.

The new research paper, Taking the pulse of Earth's tropical forests using networks of highly distributed plots, provides a vision for more integrated and equitable monitoring of Earth's most precious ecosystems.

The collaborative paper is particularly timely as it also highlights the impact Leeds and research partners have made to the understanding of carbon dynamics in tropical forests ahead of the global climate conference COP26, which takes place in Glasgow in November.


CAPTION

Amazon Forest canopy at dawn in Brazil

CREDIT

Peter van der Sleen

Further information

https://doi.org/10.1016/j.biocon.2020.108849

For image and video requests, or to arrange interviews, please contact Ian Rosser in the University of Leeds press office i.rosser@leeds.ac.uk

 

Energy production at Mutriku remains constant even if the wave force increases

The EOLO group has developed a statistical model that relates the power generation of the Mutriku wave farm to wave energy

UNIVERSITY OF THE BASQUE COUNTRY

Research News

IMAGE

IMAGE: GABRIEL IBARRA AND AN IMAGE OF THE DOCK THAT HOUSES THE MUTRIKU FACILITIES FOR TRANSFORMING WAVE ENERGY INTO ELECTRICAL POWER view more 

CREDIT: MITXI. UPV/EHU

The Mutriku wave power plant was built on the Mutriku breakwater, a site with great wave energy potential, and has been in operation since 2011. With 14 oscillating water columns to transform wave energy, it is the only wave farm in the world that supplies electricity to the grid on a continuous basis. In general, technologies that harness the power of the waves to produce electricity are in their infancy, and this is precisely what is being explored by the UPV/EHU's Research Group EOLO, which focusses on Meteorology, Climate and Environment, among many other aspects.

Gabriel Ibarra, researcher in the group and lecturer in the UPV/EHU's Department of Energy Engineering, explained that "one thing is the energy the waves produce, the hydraulic energy they have, and another thing is the amount of electrical power obtained from them". This is what they have been working on over the last few years. "After identifying some of the key aspects of the operation of the Mutriku facilities a few years ago, we have now developed a methodology that allows us to find out the impact of climate change on the output at Mutriku. We have used it to reconstruct the daily electrical power that would have been generated if the Mutriku wave farm had been operational during the entire 1979-2019 period, and this will help us to predict what might happen in the future," explained Ibarra.

The researcher affirmed that "we have found that there has been a growing trend in the strength of the waves in the Bay of Biscay as a result of climate change, from 1900 to the present day. The aim was therefore to analyse how the Mutriku facilities responded to this trend. In this respect, while taking into account the evolution of the waves over the last four decades, we developed a methodology that allows us to determine how this increase may affect generation at Mutriku".

Wave energy increases, but not electricity output

The research group found that "in the Mutriku area this upward trend in wave energy is not as high as in other areas of the Bay of Biscay, and that this trend would be dampened and electricity output would remain constant at the Mutriku facilities as a result of the way they function, their regulation system". It follows that the energy flow levels off above a certain threshold and is therefore more stable than the wave energy flow; consequently, they determined that moderate long-term changes in wave energy cannot directly affect wave power installations consisting of oscillating water columns. In Ibarra's opinion, much stronger waves would be needed to increase electricity production.

In the study, they identified ten main types of sea state with which a distinctive pattern of electrical power generation has been associated on a daily scale. This has allowed them to reconstruct the daily electrical power that would have been generated if the Mutriku wave farm had been operational during the entire 1979-2019 period and, consequently, to assess the impact that the observed changes in the wave climate and the associated energy flow would have had on electrical power output.

So, "the next step is to consider the future that climate change will bring and make a forecast; we believe that this upward trend will continue and we want to see, firstly, whether this trend will be on a large or small scale, and secondly, what impact this will have in the future, over the coming decades, on output at Mutriku. All the research carried out at the Mutriku facilities is hugely useful in advancing this type of technology, as it is the only facility in the world that supplies energy continuously to the grid", said Ibarra. The research has therefore shown that highly reliable feasibility and economic studies of wave power facilities can be carried out, as the future uncertainties of the resource itself will not have a significant impact on the electrical power performance of the installations throughout their life cycles.

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Solar hydrogen for Antarctica -- study shows advantages of thermally coupled approach

A team from the Helmholtz-Zentrum Berlin, Ulm University, and Heidelberg University has now investigated how hydrogen can be produced at the South Pole using sunlight, and which method is the most promising

HELMHOLTZ-ZENTRUM BERLIN FÃœR MATERIALIEN UND ENERGIE

Research News 

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IMAGE: IN POLAR REGIONS AND AT HIGH ALTITUDES THE CONVERSION OF SOLAR RADIATION INTO HYDROGEN COULD CERTAINLY BE WORTHWHILE. view more 

CREDIT: ENERGY&ENV.SCIENCE. DOI: 10.1039/D1EE00650A.

When environmental physicist Kira Rehfeld, from Heidelberg University, visited Antarctica for her research, she was struck by the intense light there. "It's always light in summer. This solar radiation could actually be used to supply the research infrastructure with energy", she observes. However, generators, engines, and heaters in these remote regions have mostly been powered until now by fossil fuels delivered by ship, such as petroleum or petrol, which cause global warming. Besides the high associated economic costs, pollution from even the smallest spills is also a major problem threatening the especially sensitive ecosystem.

Fossil fuels could be replaced by hydrogen, though, a versatile energy medium that in addition is able to be stored extremely well at low temperatures. "Our idea was therefore to use solar modules to produce climate-neutral hydrogen on site during the Antarctic summer by splitting water into hydrogen and oxygen through electrolysis", says May, then a postdoc at the Helmholtz-Zentrum Berlin Institute for Solar Fuels. Rehfeld and May applied for funding from the Volkswagen Foundation to investigate whether hydrogen can be generated using sunlight even at sub-zero temperatures, and which method is best suited for this. Low temperatures can considerably reduce the efficiency of electrolysis, though cold actually increases the efficiency of most solar modules.

May and his HZB colleague, Moritz Kölbach, have now empirically compared two different approaches: a conventional setup in which the photovoltaic module is thermally and physically separated from the electrolysis tank, and a newer, thermally coupled setup in which the photovoltaic module is in close contact with the wall of the electrolysis tank, promoting thermal diffusion. To simulate Antarctic conditions, Kölbach obtained a freezer, cut a hole in the door, installed a quartz window, and illuminated the inside of the cabinet with simulated sunlight. He filled the electrolysis container with 30 per cent sulphuric acid (also known as battery acid) that has a freezing point around -35 degrees Celsius and conducts electricity well.

Kölbach then set up the experimental cells, and carried out the series of measurements. During operation, it became apparent that the cell with the thermally coupled PV modules produced comparatively more hydrogen, since the illuminated PV modules pass their waste heat directly to the electrolyser. "We were even able to increase the efficiency by adding additional thermal insulation to the electrolyser. As a result, the electrolyte temperature climbed during illumination from -20 to as high as +13.5 degrees Celsius", says Kölbach.

The results of this study confirm that thermally coupled systems have potentially higher efficiency than thermally decoupled ones. Whether these advantages can be exploited economically, however, remains to be seen. "Therefore, in the next phase we want to test prototypes under realistic conditions. That will certainly be exciting and we are currently looking for partners for this", says May.

Locally generated solar hydrogen could be an option for replacing fossil fuels and eliminating the associated pollution danger to the environment and CO2 emissions, not only at the South Pole, but also in other extremely cold and sparsely populated regions of the world. This could include the high Alps, Canada and Alaska, the Andes, and other mountainous regions like the Himalayas.

"Perhaps solar-generated hydrogen will be economically viable initially in these kinds of remote regions of the world", says May, recalling the triumphant advance of photovoltaics, which first began supplying power to satellites in space about 60 years ago.

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The study was supported by the Volkswagen Foundation under their "Experiment!" funding initiative ("Solar Hydrogen for Antarctica: Water Splitting under Extreme Conditions").


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The experiment is located in the freezer. Light comes through a window and generates via solar cells the voltage needed for electrolytical water splitting.

CREDIT

M. Kölbach/HZB


CAPTION

Efficiency increases, when the photovoltaic module is in close contact with the wall of the electrolysis tank.

CREDIT

M. Kölbach/HZB