Friday, July 22, 2022

Could modified train cars capture carbon from the air? This team has a plan to make it happen

CELL PRESS

Train car for direct air capture — IMAGE: TRAIN CAR FOR DIRECT AIR CAPTURE view more
CREDIT: JOULE/BACHMAN ET AL.

Direct air capture technology removes carbon dioxide from the air and compresses it for sequestration or utilization and promises to help us meet net-zero emissions goals. However, the process of direct air capture can be energy and land intensive and expensive. To design a direct air capture process that uses less energy and less land, a multi-disciplinary team outlines a plan to retrofit train cars to remove carbon from the air at a much lower than average cost per tonne in an article published in a peer-reviewed article in the journal Joule on July 20.

Stationary direct air capture facilities require large areas of land to house their equipment and construct the renewable energy sources required to support them. Obtaining the proper permits to operate can be difficult, and many residents are opposed to the construction of these large facilities in their towns and cities. “It’s a huge problem because most everybody wants to fix the climate crisis, but nobody wants to do it in their backyard,” says co-author Geoffrey Ozin, a carbon dioxide utilization chemist and chemical engineer and director of the solar fuels group at the University of Toronto. “Rail-based direct air capture cars would not require zoning or building permits and would be transient and generally unseen by the public.”

These purpose-built train cars use large vents to intake air, which would eliminate the need for the energy-intensive fan systems that stationary direct air capture systems use. After a sufficient amount of carbon dioxide has been captured, the chamber is closed, and the harvested carbon dioxide is collected, concentrated, and stored in a liquid reservoir until it can be emptied from the train at crew-change or fueling stops for direct transportation into the circular carbon economy or to nearby geological sequestration sites. The carbon-dioxide-free air then travels out the back or underside of the car and returns into the atmosphere.

When a train pumps the brakes, its energy braking system converts forward momentum into electrical energy. As the braking system is applied, the energy is dissipated in the form of heat and discharged out of the top of the train. “That is wasted energy,” says lead author E. Bachman, founder of CO2Rail. “Every complete braking maneuver generates enough energy to power 20 average homes for a day, so we're not talking about a trivial amount of energy.” This energy, the authors suggest, should be used to help mitigate climate change.

The authors argue that direct air capture becomes an even more viable climate solution because the rail system is already in place. “The infrastructure exists,” says Ozin. “That's the bottom line. All you need to do is take advantage of what is already available.”

The researchers say that an average freight train with these direct air capture cars could remove up to 6,000 tonnes of carbon dioxide per year. Because its sustainable-energy needs are being supplied by on-board sources, the price per tonne is significantly lower than that of other direct air capture systems. “The projected cost at scale is less than $50 per tonne, which makes the technology not only commercially feasible but commercially attractive,” Bachman says.

The authors hope this technology could have a positive impact beyond the carbon it removes from the atmosphere. “We could get a positive-feedback loop where the encouragement of rail to broadly deploy these direct air capture rail cars could even further decrease carbon emissions because rail is about five or six times more efficient than trucks,” says Bachman. “By increasing rail utilization, you increase the efficiency of the entire transportation system.”

###

Joule, Bachman et al. “Rail-Based Direct Air Carbon Capture” https://www.cell.com/joule/fulltext/S2542-4351(22)00299-9

Joule (@Joule_CP), published monthly by Cell Press, is a new home for outstanding and insightful research, analysis, and ideas addressing the need for more sustainable energy. A sister journal to Cell, Joule spans all scales of energy research, from fundamental laboratory research into energy conversion and storage to impactful analysis at the global level. Visit http://www.cell.com/joule. To receive Cell Press media alerts, contact press@cell.com.

JOURNAL

Joule

DOI

10.1016/j.joule.2022.06.025

METHOD OF RESEARCH

Commentary/editorial

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Rail-Based Direct Air Carbon Capture

ARTICLE PUBLICATION DATE

20-Jul-2022

Modified rail cars clean air of CO2 and help mitigate climate change

Researchers from the University of Sheffield are working with US-based CO2Rail Company to design Direct Air Capture equipment which can be used within special rail cars placed with already running trains

Peer-Reviewed Publication

UNIVERSITY OF SHEFFIELD

New research shows rail systems around the world could be harnessed to help mitigate climate change and clean our air of CO2
Researchers from the University of Sheffield are working with US-based CO2Rail Company to design Direct Air Capture equipment which can be used within special rail cars placed with already running trains
On average, each complete train braking manoeuvre generates enough energy to power 20 homes for an entire day - until now this enormous amount of sustainable energy has been wasted
If the energy of every stop or deceleration for every train in the world could be captured it would harness 105 times more energy than the Hoover Dam produces in the same time period

Rail systems around the world could help mitigate climate change and clean the air of CO2 by capturing the sustainable energy generated when trains break and decelerate.

US-based startup, CO2Rail Company have been working with a world-renowned team of researchers, including engineers from the University of Sheffield, to design Direct Air Capture (DAC) technology that removes carbon dioxide from the air, which can be used within special rail cars placed with already running trains in regular service.

The DAC rail cars work by using large intakes of air that extend up into the slipstream of the moving train to move ambient air into the large cylindrical CO2 collection chamber and eliminate the need for energy-intensive fan systems that are necessary with stationary DAC operations.

The air then moves through a chemical process that separates the CO2 from the air and the carbon dioxide free air then travels out of the back or underside of the car and returns to the atmosphere.

After a sufficient amount has been captured, the chamber is closed and the harvested CO2 is collected, concentrated, and stored in a liquid reservoir until it can be emptied from the train at a crew change or fuelling stop into normal CO2 rail tank cars. It is then transported into the circular carbon economy as value-added feedstock for CO2 utilisation, or to nearby geological landfill sites.

Each of these processes are powered exclusively by on-board generated, sustainable energy sources that require no external energy input or off-duty charging cycles.

When a train pumps the brakes, its energy braking system converts the train’s forward momentum into electrical energy in much the same way as a regenerative electric vehicle. Currently, this energy is dissipated on trains in the form of heat and discharged out of the top of the locomotive during every braking manoeuvre.

Professor Peter Styring, Director of the UK Centre for Carbon Dioxide Utilization at the University of Sheffield and co-author of the research, said: “The direct capture of carbon dioxide from the environment is increasingly becoming an urgent necessity to mitigate the worst effects of climate change.

“Currently the enormous amount of sustainable energy created when a train brakes or decelerates is simply lost. This innovative technology will not only use the sustainable energy created by the braking manoeuvre to harvest significant quantities of CO2, but it will also take advantage of many synergies that integration within the global rail network would provide.

“The technology will harvest meaningful quantities of CO2 at far lower costs and has the potential to reach annual productivity of 0.45 gigatons by 2030, 2.9 gigatons by 2050, and 7.8 gigatons by 2075 with each car having an annual capacity of 3,000 tonnes of CO2 in the near term.”

Unlike stationary DAC operations, which require large areas of land to build equipment and to construct renewable sources of energy to power them, CO2Rail would be transient and would generally be unseen by the public. The potential impact of this technology was recently energised when European transport organisations announced earlier this month that they are committed to tripling high-speed rail use by 2050 to curb CO2-heavy air travel.

Eric Bachman of CO2Rail Company, said: “On average, each complete braking manoeuvre generates enough energy to power 20 average homes for an entire day so it is not a trivial amount of energy.

“Multiply this by every stop or deceleration for nearly every train in the world and you have about 105 times more energy than the Hoover Dam produces within that same period, and that was a hydro-electric construction project that took six years and cost $760 million in today’s dollars.”

He added: “Imagine stepping onto a train each morning, seeing the CO2Rail cars attached, and knowing that your commute to work each day is actually helping to mitigate climate change.

“It will work the same with freight, if there is a choice between rail and another mode of transportation, I think this technology will sway many shippers.”

The team, which includes researchers from the University of Sheffield, University of Toronto, MIT, Princeton, business, and industry, found each direct air capture car can harvest about 6,000 metric tons of carbon dioxide from the air per year and more as the technology develops. Moreover, since trains are capable of hosting multiple CO2Rail cars, each train will harvest a corresponding multiple of CO2 tonnage.

With its sustainable power requirements exclusively supplied by train-generated sources that are without incremental cost, savings of 30 – 40 per cent per tonne of harvested CO2 can be realised from energy inputs alone.

This, along with other significant savings such as land, brings projected cost at scale down to less than $50 per tonne and makes the technology not only commercially viable but commercially attractive.

Professor Geoffrey Ozin from the University of Toronto and co-author of the study, said: “At these price points and with its tremendous capabilities, CO2Rail is likely to soon become the first megaton-scale, first gigaton-scale, and overall largest provider of direct air capture deployments in the world.

“Carbon-neutral in regular transportation and then significantly carbon-negative with ambient air DAC operations. A win-win in every respect and a ‘save humanity’ technology.”

The team is also working on a similar system that can remove the CO2 emissions from the exhaust of diesel-powered locomotives as are universally common in North America and other parts of the world. With the growth of sustainably-sourced rail electrification systems, this point-source capability on diesel lines would make rail the world’s first carbon-neutral mode of large-scale transportation.

The research entitled: “Rail-Based Direct Air Carbon Capture” is published in the Future Energy section of the journal Joule.

Media contact: Amy Huxtable, Media and PR Officer, University of Sheffield, mediateam@sheffield.ac.uk, 07725 213702

JOURNAL

Joule

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Rail-Based Direct Air Carbon Capture

ARTICLE PUBLICATION DATE

20-Jul-2022

All-in-one solar-powered tower makes carbon-neutral jet fuel

Peer-Reviewed Publication

CELL PRESS

Solar tower fuel plant during operation — IMAGE: SOLAR TOWER FUEL PLANT DURING OPERATION view more
CREDIT: IMDEA ENERGY

Researchers have designed a fuel production system that uses water, carbon dioxide (CO2), and sunlight to produce aviation fuel. They have implemented the system in the field, and the design, publishing July 20 in the journal Joule, could help the aviation industry become carbon neutral.

“We are the first to demonstrate the entire thermochemical process chain from water and CO2 to kerosene in a fully-integrated solar tower system,” says Aldo Steinfeld (@solarfuels), a professor from ETH Zurich and the corresponding author of the paper. Previous attempts to produce aviation fuels through the use of solar energy have mostly been performed in the laboratory.

The aviation sector is responsible for about 5% of global anthropogenic emissions causing climate change. It relies heavily on kerosene, or jet fuel, which is a liquid hydrocarbon fuel typically derived from crude oil. Currently, no clean alternative is available to power long-haul commercial flights at the global scale.

“With our solar technology, we have shown that we can produce synthetic kerosene from water and CO2 instead of deriving it from fossil fuels. The amount of CO2 emitted during kerosene combustion in a jet engine equals that consumed during its production in the solar plant,” Steinfeld says. “That makes the fuel carbon neutral, especially if we use CO2 captured directly from the air as an ingredient, hopefully in the not-too-distant future.”

As a part of the European Union’s SUN-to-LIQUID project, Steinfeld and his colleagues have developed a system that uses solar energy to produce drop-in fuels, which are synthetic alternatives to fossil-derived fuels such as kerosene and diesel. The solar-made kerosene is fully compatible with the existing aviation infrastructure for fuel storage, distribution, and end use in jet engines, Steinfeld says. It can also be blended with fossil-derived kerosene, he adds.

In 2017, the team started scaling up the design and built a solar fuel-production plant at IMDEA Energy Institute in Spain. The plant consists of 169 sun-tracking reflective panels that redirect and concentrate solar radiation into a solar reactor mounted on top of a tower. The concentrated solar energy then drives oxidation-reduction (redox) reaction cycles in the solar reactor, which contains a porous structure made of ceria. The ceria –which is not consumed but can be used over and over –converts water and CO2 injected into the reactor into syngas, a tailored mixture of hydrogen and carbon monoxide. Subsequently, syngas is sent into a gas-to-liquid converter, where it is finally processed into liquid hydrocarbon fuels that include kerosene and diesel.

“This solar tower fuel plant was operated with a setup relevant to industrial implementation, setting a technological milestone towards the production of sustainable aviation fuels,” Steinfeld says.

During a nine-day run of the plant reported in the paper, the solar reactor’s energy efficiency—the portion of solar energy input that is converted into the energy content of the syngas produced—was around 4%. Steinfeld says his team is working intensively on improving the design to increase the efficiency to values over 15%. For example, they are exploring ways to optimize the ceria structure for absorbing solar radiation and developing methods to recover the heat released during the redox cycles.

CAPTION

Schematic of the solar tower fuel plant

CREDIT

ETH Zurich

This work is supported by Swiss State Secretariat for Education, Research and Innovation, and the EU Horizon 2020 research and innovation program.

Joule, Zoller et al. “A solar tower fuel plant for the thermochemical production of kerosene from H2O and CO2” https://www.cell.com/joule/fulltext/S2542-4351(22)00286-0

JOURNAL

Joule

DOI

10.1016/j.joule.2022.06.012

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

A Solar Tower Fuel Plant for the Thermochemical Production of Kerosene from H2O and CO2

ARTICLE PUBLICATION DATE

20-Jul-2022

OUR QUANTUM REALITY CHANGED

Strange new phase of matter created in quantum computer acts like it has two time dimensions

By subjecting a quantum computer’s qubits to quasi-rhythmic laser pulses based on the Fibonacci sequence, physicists demonstrated a way of storing quantum information that is less prone to errors

Peer-Reviewed Publication

SIMONS FOUNDATION

By shining a laser pulse sequence inspired by the Fibonacci numbers at atoms inside a quantum computer, physicists have created a remarkable, never-before-seen phase of matter. The phase has the benefits of two time dimensions despite there still being only one singular flow of time, the physicists report July 20 in Nature.

This mind-bending property offers a sought-after benefit: Information stored in the phase is far more protected against errors than with alternative setups currently used in quantum computers. As a result, the information can exist without getting garbled for much longer, an important milestone for making quantum computing viable, says study lead author Philipp Dumitrescu.

The approach’s use of an “extra” time dimension “is a completely different way of thinking about phases of matter,” says Dumitrescu, who worked on the project as a research fellow at the Flatiron Institute’s Center for Computational Quantum Physics in New York City. “I’ve been working on these theory ideas for over five years, and seeing them come actually to be realized in experiments is exciting.”

Dumitrescu spearheaded the study’s theoretical component with Andrew Potter of the University of British Columbia in Vancouver, Romain Vasseur of the University of Massachusetts, Amherst, and Ajesh Kumar of the University of Texas at Austin. The experiments were carried out on a quantum computer at Quantinuum in Broomfield, Colorado, by a team led by Brian Neyenhuis.

The workhorses of the team’s quantum computer are 10 atomic ions of an element called ytterbium. Each ion is individually held and controlled by electric fields produced by an ion trap, and can be manipulated or measured using laser pulses.

Each of those atomic ions serves as what scientists dub a quantum bit, or ‘qubit.’ Whereas traditional computers quantify information in bits (each representing a 0 or a 1), the qubits used by quantum computers leverage the strangeness of quantum mechanics to store even more information. Just as Schrödinger’s cat is both dead and alive in its box, a qubit can be a 0, a 1 or a mashup — or ‘superposition’ — of both. That extra information density and the way qubits interact with one another promise to allow quantum computers to tackle computational problems far beyond the reach of conventional computers.

There’s a big problem, though: Just as peeking in Schrödinger’s box seals the cat’s fate, so does interacting with a qubit. And that interaction doesn’t even have to be deliberate. “Even if you keep all the atoms under tight control, they can lose their quantumness by talking to their environment, heating up or interacting with things in ways you didn’t plan,” Dumitrescu says. “In practice, experimental devices have many sources of error that can degrade coherence after just a few laser pulses.”

The challenge, therefore, is to make qubits more robust. To do that, physicists can use ‘symmetries,’ essentially properties that hold up to change. (A snowflake, for instance, has rotational symmetry because it looks the same when rotated by 60 degrees.) One method is adding time symmetry by blasting the atoms with rhythmic laser pulses. This approach helps, but Dumitrescu and his collaborators wondered if they could go further. So instead of just one time symmetry, they aimed to add two by using ordered but non-repeating laser pulses.

The best way to understand their approach is by considering something else ordered yet non-repeating: ‘quasicrystals.’ A typical crystal has a regular, repeating structure, like the hexagons in a honeycomb. A quasicrystal still has order, but its patterns never repeat. (Penrose tiling is one example of this.) Even more mind-boggling is that quasicrystals are crystals from higher dimensions projected, or squished down, into lower dimensions. Those higher dimensions can even be beyond physical space’s three dimensions: A 2-D Penrose tiling, for instance, is a projected slice of a 5-D lattice.

For the qubits, Dumitrescu, Vasseur and Potter proposed in 2018 the creation of a quasicrystal in time rather than space. Whereas a periodic laser pulse would alternate (A, B, A, B, A, B, etc.), the researchers created a quasi-periodic laser-pulse regimen based on the Fibonacci sequence. In such a sequence, each part of the sequence is the sum of the two previous parts (A, AB, ABA, ABAAB, ABAABABA, etc.). This arrangement, just like a quasicrystal, is ordered without repeating. And, akin to a quasicrystal, it’s a 2D pattern squashed into a single dimension. That dimensional flattening theoretically results in two time symmetries instead of just one: The system essentially gets a bonus symmetry from a nonexistent extra time dimension.

Actual quantum computers are incredibly complex experimental systems, though, so whether the benefits promised by the theory would endure in real-world qubits remained unproven.

Using Quantinuum’s quantum computer, the experientialists put the theory to the test. They pulsed laser light at the computer’s qubits both periodically and using the sequence based on the Fibonacci numbers. The focus was on the qubits at either end of the 10-atom lineup; that’s where the researchers expected to see the new phase of matter experiencing two time symmetries at once. In the periodic test, the edge qubits stayed quantum for around 1.5 seconds — already an impressive length given that the qubits were interacting strongly with one another. With the quasi-periodic pattern, the qubits stayed quantum for the entire length of the experiment, about 5.5 seconds. That’s because the extra time symmetry provided more protection, Dumitrescu says.

“With this quasi-periodic sequence, there’s a complicated evolution that cancels out all the errors that live on the edge,” he says. “Because of that, the edge stays quantum-mechanically coherent much, much longer than you’d expect.”

Though the findings demonstrate that the new phase of matter can act as long-term quantum information storage, the researchers still need to functionally integrate the phase with the computational side of quantum computing. “We have this direct, tantalizing application, but we need to find a way to hook it into the calculations,” Dumitrescu says. “That’s an open problem we’re working on.”

CAPTION

The Penrose tiling pattern is a type of quasicrystal, which means that it has an ordered yet never-repeating structure. The pattern, composed of two shapes, is a 2D projection of a 5D square lattice.

CREDIT

None

ABOUT THE FLATIRON INSTITUTE

The Flatiron Institute is the research division of the Simons Foundation. The institute's mission is to advance scientific research through computational methods, including data analysis, theory, modeling and simulation. The institute's Center for Computational Quantum Physics aims to develop the concepts, theories, algorithms and codes needed to solve the quantum many-body problem and to use the solutions to predict the behavior of materials and molecules of scientific and technological interest.

JOURNAL

Nature

DOI

10.1038/s41586-022-04853-4

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Dynamical topological phase realized in a trapped-ion quantum simulator

ARTICLE PUBLICATION DATE

20-Jul-2022

New fossil shows four-legged fishapod that returned to the water while Tiktaalik ventured onto land

Researchers discover a new fossil that is closely related to other animals that made the transition to land, but with features more suited for swimming and life in the water

Peer-Reviewed Publication

UNIVERSITY OF CHICAGO

Qiqiktania reconstruction — IMAGE: ILLUSTRATION OF QIKIQTANIA WAKEI (CENTER) IN THE WATER WITH ITS LARGER COUSING, TIKTAALIK ROSEAE view more
CREDIT: ALEX BOERSMA

A meme has been circulating online during the pandemic featuring Tiktaalik roseae, the iconic, four-legged “fishapod” that first made the transition from water to land 375 million years ago. Most variations show Tiktaalik poking its head out of the water and ready to crawl ashore, while an out of frame hand threatens it with a rolled-up newspaper or a stick. The joke is that those of us exhausted by the modern world wish we could go back in time, shoo it back into the water, and stop evolution in its tracks, sparing ourselves the present day of war, pestilence, and internet memes.

As it turns out, one of Tiktaalik’s close relatives did just that, opting to return to living in open water instead of venturing onto land. A new study from the laboratory of Neil Shubin, PhD, who co-discovered Tiktaalik in 2004, describes a fossil species that closely resembles Tiktaalik but has features that made it more suited to life in the water than its adventurous cousin. Qikiqtania wakei was small—just 30 inches long—compared to Tiktaalik, which could grow up to nine feet. The new fossil includes partial upper and lower jaws, portions of the neck, and scales. Mostly importantly, it also features a complete pectoral fin with a distinct humerus bone that lacks the ridges that would indicate where muscles and joints would be on a limb geared toward walking on land. Instead, Qikiqtania’s upper arm was smooth and curved, more suited for a life paddling underwater. The uniqueness of the arm bones of Qikiqtania suggest that it returned to paddling the water after its ancestors began to use their appendages for walking.

“At first we thought it could be a juvenile Tiktaalik, because it was smaller and maybe some of those processes hadn’t developed yet,” Shubin said. “But the humerus is smooth and boomerang shaped, and it doesn’t have the elements that would support it pushing up on land. It’s remarkably different and suggests something new.”

The paper, “A New Elpistostegalian from the Late Devonian of the Canadian Arctic and the diversity of stem tetrapods,” was published July 20, 2022, in Nature.

A prehistoric pandemic project

Shubin, who is the Robert R. Bensley Distinguished Service Professor of Organismal Biology and Anatomy at the University of Chicago, found the fossil days before Tiktaalik was discovered, at a site about one mile east on southern Ellesmere Island in the territory of Nunavut in northern Arctic Canada. The name Qikiatania comes from the Inuktitut word Qikiqtaaluk or Qikiqtani, the traditional name for the region where the fossil site is located. The species designation wakei is in memory of the late David Wake, an eminent evolutionary biologist from the University of California at Berkeley.

Shubin and his field partner, Ted Daeschler, PhD, from the Academy of Natural Sciences of Drexel University, collected the specimens from a quarry after spotting a few promising looking rocks with distinctive, white scales on the surface. But they sat in storage, mostly unexamined, while the team focused on preparing Tiktaalik.

Fifteen years later, the discovery of Qikiqtania became another pandemic story. Postdoctoral researchers Justin Lemberg, PhD, and Tom Stewart, PhD, CT-scanned one of the larger rock specimens in March 2020 and realized that it contained a pectoral fin. Unfortunately, it was too deep inside the rock to get a high-resolution image, and they couldn’t do much more with it once the pandemic forced labs to close.

"We were trying to collect as much CT-data of the material as we could before the lockdown, and the very last piece we scanned was a large, unassuming block with only a few flecks of scales visible from the surface,” said Lemberg, who is now doing cultural resource management fieldwork in Southern California. “We could hardly believe it when the first, grainy images of a pectoral fin came into view. We knew we could collect a better scan of the block if we had the time, but that was March 13th, 2020, and the University shut down all non-essential operations the following week."

In the summer of 2020 when campus facilities reopened, they contacted Mark Webster, PhD, Associate Professor of Geophysical Sciences, who had access to a saw that could trim pieces off the specimen so that a CT scanner could get closer and produce a better image. Stewart and Lemberg carefully marked the boundaries on the block and arranged an exchange outside their lab in Culver Hall. The resulting images revealed a nearly complete pectoral fin and upper limb, including the distinctive humerus bone.

“That’s what blew our minds,” Shubin said. “This was by no means a fascinating block at first, but we realized during the COVID lockdown when we couldn’t get in the lab that the original scan wasn’t good enough and we needed to trim the block. And when we did, look at what happened. It gave us something exciting to work on during the pandemic. It’s a fabulous story.”

Glimpses into vertebrate history

Qikiqtania is slightly older than Tiktaalik but not by much. The team’s analysis of where it sits on the tree of life places it, like Tiktaalik, adjacent to the earliest creatures known to have finger-like digits. But even though Qikiqtania’s distinct pectoral fin was more suited for swimming, it wasn’t entirely fish-like either. Its curved paddle shape was a distinct adaptation, different from the jointed, muscled legs or fan-shaped fins we see in tetrapods and fish today.

We tend to think animals evolved in a straight line that connects their prehistoric forms to some living creature today, but Qikiqtania shows that some animals stayed on a different path that ultimately didn’t work out. Maybe that’s a lesson for those wishing Tiktaalik had stayed in the water with it.

“Tiktaalik is often treated as a transitional animal because it’s easy to see the stepwise pattern of changes from life in the water to life on land. But we know that in evolution things aren’t always so simple,” said Stewart, who will be joining the faculty at Penn State University this summer. “We don’t often get glimpses into this part of vertebrate history. Now we’re starting to uncover that diversity and to get a sense of the ecology and unique adaptations of these animals. It’s more than simple transformation with just a limited number of species.”

The research was supported by the Brinson Foundation, the Academy of Natural Sciences of Drexel University, the University of Chicago Biological Sciences Division, the Polar Continental Shelf Program of Natural Resources Canada, the Nunavut Department of Culture and Heritage, the Hamlet of Grise Fiord and its Iviq Hunters and Trappers Association, and the National Science Foundation.

Qiqiktania video 1 [VIDEO] | EurekAlert! Science News Releases

Qiqiktania video 2 [VIDEO] | EurekAlert! Science News Releases

CAPTION

Tom Stewart, PhD, Assistant Professor of Biology at Penn State University, holds the fossil specimen of Qikiqtania wakei

CREDIT

Tom Stewart

JOURNAL

Nature

DOI

10.1038/s41586-022-04990-w

METHOD OF RESEARCH

Imaging analysis

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

A new elpistostegalian from the Late Devonian of the Canadian Arctic

ARTICLE PUBLICATION DATE

20-Jul-2022

Human eggs remain healthy for decades by putting ‘batteries on standby mode’

Researchers at the CRG have solved how oocytes remain dormant without losing their reproductive capacity. The findings are reported in the journal Nature.

Peer-Reviewed Publication

CENTER FOR GENOMIC REGULATION

Absence of reactive oxygen species shown in oocytes — IMAGE: LIVE CELL IMAGING OF HUMAN FOLLICLE, SHOWING GRANULOSA CELLS ON THE OUTER LAYER, WHICH SUPPORT THE OOCYTE, CONTAINED WITHIN. THE ACTIVITY OF REACTIVE OXYGEN SPECIES IS SHOWN IN RED. THE RESEARCHERS OBSERVED ROS ACTIVITY IN THE GRANULOSA CELLS BUT IT IS VIRTUALLY ABSENT IN THE OOCYTE. view more
CREDIT: AIDA RODRIGUEZ/NATURE

Immature human egg cells skip a fundamental metabolic reaction thought to be essential for generating energy, according to the findings of a study by researchers at the Centre for Genomic Regulation (CRG) published today in the journal Nature.

By altering their metabolic activity, the cells avoid creating reactive oxygen species, harmful molecules that can accumulate, damage DNA and cause cell death. The findings explain how human egg cells remain dormant in ovaries for up to 50 years without losing their reproductive capacity.

“Humans are born with all the supply of egg cells they have in life. As humans are also the longest-lived terrestrial mammal, egg cells have to maintain pristine conditions while avoiding decades of wear-and-tear. We show this problem is solved by skipping a fundamental metabolic reaction that is also the main source of damage for the cell. As a long-term maintenance strategy, its like putting batteries on standby mode. This represents a brand new paradigm never before seen in animal cells,” says Dr. Aida Rodriguez, postdoctoral researcher at the CRG and first author of the study.

Human eggs are first formed in the ovaries during foetal development, undergoing different stages of maturation. During the early stages of this process, immature egg cells known as oocytes are put into cellular arrest, remaining dormant for up to 50 years in the ovaries. Like all other eukaryotic cells, oocytes have mitochondria – the batteries of the cell – which they use to generate energy for their needs during this period of dormancy.

Using a combination of live imaging, proteomic and biochemistry techniques, the authors of the study found that mitochondria in both human and Xenopus oocytes use alternative metabolic pathways to generate energy never before seen in other animal cell types.

A complex protein and enzyme known as complex I is the usual ‘gatekeeper’ that initiates the reactions required to generate energy in mitochondria. This protein is fundamental, working in the cells that constitute living organisms ranging from yeast to blue whales. However, the researchers found that complex I is virtually absent in oocytes. The only other type of cell known to survive with depleted complex I levels are all the cells that make up the parasitic plant mistletoe.

According to the authors of the study, the research explains why some women with mitochondrial conditions linked to complex I, such as Leber’s Hereditary Optic Neuropathy, do not experience reduced fertility compared to women with conditions affecting other mitochondrial respiratory complexes.

The findings could also lead to new strategies that help preserve the ovarian reserves of patients undergoing cancer treatment. “Complex I inhibitors have previously been proposed as a cancer treatment. If these inhibitors show promise in future studies, they could potentially target cancerous cells while sparing oocytes,” explains Dr. Elvan Böke, senior author of the study and Group Leader in the Cell & Developmental Biology programme at the CRG.

Oocytes are vastly different to other types of cells because they have to balance longevity with function. The researchers plan to continue this line of research and uncover the energy source oocytes use during their long dormancy in the absence of complex I, with one of the aims being to understand the effect of nutrition on female fertility.

“One in four cases of female infertility are unexplained – pointing to a huge gap of knowledge in our understanding of female reproduction. Our ambition is to discover the strategies (such as the lack of complex I ) oocytes employ to stay healthy for many years in order to find out why these strategies eventually fail with advanced age” concludes Dr. Böke.

JOURNAL

Nature

DOI

10.1038/s41586-022-04979-5

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Human tissue samples

ARTICLE TITLE

Oocytes maintain ROS-free mitochondrial metabolism by suppressing complex I

ARTICLE PUBLICATION DATE

20-Jul-2022