Ocean warming is accelerating, and hotspots reveal which areas are absorbing the most heat

A new study reveals increasing warming rates in the world’s oceans in recent decades and the locations with the greatest heat uptake

Peer-Reviewed Publication

UNIVERSITY OF NEW SOUTH WALES

Ocean warming has accelerated dramatically since the 1990s, nearly doubling during 2010–2020 relative to 1990–2000, according to new UNSW Sydney-led research.

The study, published this week in Nature Communications, also shows some areas of the ocean are doing more of the work in heat uptake or absorption, which has implications for our understanding of sea-level rise and climate impacts.

Increasing concentrations of greenhouse gases in the atmosphere from human activity traps heat within the climate system, warming air, the land surface, the oceans, and melting polar ice. Oceans do by far the most work, absorbing more than 90 per cent of the excess human-generated heat accumulated in the Earth’s climate system, moderating atmospheric temperature rises.

While ocean warming helps slow the pace of climate change, it is not without cost, says Scientia Professor Matthew England, co-author of the study from the UNSW Centre for Marine Science and Innovation.

“The world ocean, in 2023, is now the hottest ever recorded, and sea levels are rising because heat causes water to expand and ice to melt,” says Prof. England. “Ecosystems are also experiencing unprecedented heat stress, and the frequency and intensity of extreme weather events are changing rapidly, and the costs are enormous.”

“Right now, the ocean is warming at a dramatically accelerating rate, nearly doubling during the 2010s relative to the 1990s,” says Dr Zhi Li, lead author of the study from the UNSW Centre for Marine Science and Innovation. “What we wanted to do in this study was to figure out exactly where this ocean heat uptake has been occurring.”

Hotspots of ocean heat uptake

For the study, the researchers evaluated all available observations of ocean warming activity spanning modern Argo float data – an international ocean research program that collects information using robotic instruments – to those taken in the 1950s when only sparse measurements were made from ship-borne devices. They then analysed the heat uptake across water masses and quantified each water mass’s role in ocean heat content change.

They found oceanic warming has been pervasive worldwide, spreading from the surface to the deep-sea regions known as the abyssal layers and spanning each basin from the tropics to the polar regions. However, the distribution of ocean warming by region was far from uniform.

The Southern Ocean saw the largest increase in heat storage over the past two decades, holding almost the same excess anthropogenic heat as the Atlantic, Pacific, and Indian Ocean combined. This includes two large masses of water in the Southern Ocean that combine to fill a depth range of 300 – 1500 metres.

“Melting ice caps, extreme weather, and marine ecosystems, including coral reefs, are all highly sensitive to ocean temperature changes,” says Dr Sjoerd Groeskamp, co-author of the study from the Royal Netherlands Institute for Sea Research. “It is critical we understand exactly how and where the ocean warms – both now and into the future.”

Exactly how heat uptake plays out over the coming decades and beyond remains highly uncertain. For example, if the oceans develop a reduced capacity to absorb heat, it will have profound implications for the rate of future climate change.

The scientists say their findings highlight an urgent need to increase monitoring of the global oceans, especially in remote locations like the polar oceans, as well as key regions of the subtropical and coastal seas to better understand and predict sea-level rise and impacts on marine ecosystems.

“Without Argo floats, for example, this study would not have been possible,” says Prof. England.

The team also call for more international action from big-emitting nations to meet their net zero carbon targets as soon as possible and limit the damage from uncontrolled ocean warming.

“Without any action, these net zero pledges are just meaningless,” says Dr Groeskamp.

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JOURNAL

Nature Communications

DOI

10.1038/s41467-023-42468-z 

METHOD OF RESEARCH

Data/statistical analysis

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Recent acceleration in global ocean heat accumulation by mode and intermediate waters

Research explores whether coral islands could survive the impact of rising sea levels

Grant and Award Announcement

UNIVERSITY OF PLYMOUTH

A major international research project is to explore the potential for low-lying coral atoll islands to survive the predicted rise in sea level.

The islands, commonly found in the Indian and Pacific Oceans, are widely acknowledged to be among the world’s most vulnerable environments to climate change.

Most of them are presently predicted to be uninhabitable by the mid-21st century, but those forecasts are based on relatively simple hydrodynamic models.

A £2.8million ARISE project, funded through UK Research and Innovation’s Horizon Europe Guarantee programme, aims to improve our understanding of the processes that will threaten and preserve these island nations. It also aims to aid in the formulation, development and implementation of climate change adaptation strategies.

The project is being led by the Coastal Processes Research Group at the University of Plymouth, which has previously led studies suggesting that island ‘drowning’ may not be inevitable in the face of sea-level rise.

Gerd Masselink, Professor of Coastal Geomorphology at the University of Plymouth, is the project’s Principal Investigator. He said: “The rise in sea levels as a result of climate change is going to place many coastal communities under threat. Within that, it has largely been assumed that these coral atoll islands could just disappear. Our previous research has suggested that is not a foregone conclusion, and this project will establish the processes at play and as well as supporting the communities that call these islands home by identifying and evaluating adaptation strategies.”

The five-year project will include a series of extensive field tests in both the Maldives and the Pacific, beginning in January 2024 and continuing through 2027, using their state-of-the art coastal process research instrumentation and autonomous survey equipment.

There will also be laboratory experiments in the spring and summer of 2024 in the largest wave flume in the world - the Delta Flume at Deltares in the Netherlands.

Combined, these tests will enable researchers to explore the impact of overwashing on the islands’ beaches and any natural processes that are adding to their resilience.

The research teams will also be on standby to travel to the atoll island systems and analyse their response to cyclones and other extreme wave events.

The datasets generated through these tests will be used to develop, calibrate and validate a series of numerical models, which will then be used to evaluate how they might respond – both in the short and long-term – to sea level rise.

Much of the Coastal Processes Research Group’s previous work has been conducted with communities in the Maldives, and this project will extend this collaboration to the Pacific.

They will be working closely together with the Maldives Government, Secretariat of the Pacific Community and the Maldives National University.

The researchers also aim to work with communities and government bodies in the island nations, enabling them to implement adaptation strategies that maximise opportunities for continued habitation.

Professor Masselink added: “Atoll islands have been created over hundreds to thousands of years by ocean waves, and their future is intrinsically connected to it. The ecology of the reefs they sit on is also under threat, but their survival is critically important to the island’s survival. The big question is whether all of that can keep up with sea level rise, and answering that is crucial for both the islands and the people who live on them.”

In addition to academics and technicians from the Coastal Processes Research Group, and a number of international partners, the project has recruited six PhD candidates. They will be working with the researchers to explore the many and varied processes impacting the islands, and also the ways in which they might adapt to them.

For more about the project, and the research team leading it, visit https://www.plymouth.ac.uk/research-and-expertise/coastal-processes-research-group/arise

Investigators examine shifts in coral microbiome under hypoxia

Peer-Reviewed Publication

AMERICAN SOCIETY FOR MICROBIOLOGY

Washington, D.C.—A new study published in Applied and Environmental Microbiology, a journal of the American Society for Microbiology, provides the first characterization of the coral microbiome under hypoxia, insufficient oxygen in the water. The research is an initial step toward identifying potential beneficial bacteria for corals facing this environmental stressor. 

The researchers conducted the study because of the increasing awareness of the impact of the microbiome on host health. For example, a healthy human gut microbiome plays key roles in digestion, immune system response, and even mental health. As in humans, the coral microbiome has beneficial impacts on its host, the coral animal. These include disease prevention, nutrient uptake and resistance to environmental stressors like rising temperatures and acidification. 

Despite this, scientists know far less about the role of the microbiome when corals experience hypoxia. The researchers wanted to understand how the microorganisms living on the coral's surface react to hypoxia. They thought the work may provide insights on how symbiotic microbes respond to host and environmental stress. 

The researchers conducted their experiments in Bahiá Almirante, Bocas del Toro, Panama. “We picked this site because we have seen hypoxic events here associated with human activity, including agriculture and coastal development,” said lead study author Rachel Howard, Ph.D. candidate, Department of Soil, Water and Ecosystem Sciences, University of Florida. “We established experimental chambers which lowered dissolved oxygen on patches of coral reef. We then sampled the microorganisms living on corals in those chambers and corals outside the chambers after 2 days to see how the community of microbes differed with and without the stress of low oxygen.” 

The researchers found that when oxygen levels dropped, the overall coral microbiome changed after only 48 hours, and the number of some specific types of bacteria increased. The bacteria that increased are those that can survive without oxygen and are ready to take advantage of a change in resources. When there is not enough oxygen in the water, it throws the community of microorganisms on the coral out of balance, and some of the suspected harmful bacteria, such as Desulfovibrionaceae or Clostridia, become more active. 

“Because corals vary in their sensitivity to deoxygenation and given the crucial role of microorganisms in coral health, we suggest that changes in the microbiome may influence coral resilience to low oxygen conditions. Episodes of low oxygen, along with other impacts of climate change, pose a threat to coral and other marine organisms,”  Howard said. 

The researchers say that the microbiome is key to understanding the response of corals to stressors including warming seas. This study is a first step toward understanding the response of coral microbiomes to deoxygenation which, along with warming and ocean acidification, represent the “triple threat” of climate change to the ocean’s ecosystem.

The researchers plan to look more closely at the health of corals and relate that to the response of coral microbiomes when challenged by the stress of low oxygen.
 

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The American Society for Microbiology is one of the largest professional societies dedicated to the life sciences and is composed of 36,000 scientists and health practitioners. ASM's mission is to promote and advance the microbial sciences. 
 
ASM advances the microbial sciences through conferences, publications, certifications, educational opportunities and advocacy efforts. It enhances laboratory capacity around the globe through training and resources. It provides a network for scientists in academia, industry and clinical settings. Additionally, ASM promotes a deeper understanding of the microbial sciences to diverse audiences.  

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JOURNAL

Applied and Environmental Microbiology

 

Plastic-eating bacteria turn waste into useful starting materials for other products

Peer-Reviewed Publication

AMERICAN CHEMICAL SOCIETY

 

IMAGE: 

THESE BEADS CONTAIN ENGINEERED E. COLI THAT EFFICIENTLY TRANSFORM PET WASTE INTO A HIGH-VALUE COMPOUND.

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CREDIT: ADAPTED FROM ACS CENTRAL SCIENCE 2023, DOI: 10.1021/ACSCENTSCI.3C00414

Mountains of used plastic bottles get thrown away every day, but microbes could potentially tackle this problem. Now, researchers in ACS Central Science report that they’ve developed a plastic-eating E. coli that can efficiently turn polyethylene terephthalate (PET) waste into adipic acid, which is used to make nylon materials, drugs and fragrances.

Previously, a team of researchers including Stephen Wallace engineered a strain of E. coli to transform the main component in old PET bottles, terephthalic acid, into something tastier and more valuable: the vanilla flavor compound vanillin. At the same time, other researchers engineered microbes to metabolize terephthalic acid into a variety of small molecules, including short acids. So, Wallace and a new team from the University of Edinburgh wanted to expand E. coli’s biosynthetic pathways to include the metabolism of terephthalic acid into adipic acid, a feedstock for many everyday products that’s typically generated from fossil fuels using energy-intensive processes.

The team developed a new E. coli strain that produced enzymes that could transform terephthalic acid into compounds such as muconic acid and adipic acid. Then, to transform the muconic acid into adipic acid, they used a second type of E. coli, which produced hydrogen gas, and a palladium catalyst. In experiments, the team found that attaching the engineered microbial cells to alginate hydrogel beads improved their efficiency, and up to 79% of the terephthalic acid was converted into adipic acid. Using real-world samples of terephthalic acid from a discarded bottle and a coating taken from waste packaging labels, the engineered E. coli system efficiently produced adipic acid. In the future, the researchers say they will look for pathways to biosynthesize additional higher-value products.

The authors acknowledge funding from the Carnegie Trust for the Universities of Scotland; the Industrial Biotechnology Innovation Centre; a Future Leaders Fellowship from UK Research and Innovation; and an Engineering and Physical Sciences Research Council Sustainable Manufacturing grant.

The paper’s abstract will be available on Nov. 1 at 8 a.m. Eastern time here: http://pubs.acs.org/doi/abs/10.1021/acscentsci.3c00414  

The American Chemical Society (ACS) is a nonprofit organization chartered by the U.S. Congress. ACS’ mission is to advance the broader chemistry enterprise and its practitioners for the benefit of Earth and all its people. The Society is a global leader in promoting excellence in science education and providing access to chemistry-related information and research through its multiple research solutions, peer-reviewed journals, scientific conferences, eBooks and weekly news periodical Chemical & Engineering News. ACS journals are among the most cited, most trusted and most read within the scientific literature; however, ACS itself does not conduct chemical research. As a leader in scientific information solutions, its CAS division partners with global innovators to accelerate breakthroughs by curating, connecting and analyzing the world’s scientific knowledge. ACS’ main offices are in Washington, D.C., and Columbus, Ohio.

To automatically receive news releases from the American Chemical Society, contact newsroom@acs.org.

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JOURNAL

ACS Central Science

DOI

10.1021/acscentsci.3c00414 

ARTICLE TITLE

Plastic-eating bacteria turn waste into useful starting materials for other products

ARTICLE PUBLICATION DATE

1-Nov-2023

 

Toward sustainable construction: preparing liquefied stabilized soil from construction sludge

Scientists from Japan have developed high-flowability liquefied stabilized soil from construction sludge that could revolutionize the sustainability of the construction industry

Peer-Reviewed Publication

SHIBAURA INSTITUTE OF TECHNOLOGY

 

IMAGE: 

AN ADVANCED FORM OF LIQUEFIED STABILIZED SOIL (LLS), KNOWN AS HIGH-FLOWABILITY LIQUEFIED STABILIZED SOIL (HFLSS) HAS BEEN DEVELOPED FROM CONSTRUCTION SLUDGE. IT EXHIBITS SUPERIOR MECHANICAL PROPERTIES AND FLOWABILITY THAN CONVENTIONAL (LSS), PROMOTING THE CONCEPT OF SUSTAINABLE CONSTRUCTION.

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CREDIT: SHINYA INAZUMI FROM SIT, JAPAN

The construction industry is a highly resource-intensive and polluting sector, with significant water consumption and notable contribution to environmental degradation. According to a survey conducted by the Ministry of Land, Infrastructure, Transport, and Tourism in 2018, the Japanese construction sector discharged about 74.4 million tons of construction by-products, including 6.2 million tons of construction sludge. In recent years, the construction industry has made efforts to reduce its environmental impact and adopt more sustainable materials and processes. Sustainable construction emphasizes efficient resource utilization, particularly water management; and circularity, wherein construction waste is recycled within the industry.

One such example of circularity in construction is liquified stabilized soil (LSS), which comprises construction-generated soil or construction sludge that is mixed with a solidifier and intermediately treated. LSS is already widely used in construction sites, especially for filling long, narrow spaces where compaction by earthworks is challenging. The utility of LSS as a construction material lies in its flowability, which makes it easily pourable, and its strength after solidifying. LSS exhibits low permeability and high cohesive strength, making this material impervious to groundwater erosion. Moreover, it does not shrink much after casting, and its high adhesion ensures durability during earthquakes. However, despite these favorable properties, there is still scope for improving the characteristics of LSS to further expand its uses and enable more efficient construction practices.

To address this, a group of scientists from Shibaura Institute of Technology (SIT), Japan, and Kasetsart University, Thailand developed a high-flowability LSS (HFLSS) made with construction sludge (HFLSS from RCS) and examined its mechanical properties and flowability through experimental approaches. The team led by Prof. Shinya Inazumi, from the Department of Civil Engineering at SIT, developed their HFLSS using a dewatered solution of very fine clay particles that was derived after dewatering construction sludge. This dewatered solution was blended with ordinary Portland cement as the solidifier.

This paper was published in Volume 8, Issue 5 of Recycling on 30 August 2023. “Advances in LSS could transform the construction industry and urban development. Urbanization is increasing the demand for space-efficient construction solutions, and LSS and HFLSS made from RCS could be the answer. Their application in tight, challenging spaces could lead to more efficient and sustainable infrastructure projects, while alleviating environmental concerns through the reuse of construction waste,” says Prof. Inazumi.

The results of this experimental study show that HFLSS from RCS exhibits more favorable characteristics than conventional LSS for construction activities. The mechanical properties of HFLSS from RCS are lower than those of conventional LSS, whereas its flow value or flowability is higher than normal LSS (0.54m vs. 0.44m), owing to its lower specific gravity. The high flowability of HFLSS from RCS also results in a lower unconfined compressive strength than conventional LSS (515 kN/m2 vs. 1000 kN/m2). Usually, the unconfined compressive strength required for ordinary backfilling is ≥100–300 kN/m2, suggesting that HFLSS from RCS also meets this requirement.

These results establish HFLSS from RCS as a more efficient and advanced form of LSS extending its applications beyond the usual backfill/filling and road construction. With its high flowability, HFLSS from RCS can fill narrow spaces, such as waste pipes, making it more suitable for use within complex structures. Further, it can also be pumped for distances of 500m and more at lower pressures, decreasing intermediate work and construction time.

“These findings position HFLSS from RCS as a promising sustainable material for large-scale civil engineering projects. Future research on improving this material could revolutionize the construction industry. Overall, its implications are vast—from reduced construction waste and environmental impact, to faster, more efficient urban development, which would benefit economies and promote a sustainable future for generations to come,” concludes Prof. Inazumi.

 

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Reference

DOI: https://doi.org/10.3390/recycling8050067  

 

About Shibaura Institute of Technology (SIT), Japan

Shibaura Institute of Technology (SIT) is a private university with campuses in Tokyo and Saitama. Since the establishment of its predecessor, Tokyo Higher School of Industry and Commerce, in 1927, it has maintained “learning through practice” as its philosophy in the education of engineers. SIT was the only private science and engineering university selected for the Top Global University Project sponsored by the Ministry of Education, Culture, Sports, Science and Technology and will receive support from the ministry for 10 years starting from the 2014 academic year. Its motto, “Nurturing engineers who learn from society and contribute to society,” reflects its mission of fostering scientists and engineers who can contribute to the sustainable growth of the world by exposing their over 8,000 students to culturally diverse environments, where they learn to cope, collaborate, and relate with fellow students from around the world.

Website: https://www.shibaura-it.ac.jp/en/

 

About Professor Shinya Inazumi from SIT, Japan

Professor Shinya Inazumi is a geotechnical engineering professor at the Department of Civil Engineering, Shibaura Institute of Technology (SIT), Japan. He heads the Geotechnical Engineering Laboratory at SIT, which covers research areas such as civil engineering, environmental engineering, construction management, geotechnology, and environmental geotechnology. His research focuses on the development of technologies and solutions that address issues pertaining to disaster mitigation, environmental protection, resource optimization, pollution and waste management, and sustainable development. Before joining SIT, Prof. Inazumi also served as a professor at Kyoto University, Japan, and National Institute of Technology, Akashi College, Japan.

 

Funding Information

This research received no external funding.

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JOURNAL

Recycling

DOI

10.3390/recycling8050067 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Properties of High-Flowability Liquefied Stabilized Soil Made of Recycled Construction Sludge

 

Research from China University of Geosciences (Beijing) provides new insights into the India–Asia collision in the Western Himalayas dating back to circa 55 million years and the extent of Greater India

Compelling new evidence resolves discrepant interpretations and supports the large size of Greater India

Peer-Reviewed Publication

CACTUS COMMUNICATIONS

 

IMAGE: 

RECONSTRUCTION THROUGH TIME (TOP) SHOWING THE INDIAN PLATE BREAKING AWAY FROM THE GONDWANA SUPERCONTINENT AND SUBDUCTING UNDER ASIA, THEREBY HELPING TO CREATE THE WORLD'S HIGHEST TOPOGRAPHY, I.E., MOUNT EVEREST (BOTTOM).

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CREDIT: JUN MENG FROM CHINA UNIVERSITY OF GEOSCIENCES (BEIJING) AND PROF. STUART A. GILDER FROM LUDWIG MAXIMILIANS UNIVERSITY

Hundreds of millions of years ago, the surface of the Earth looked very different from how we see it today. There were just two continents: Laurasia and Gondwanaland. The present Indian subcontinent was part of Gondwanaland, which broke up about 150 million years ago. A part of the Indian Plate that broke away from the Gondwana supercontinent is now subducted under the Himalayas and the Tibetan Plateau. Understanding the original extent of the ‘lost’ part of this continent, called Greater India, is therefore important to resolve several key questions surrounding the age of the India–Asia collision and answer how and when the Tibetan Plateau got built.

However, estimates of the extent of Greater India have remained uncertain, varying from 100’s to more than 2,000 km. The Sangdanlin section lying between the Indian and Asian plates in southern Tibet represents a geologic Rosetta stone to constrain the initiation of the India–Asia collision; however, divergent evidence regarding its age and paleomagnetic record has made the estimation challenging.

Providing key answers, researchers from China University of Geosciences (Beijing) (CUGB) along with colleagues from other institutions, including Ludwig Maximilians University and Chinese Academy of Sciences, have now clarified that Greater India was a single plate of 2,000 to 3,000 km before it subducted under Asia. Professor Jun Meng from the School of Earth Sciences and Resources, CUGB, the first author of the study that was published in Proceedings of the National Academy of Sciences of the USA on August 8, 2023, explains, “There are two primary models for the India–Asia collision. The first is a multistage collision model that subdivides the oceanic basin at the leading edge of India into smaller plates that were later incorporated into the Asian plate. The second model says that India and Greater India existed as a single plate in the Early Cretaceous period, with the upper crust of the northern margin of Greater India forming the Himalayan thrust belt and the lower crust being subducted under Asia.” His colleague from CUGB, Professor Chengshan Wang adds, “Our goal was to understand which of these models was more accurate.”

The researchers resolved several questions surrounding these issues through a combined geologic, paleontologic, and paleomagnetic study of the infamous Sangdanlin section. The paleomagnetism of the Cretaceous rocks allowed the researchers to track the geographical position of the northern sector of the Indian Plate through time and calculate a minimum size for Greater India. The data obtained in the study showed that the lithosphere— the rocky outer shell of the Earth—consumed by subduction since the onset of the collision 55 mya was larger than the area of the Indian subcontinent today and originally extended ~2,000 to 3,000 km to the north. Consequently, almost 5 million km² of lithosphere has been subducted under the Asian Plate, which must have contributed to the rise of the Tibetan Plateau.

These findings represent a tectonic shift in our understanding of the India–Asia collision and the emergence of various geological structures in these regions.  Prof. Stuart A. Gilder from Ludwig Maximilians University observes, “Our findings challenge established notions of the formation of Asia’s southern margin through the coalescence of independent tectonic blocks in the Tethys Ocean. They could help us fill the gap in the knowledge regarding the size of the Indian plate in a Gondwanaland configuration and the tectonic history of India up until its collision with Asia.”

Disruptive discoveries advance human knowledge in leaps and bounds. Kudos to the research team for contributing to such a discovery!

For a quick animated version of this research story, check out this video, here.

 

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Reference

DOI: https://doi.org/10.1073/pnas.2305928120

Authors: Jun Menga, Stuart A. Gilderb, Xiaodong Tanc, Xin Lid, Yalin Lia, Hui Luod, Noritoshi Suzukie, Zihao Wanga, Yuchen Chib, Chunyang Zhanga, and Chengshan Wanga

Affiliations      

aState Key Laboratory of Biogeology and Environmental Geology, School of Earth Sciences and Resources, China University of Geosciences Beijing, Beijing 100083, China

bDepartment of Earth and Environmental Sciences, Ludwig Maximilians University, 80333 Munich, Germany

cKey Laboratory of Ocean and Marginal Sea Geology, South China; Sea Institute of Oceanology, Chinese Academy of Sciences, Guangzhou 510301, China

dState Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing 210008, China;

eDepartment of Earth Science, Graduate School of Science, Tohoku University, Sendai City 980-8578, Japan

 

 

About Professor Chengshan Wang

Chengshan Wang is a Professor at the School of Earth Sciences and Resources

at China University of Geosciences (Beijing). He is a member of the Chinese Academy of Sciences and the President of the Executive Committee of the Deep-time Digital Earth (DDE) Big Science Program. His research interests include the Cretaceous paleoenvironment and paleoclimate, tectonic uplift and sedimentary response, and analysis of petroliferous basins. With over 19,000 citations, he is a leader in the field of uplift of mountain ranges and has extensively studied the Tibetan Plateau and the Himalayan range. He has received The Li Siguang Geological Science Award and the National Award of Natural Sciences.

 

 

About Professor Jun Meng

Dr. Jun Meng is a professor at the School of Earth Sciences and Resources at the China University of Geosciences, Beijing, China. Prof. Meng’s research interests include paleomagnetism and tectonics. He has authored over 20 research papers in reputed scientific journals and has over 1,000 citations to his credit.

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JOURNAL

Proceedings of the National Academy of Sciences

DOI

10.1073/pnas.2305928120 

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Strengthening the argument for a large Greater India

 

A mathematical model for studying methane hydrate distribution in the Nankai Trough

Scientists develop a one-dimensional flow model for simulating methane hydrate generation and distribution processes in the Nankai Trough of Japan

Peer-Reviewed Publication

CHIBA UNIVERSITY

 

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METHANE HYDRATE HAS GARNERED CONSIDERABLE RESEARCH ATTENTION OWING TO ITS POTENTIAL AS AN ENERGY SOURCE. NOW, RESEARCHERS FROM JAPAN USE ONE-DIMENSIONAL MODEL-BASED NUMERICAL SIMULATIONS TO UNDERSTAND THE NATURE OF METHANE HYDRATION SATURATION AND GENERATION PROCESS UNDER DIFFERENT RESERVOIR AND FLUID CONDITIONS IN THE KUMANO FOREARC BASIN, NANKAI TROUGH, JAPAN.

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CREDIT: PEKA FROM WIKIMEDIA COMMONS HTTPS://COMMONS.WIKIMEDIA.ORG/W/INDEX.PHP?CURID=2867384

Methane hydrate is a naturally occurring ice-like crystalline solid that forms when methane and water are subjected to geological high-pressure and low-temperature conditions. It is often found trapped in continental margin sediments and permafrost. Owing to its immense potential as a possible energy resource, researchers have attempted to get a better understanding of the geochemical and geophysical factors that control the distribution of methane hydrate reservoirs. However, these deposits take thousands of years to form, and their reservoirs are often found in geologically heterogeneous conditions. This makes it difficult to conduct a real-time or thorough evaluation of the formation, distribution, or accumulation of methane hydrates.

In a new study published in Island Arc on September 19, 2023, Associate Professor Hitoshi Tomaru, along with Chao Xu from the Graduate School of Science and Engineering, Chiba University, have now developed a mathematical model to circumvent this problem. They investigated the distribution characteristics and accumulation mechanisms of methane hydrates in the Nankai Trough of Japan indirectly with the help of numerical simulations using a one-dimensional flow model.

The researchers carried out numerical simulations of the hydrate generation process by modifying the mathematical model proposed by Liu and Fleming in 2007 to investigate methane hydrate saturation (Sh). They used logging and geochemical data from the Kumano Forearc Basin of the Nankai Trough, which is located off the shore of the main island of Japan and is home to considerable hydrate reserves.

“With this model, we aimed to obtain insights into the distribution regularity of methane hydrate and the factors controlling hydrate generation. So, building on the original model, we explored the effects of deep fluid supply and reservoir lithology on the distribution and quantity of methane hydrates. We employed a smoother flux configuration to better observe the impact of methane flux variation on the simulation results,” explains Dr. Tomaru.

Considering the importance of methane flux and water flow for the formation and distribution of methane hydrates, the researchers investigated three distinct scenarios corresponding to low-, moderate-, and high-methane flux. They observed that the hydrate distribution in the Nankai Trough area coincided with the results when the methane flux was relatively small.

Prior studies have shown that in low-methane flux environments, Sh is highest near the base of the gas hydrate stability zone. In contrast, the formation of hydrates is significantly faster, and Sh is highest at the sea floor in high-methane flux regions. In other words, low-methane flux reduces Sh upward from the bottom, and high-methane flux increases it downward. The simulation results obtained in this study add to these observations and suggest that geological factors such as the distribution of fractures and a deep fissure in a rock formation also influence the sediment stress conditions and constrain the flow regime.

Furthermore, the team used typical permeability values of sand and mud to run simulations and understand the impact of permeability changes caused by lithological units on hydrate distribution. The results further revealed that Sh substantially increased in the sand layer but drastically decreased in the mud layer.

Elaborating on these results, Dr. Tomaru says, “Our simulation model provides valuable insights into the location, saturation, and distribution of natural methane hydrate resources in deep-sea sediments without the need for energy- and labor-intensive processes like physical drilling or coring of the sea floor.”

Going ahead, these findings can enable the development of more efficient strategies for methane hydrate generation and contribute to the development of better geohazard prevention plans.

 

About Associate Professor Hitoshi Tomaru
Hitoshi Tomaru is an Associate Professor at the Department of Earth Sciences of the Graduate School of Science and Engineering at Chiba University, Japan. He received his Doctor of Science degree from the University of Tokyo in 2004 and joined the University of Rochester as a postdoctoral fellow. He was a Japan Society for the Promotion of Science (JSPS) postdoctoral fellow at the University of Tokyo and Kitami Institute of Technology. His research interests include geochemistry, energy resources, and iodine isotopes. His team currently works on the geophysics of methane hydrates and the development of 129I geochronology for material transport via fluid in the shallow geosphere.

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JOURNAL

Island Arc

DOI

10.1111/iar.12502 

METHOD OF RESEARCH

Computational simulation/modeling

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Simulation of methane hydrate formation in coarse- to fine-grained sediments in the Nankai Trough, Japan