Friday, December 20, 2024

 SPACE/ COSMOS

 

Supermassive black holes halt rapid construction in an ancient celestial city



The James Webb Space Telescope has captured a group of massive galaxies ending their growth due to supermassive black holes about 11 billion light years away



Waseda University

Role of supermassive black holes in stopping star formation of massive galaxies 

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Results from the James Webb Telescope near-infrared camera clearly show that massive galaxies with active galactic nucleus feedback from supermassive black holes have lower star formation.

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Credit: Rhythm Shimakawa from Waseda University




Understanding how galaxies form and complete their growth is an area of fundamental focus in astrophysics. The dense regions of the universe, like galaxy clusters, are dominated by giant elliptical galaxies—massive, ancient galaxies that consist of old stars. Although the mechanism by which these giant elliptical galaxies halt star formation remains debated, one theory predicts that supermassive black holes (SMBHs) could play a key role. Their intense energy can suppress the gas supply to galaxies, which may lead to the formation of the giant elliptical galaxies seen today.

Against this backdrop, an international team of researchers investigated massive galaxies in an ancient galaxy cluster known as the Spiderweb protocluster, located 11 billion light years away (Fig. 1), using data from the James Webb Space Telescope (JWST). The research was led by Associate Professor Rhythm Shimakawa from Waseda University, Japan; Dr. Yusei Koyama from the National Astronomical Observatory of Japan; Prof. Tadayuki Kodama from Tohoku University, Japan; Dr. Helmut Dannerbauer and Dr. J. M. Perez-Martinez from the Instituto de Astrofísica de Canarias and Universidad de La Laguna, Spain; along with others who were a part of the team. Their findings were published in the Monthly Notices of the Royal Astronomical Society: Letters on December 18, 2024.

The team succeeded in obtaining high-resolution maps of the recombination lines of hydrogen, which indicate the activity of star formation and SMBHs, through the Near-Infrared Camera mounted on JWST. Detailed analysis showed that massive galaxies with active SMBHs exhibit no sign of star formation, meaning that their growth is severely hampered by SMBHs (Fig. 2). The results support the theoretical prediction that the formation of giant elliptical galaxies is linked with SMBH activity in the past.

“The Spiderweb protocluster has been studied by our team for more than 10 years using the Subaru Telescope and other facilities. With the new JWST data, we are now able to ‘answer the questions’ of understanding and predicting galaxy formation that we have accumulated,” remarks Dr. Shimakawa. He adds further, “This study marks a significant step forward in expanding our understanding of the co-evolution of SMBHs and galaxies in celestial cities.”

 

The Spiderweb protocluster, an ancient galaxy cluster 11 billion light years away 

Researchers break down the activities of star formation and SMBH occurring in galaxies

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Reference

DOI: https://doi.org/10.1093/mnrasl/slae098

 

Authors: Rhythm Shimakawa1,2, Yusei Koyama3,4,5, Tadayuki Kodama6, Helmut Dannerbauer7,8, J. M. Pérez-Martínez7,8, Huub J. A. Röttgering9, Ichi Tanaka4, Chiara D’Eugenio7,8, Abdurrahman Naufal5, Kazuki Daikuhara6, and Yuheng Zhang7,8,10,11

 

Affiliations:

1Waseda Institute for Advanced Study (WIAS), Waseda University, Japan

2Center for Data Science, Waseda University, Japan

3National Astronomical Observatory of Japan (NAOJ), National Institutes of Natural Sciences, Japan

4Subaru Telescope, National Astronomical Observatory of Japan, National Institutes of Natural Sciences, Japan

5Department of Astronomical Science, The Graduate University for Advanced Studies, Japan

6Astronomical Institute, Tohoku University, Japan

7Instituto de Astrofísica de Canarias, Spain

8Universidad de La Laguna, Dpto. Astrofísica, Spain

9Leiden Observatory, Leiden University, the Netherlands

10Purple Mountain Observatory, Chinese Academy of Sciences, China

11School of Astronomy and Space Science, University of Science and Technology of China, China

 

About Waseda University
Located in the heart of Tokyo, Waseda University is a leading private research university that has long been dedicated to academic excellence, innovative research, and civic engagement at both the local and global levels since 1882. The University has produced many changemakers in its history, including nine prime ministers and many leaders in business, science and technology, literature, sports, and film. Waseda has strong collaborations with overseas research institutions and is committed to advancing cutting-edge research and developing leaders who can contribute to the resolution of complex, global social issues. The University has set a target of achieving a zero-carbon campus by 2032, in line with the Sustainable Development Goals (SDGs) adopted by the United Nations in 2015. 

To learn more about Waseda University, visit https://www.waseda.jp/top/en

 

About Associate Professor Rhythm Shimakawa
Rhythm Shimakawa is currently an Associate Professor at the Waseda Institute for Advanced Study (WIAS) and Center for Data Science at Waseda University. He obtained his Ph.D. from Osaka University in 2012. Before joining Waseda University, he was a NAOJ fellow of the National Astronomical Observatory of Japan (NAOJ). He has published over 100 articles that have received over 1,800 citations. His research interests include galaxy formation and evolution, data astronomy, and galaxy–black hole co-evolution, among others.

Chang’e-6 farside basalts reveal a reinforced lunar dynamo





Chinese Academy of Sciences Headquarters

The ancient strength of the lunar magnetic field 

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The ancient strength of the lunar magnetic field recorded by the Chang'e-6 basalt clasts reveal the existence of a relatively active lunar dynamo at 2.8 Ga.

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Credit: Image by ZHANG Min, QI Kaixian, and SHI Pingyuan




The evolution of the lunar dynamo is crucial for understanding the Moon’s deep interior structure, thermal history, and surface environment. A recent study by Chinese scientists conducted paleomagnetic analyses on basalts returned by the Chang’e-6 mission and revealed a significant reinforcement of the lunar dynamo approximately 2.8 billion years ago (Ga).

This groundbreaking work was published in Nature.

Previous paleomagnetic studies of nearside lunar samples have established a general timeline for the evolution of the Moon’s magnetic field. However, limited spatial and temporal constraints have left the evolutionary trajectory of the lunar dynamo unclear.

The Chang'e-6 mission, which returned the first farside basalt samples dated to approximately 2.8 Ga, provides a unique opportunity to fill this critical gap in our understanding of the lunar dynamo’s spatiotemporal evolution.

Led by Prof. ZHU Rixiang at the Institute of Geology and Geophysics of the Chinese Academy of Sciences (CAS), Associate Professor CAI Shuhui and her colleagues measured the ancient magnetic field strength from the Chang'e-6 basalts, obtaining values ranging from approximately 5 to 21 microteslas (µT).

These findings revealed an unexpected resurgence in field strength at 2.8 Ga, following a sharp decline around 3.1 Ga. This challenges the prevailing hypothesis that the lunar dynamo entered a low-energy state after 3 Ga and remained in this condition until its cessation.

The researchers proposed that the lunar magnetic field during this period may have been driven by a basal magma ocean and/or powered by precessional forces. Additional mechanisms, such as core crystallization, may have also a role.

These findings suggest that the Moon’s deep interior remained hot and geologically active well into its mid-early history.

This study represents the first ever paleomagnetic data obtained from the Moon’s farside, providing critical insights into the intermediate stages of the lunar dynamo’s evolution. By synthesizing this data with existing findings, the researchers suggested significant fluctuations in the lunar magnetic field between 3.5 and 2.8 Ga, indicating a highly unstable dynamo during this period.

These results offer valuable guidance for future lunar exploration missions, including the search for potential magnetic reversals.

The research was conducted in collaboration with the National Astronomical Observatories, CAS. Lunar samples were supplied by the China National Space Administration, and the study was supported by the National Natural Science Foundation of China, the Strategic Priority Research Program (Category B) of CAS, and the Key Research Program of the Institute of Geology and Geophysics, CAS.

Study reveals origins of lunar water and its connection to earth's early history




Vrije Universiteit Brussel





The team analyzed water in nine samples from the Apollo lunar mission, using a high-precision triple oxygen isotope technique. This method, developed by Dr. Morgan Nunn Martinez of the University of California, San Diego, separates water into its various binding phases—loosely bound, tightly bound, and trapped within minerals—via stepwise heating at 50°C, 150°C, and 1,000°C. Their findings provide crucial evidence that lunar water has a dual heritage: one part originating from early Earth-like material and another delivered through cometary impacts.

"This is a major step forward in unraveling where lunar water comes from," Dr. Maxwell Thiemens of the AMGC research group of the VUB explained. "Our data suggest that the Moon inherited water tracing back to Earth's formation, followed by later contributions from comets, delivering the water reservoirs we see today."

Three key results are central to the report. An early Earth signature: The oxygen isotopic composition closely matches enstatite chondrites, a meteorite type believed to be the building blocks of the Earth. There are also clear signs of cometary contribution: A significant portion of lunar water shows isotopic similarities to comets. A reducedimportance of solar wind: the study challenges the prevalent theory that the majority of lunar water was produced in situ via solar interactions with lunar silicates, presenting instead a complex mixing of sources.

This discovery is timely as nations and private enterprises intensify their efforts to establish permanent lunar bases. Understanding the water’s origins and distribution could have significant implications for sustaining human presence on the Moon.

"The data not only enhance our understanding of the Moon’s past but also pave the way for future space exploration and resource utilization. These findings should redefine how we think about water as a resource for long-term lunar habitation." Thiemens concludes.

This research has the potential to shape lunar and planetary science for decades to come, offering a deeper connection between Earth's water-rich environment and the Moon’s arid surface. With Artemis missions on the horizon, this pioneering study provides a crucial foundation for future exploration and resource planning.

 

Reference:

M.M. Thiemens, M.H.N. Martinez, M.H. Thiemens, Triple oxygen isotopes of lunar water unveil indigenous and cometary heritage, Proc. Natl. Acad. Sci. U.S.A. 121 (52) e2321069121, https://doi.org/10.1073/pnas.2321069121 (2024)

University of Houston scientists solving meteorological mysteries on mars



Groundbreaking new paper answers key climate questions



University of Houston

Comparison of Mars and Earth REB 

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Comparison of Mars and Earth REB

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Credit: Univ. of Houston Dept. of Physics




A groundbreaking achievement by scientists at the University of Houston is changing our understanding of climate and weather on Mars and providing critical insights into Earth’s atmospheric processes as well.

The study, led by Larry Guan, a graduate student in the Department of Physics at UH's College of Natural Sciences and Mathematics, under the guidance of his advisors, Professor Liming Li from the Department of Physics and Professor Xun Jiang from the Department of Earth and Atmospheric Sciences and several world-renowned planetary scientists, generated the first-ever meridional profile of Mars’ radiant energy budget, or REB, which represents the balance or imbalance between absorbed solar energy and emitted thermal energy across the latitudes. On a global scale, an energy surplus leads to global warming, while a deficit results in global cooling. Furthermore, the meridional profile of Mars’ REB fundamentally influences weather and climate patterns on the red planet.

The findings are in a new paper just published in AGU Advances and will be featured in AGU’s prestigious science magazine EOS.

“The work in establishing Mars’ first meridional radiant energy budget profile is noteworthy,” Guan said. “Understanding Earth’s large-scale climate and atmospheric circulation relies heavily on REB profiles, so having one for Mars allows critical climatological comparisons and lays the groundwork for Martian meteorology.”

The profile, based on long-term observations from orbiting spacecraft, offers a detailed comparison of Mars’ REB to that of Earth, uncovering striking differences in the way each planet receives and radiates energy. While Earth exhibits an energy surplus in the tropics and a deficit in the polar regions, Mars displays the opposite configuration.

“On Earth, the tropical energy surplus drives warming and upward atmospheric motion, while the polar energy deficit causes cooling and downward atmospheric motion,” Jiang explained. “These atmospheric motions significantly influence weather and climate on our home planet. However, on Mars, we observe a polar energy surplus and a tropical energy deficit.”

That surplus, Guan says, is especially pronounced in Mars’ southern hemisphere during spring, playing a critical role in driving the planet’s atmospheric circulation and triggering global dust storms, the most prominent feature of Martian weather. These massive storms, which can envelop the entire planet, significantly alter the distribution of energy, providing a dynamic element that affects Mars’ weather patterns and climate.

“The interaction between dust storms and the REB, as well as with polar ice dynamics, brings to light the complex feedback processes that likely shape Martian weather patterns and long-term climate stability,” Guan said.

Earth’s global-scale energy imbalance has been recently discovered, which significantly contributes to global warming at a magnitude comparable to that caused by increasing greenhouse gases. Mars presents a distinct environment due to its thinner atmosphere and lack of anthropogenic effects. The research team is now examining potential long-term energy imbalances on Mars and their implications for the planet’s climate evolution.

“The REB difference between the two planets is truly fascinating, so continued monitoring will deepen our understanding of Mars’ climate dynamics,” Li said. "This research not only deepens our knowledge of the red planet but also provides critical insights into planetary atmospheric processes.”

Also contributing to this major achievement were UH graduate students Ellen Creecy and Xinyue Wang, renowned planetary scientists Germán Martínez, Ph.D. (Houston’s Lunar and Planetary Institute), Anthony Toigo, Ph.D. (Johns Hopkins University) and Mark Richardson, Ph.D. (Aeolis Research), and Prof. Agustín Sánchez-Lavega (Universidad del País, Vasco, Spain) and Prof. Yeon Joo Lee (Institute for Basic Science, South Korea).

New evidence exists for hidden water reservoirs and rare magmas on ancient Mars



Rice University research findings have ‘significant implications for habitability’



Peer-Reviewed Publication

Rice University




A new study explores how variations in Mars’ crustal thickness during its ancient history may have influenced the planet’s magmatic evolution and hydrological systems. The research, published in Earth and Planetary Science Letterssuggests that the thick crust of Mars’ southern highlands formed billions of years ago generated granitic magmas and sustained vast underground aquifers, challenging long-held assumptions about the red planet’s geological and hydrological past.

The study, led by Rice University’s Cin-Ty Lee, demonstrates that the southern highlands’ thick crust — up to 80 kilometers in some areas — was hot enough during the Noachian and early Hesperian periods (3-4 billion years ago) to undergo partial melting in the lower crust. This process, driven by radioactive heating, could have produced significant amounts of silicic magmas such as granites and supported subsurface aquifers beneath a frozen surface layer.

“Our findings indicate that Mars’ crustal processes were far more dynamic than previously thought,” said Lee, the Harry Carothers Wiess Professor of Geology and professor of Earth, environmental and planetary sciences. “Not only could thick crust in the southern highlands have generated granitic magmas without plate tectonics, but it also created the thermal conditions for stable groundwater aquifers — reservoirs of liquid water — on a planet we’ve often considered dry and frozen.”

The research team — including Rice professors Rajdeep Dasgupta and Kirsten Siebach, postdoctoral research associate Duncan Keller, graduate students Jackson Borchardt and Julin Zhang and Patrick McGovern of the Lunar and Planetary Institute — employed advanced thermal modeling to reconstruct the thermal state of Mars’ crust during the Noachian and early Hesperian periods. By considering factors such as crustal thickness, radioactive heat generation and mantle heat flow, the researchers simulated how heat affected the potential for crustal melting and groundwater stability.

Their models revealed that regions with crustal thicknesses exceeding 50 kilometers would have experienced widespread partial melting, producing felsic magmas either directly through dehydration melting or indirectly via fractional crystallization of intermediate magmas. Moreover, due to the elevated heat flow, the southern highlands’ thick crust would have sustained significant groundwater aquifers extending several kilometers below the surface.

The study challenges the notion that granites are unique to Earth, demonstrating that Mars could also produce granitic magmas through radiogenic heating even without plate tectonics. These granites likely remain hidden beneath basaltic flows in the southern highlands, offering new insights into Martian geology. Additionally, the research highlights the possible formation of ancient groundwater systems in Mars’ southern highlands, where high surface heat flux reduced the extent of permafrost and created stable subsurface aquifers. These reservoirs of water might have been periodically accessed by volcanic activity or impacts, resulting in episodic flooding events on the planet’s surface.

The findings have significant implications for habitability as the presence of liquid water and the ability to generate granitic magmas, which often contain elements critical for life, suggest that Mars’ southern highlands may have been more hospitable for life in the past than previously thought.

“Granites aren’t just rocks; they’re geological archives that tell us about a planet’s thermal and chemical evolution,” said Dasgupta, the Maurice Ewing Professor of Earth, Environmental and Planetary Sciences. “On Earth, granites are tied to tectonics and water recycling. The fact that we see evidence for similar magmas on Mars through deep crustal remelting underscores the planet’s complexity and its potential for hosting life in the past.”

The study highlights regions on Mars where future missions could focus on detecting granitic rocks or exploring ancient water reservoirs. Large craters and fractures in the southern highlands, for example, may provide glimpses into the planet’s deep crust.

“Every insight into Mars’ crustal processes brings us closer to answering some of the most profound questions in planetary science, including how Mars evolved and how it may have supported life,” Siebach said. “Our research provides a roadmap for where to look and what to look for as we search for these answers.”

This research was made possible by NASA grant 80NSSC18K0828 .

Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news re

Looking up the sky: UFOs and economic attention






The Hebrew University of Jerusalem


New study introduces an innovative measure of public attention based on reports of Unidentified Aerial Phenomena (UAP), demonstrating a surprising link between these sightings and economic conditions at multiple levels across the United States. This unconventional approach shows that UAP sightings, correlated with traditional attention metrics, offer a unique lens to analyze public focus, which fluctuates with economic cycles. The findings are significant because they reveal a new way to study macroeconomic behavior and inform policy, particularly in managing regional economic responses and addressing variations in public attention during periods of economic uncertainty.

A new study by Dr. Ohad Raveh from Hebrew University and Dr. Nathan Goldstein from Bar Ilan University, published in Humanities and Social Sciences Communications, unveils a novel approach to measuring public attention using reports of Unidentified Aerial Phenomena (UAP). The research bridges the gap between unconventional indicators and macroeconomic analysis, revealing surprising links between UAP sightings and economic conditions at multiple geographical levels in the United States.

The study highlights that UAP reports, often dismissed as a niche phenomenon, serve as a robust proxy for public attention. By analyzing daily-level data from NUFORC (National UFO Reporting Center), the researchers show that UAP sightings are more frequent in wealthier regions but exhibit counter-cyclical patterns within those regions over time. These findings suggest that shifts in attention to extraordinary phenomena may reflect broader fluctuations in public focus.

Key Findings:

Macroeconomic Correlation: UAP sightings are positively correlated with economic conditions across regions but display counter-cyclical patterns within regions over time.

Causal Evidence: A quasi-experimental design leveraging variations in COVID-19 lockdown restrictions demonstrates a causal link between restricted mobility and increased UAP reports, further establishing the measure as an indicator of public attention.

Policy Implications: Regions with higher UAP sighting levels show muted responses to monetary policy shocks, suggesting that attention variations can significantly influence economic outcomes.
The researchers compared UAP sightings to conventional attention metrics, finding strong correlations. This innovative measure offers unique advantages, including the ability to analyze attention at different geographical and temporal scales.

Implications for Policy and Research:
Goldstein and Raveh’s findings underscore the central role of public attention in economic dynamics. Their work not only enhances the toolkit for macroeconomic analysis but also provides policymakers with insights into managing public attention to mitigate economic shocks.
The study invites further exploration into how unconventional forms of attention, like UAP sightings, intersect with economic behaviors. “We hope this work inspires future research to deepen our understanding of the connection between public attention and macroeconomic outcomes,” the authors state.

About the Study: The research uses comprehensive UAP sighting data from NUFORC, spanning over two decades, to construct a daily-level panel of reports across U.S. counties. The analysis integrates economic, social, and environmental factors to ensure robust conclusions.

This pioneering work highlights the value of thinking beyond traditional metrics, shedding light on the role of seemingly unrelated phenomena in understanding economic patterns.