Saturday, July 18, 2026

SPACE/COSMOS

 

The Gravity from Entropy theory offers new clues for reconciling gravity with the second law of thermodynamics



Queen Mary University mathematician Professor Ginestra Bianconi explores how gravity can be reconciled with thermodynamics within the Gravity from Entropy theory



Queen Mary University of London

Professor Ginestra Bianconi 

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Professor Ginestra Bianconi from Queen Mary University of London

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Credit: Queen Mary University of London






A new study by Queen Mary University of London mathematician Professor Ginestra Bianconi proposes a new perspective on one of the deepest questions in modern physics: how can the Universe become increasingly structured and complex while still obeying the second law of thermodynamics? 

Einstein famously stated that “The second law of thermodynamics occupies a unique position among the laws of Nature,” reflecting his conviction that it is among the most fundamental principles of physics and unlikely to be overthrown. The second law states that the total entropy of an isolated system tends to increase over time, a principle often associated with the growth of disorder. 

This presents a long-standing puzzle in cosmology. The early Universe is generally believed to have existed in a low-entropy state and to evolve toward states of higher entropy. Yet over cosmic history, the Universe has also given rise to increasingly complex structures, including galaxies, stars, planets, and ultimately life itself. Reconciling the emergence of such ordered structures with the relentless increase of entropy remains an open challenge. 

In a recent paper published in Physical Review D, Professor Bianconi investigates this question within the framework of the Gravity from Entropy (GfE) theory, a quantum gravity approach that derives gravity from the microscopic degrees of freedom of spacetime geometry using principles of statistical mechanics.  

In this study, by exploring the thermodynamic properties of the Gravity from Entropy theory, she shows that while the total entropy of the Universe increases in time, the entropy per unit volume decreases in time, leaving open new interpretations for the emergence of local structures.  

The connection between gravity and thermodynamics has been known since the pioneering work of Jacob Bekenstein and Stephen Hawking in the 1970s, which established that black holes possess entropy and emit thermal radiation. These discoveries suggested a deep relationship between spacetime, information, and thermodynamics.  

Gravity from Entropy (GfE) proposes that gravity emerges from the information-theoretic tension between the true spacetime metric and the metric induced by matter fields and curvature. This new physical interpretation of gravity is reflected in the GfE Lagrangian, which is given by the Quantum Geometric Relative Entropy (QGRE) between these two metrics. The GfE gravity equations reduce to  General Relativity for low energies and small curvature, but beyond the weak limit, they deviate from it. Interestingly, beyond the weak limit, the GfE equations include the emergence of a dynamical dark energy term that could lead to testable predictions of the theory. 

This study explores the thermodynamic properties of the GfE theory in Friedmann–Robertson–Walker cosmological spacetimes. The results show that the local geometric degrees of freedom satisfy a first law of thermodynamics, in which the emergent dynamical dark-energy contribution can be interpreted as an internal energy, while the Quantum Geometric Relative Entropy (QGRE) can be identified as the local entropy per unit volume. Within this framework, effective temperature and pressure quantities also emerge naturally. Together, these findings suggest that the quantum state underlying the GfE theory may possess an intrinsic thermal nature. 

The study also highlights the fundamental role of the local volume element defined by the measure induced by the physical metric. As the Universe expands, this volume grows over time. Within the framework of the GfE theory, this expansion leads to an increase in the total entropy, while the local QGRE per unit volume decreases with time. This result reveals a distinctive thermodynamic behaviour of the GfE theory. 

Overall, this work proposes that gravity and spacetime may have an intrinsic thermodynamic and informational nature. This opens new possibilities for understanding the deep connections between gravity, quantum theory, and the emergence of complexity in the Universe. 

While still at an early theoretical stage, the authors say the work could help bridge long-standing gaps between general relativity, thermodynamics, quantum mechanics, and cosmology. Hence, “This work reveals how the Gravity from Entropy theory can tackle the challenging question to reconcile the second principle of thermodynamics with the emergence of complexity in our Universe. These results may open new avenues for investigating the long-standing problem of reconciling the foundations of cosmological irreversibility, the emergence of complex structures, and ultimately life, with fundamental gravitational dynamics” says Professor Bianconi.   

Lehigh University joins international consortium to advance commercial space research and innovation



Partnership with Ohio State University, Starlab, and global universities will develop future low-Earth orbit aerospace technology and microgravity science applications

Resolve Fall 2026: The Aerospace Issue 

Check out the Fall 2026 issue of Resolve magazine for more on Lehigh's heritage of innovation in aerospace and space systems.

Lehigh University
Lehigh's Master's in Aerospace and Space Systems 

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Lehigh's new Master's program in Aerospace and Space Systems Engineering is led by Lehigh alumnus Dr. Terry Hart, former fighter pilot, NASA astronaut, and satellite industry executive.

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Credit: Lehigh University




Seeking to expand the boundaries of microgravity science and accelerate the global space economy, Lehigh University has joined a newly formed international research consortium spearheaded by The Ohio State University.

The consortium, which recently hosted its inaugural meeting in Columbus, Ohio, unites an elite network of global academic and research institutions. The coalition is designed to spark collaborative research, facilitate faculty and student exchanges, and develop foundational technologies for future commercial low-Earth orbit (LEO) platforms, including the planned Starlab space station and its terrestrial counterpart, the VISTA science park.

Driving an institutional vision for space systems and science

Lehigh's entry into the consortium follows a formal framework agreement signed by Anand Jagota, Lehigh's vice provost for research, aligning the university with other premier research institutions across the globe. For Lehigh, the partnership serves as an accelerator for a broader, long-term commitment to space exploration and engineering innovation.

Central to this effort is a vision to position Lehigh students and researchers at the forefront of the aerospace sector, a priority highlighted by Nathan Urban, provost and senior vice president for academic affairs.

"This consortium reflects Lehigh's commitment to preparing students for careers at the leading edge of science and engineering," Urban says. "Space is no longer the domain of a handful of national agencies. It is quickly becoming a commercial sector with its own supply chains, infrastructure needs, and workforce demands. By joining this network, we're positioning Lehigh faculty and students to help define that future rather than simply react to it."

"Our engagement in this consortium is a direct extension of the strategic investments we've been making in aerospace and space systems engineering across the Rossin College," says Stephen DeWeerth, the Lew and Sherry Hay Dean of the P.C. Rossin College of Engineering and Applied Science. "From new faculty, to thriving student clubs, to our recently-launched interdisciplinary Master's in aerospace and space systems engineering, we've built the foundation. A partnership like this helps to turn that foundation into real opportunity for our students and researchers."

A growing space research ecosystem

Lehigh's role in the consortium anchors a rapidly growing aerospace and space-research footprint across campus, particularly within the Rossin College. Key initiatives driving this expansion include:

  • New faculty expertise: The Department of Mechanical Engineering and Mechanics (MEM) recently expanded its core research capabilities with the addition of new faculty member Yao Yao, whose work focuses on multifunctional deployable structures and the on-orbit assembly of large-scale space structures.
  • Specialized academic pathways: The university continues to develop advanced educational initiatives, including the Master of Science in Aerospace and Space Systems Engineering program, tailored to equip the next generation of engineers with the skills required by a rapidly evolving aerospace industry.
  • A legacy of industry connection: Lehigh's expanding space initiatives build upon a strong foundation of alumni and faculty leadership. This includes long-standing expertise on campus, such as former NASA astronaut and current mechanical engineering professor Terry Hart, as well as ties to industry leadership through distinguished alumni like Scott Willoughby '89, vice president of performance excellence for Northrop Grumman's Space Systems sector.

Supporting the transition to commercial LEO platforms

The launch of the consortium arrives during a broader transition in global space exploration. As public and private entities plan the transition from the International Space Station to commercial platforms, sustained progress depends heavily on structured university research and technical pipelines.

The consortium will focus directly on generating the scientific research and talent pipeline necessary to support platforms like Starlab, a continuously crewed, free-flying commercial space station, and VISTA (the George Washington Carver Science Park) based at Ohio State, a U.S. science park dedicated to in-space research, manufacturing, and services.

By contributing to a highly unified network across global academia and industry, Lehigh is helping build the collaborative research foundation and talent pipeline necessary to sustain long-term operations and scientific discovery in low-Earth orbit.

 

Chang’e-6 samples reveal how Earth slows solar wind striking Moon’s near side




Chinese Academy of Sciences Headquarters
Solar wind differences between the lunar nearside and farside under the influence of Earth's magnetosphere. 

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Schematic illustration of the contrasting solar wind environments experienced by the lunar nearside and farside under the influence of Earth's magnetosphere.

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Credit: Image by ZHANG Xuhang






The Moon has been bathed in solar wind for billions of years, but the two hemispheres are struck by solar wind of different speeds and energies.

Now, research based on China’s Chang’e-6 samples reveals that Earth’s magnetosphere has shaped this difference. The study was published in Nature Geoscience.

The solar wind, a continuous stream of high-speed charged particles from the Sun, bombards the Moon’s surface directly. The lunar regolith has preserved a record of this bombardment, serving as a natural archive of solar-wind-derived volatiles, including the noble gases (He, Ne, Ar, Kr, Xe). These chemically inert elements are highly reliable tracers of solar-wind implantation and provide valuable clues to this process.

Before this study, the lack of far-side samples prevented direct experiments on systematic differences in solar-wind implantation between the two hemispheres.

However, China’s Chang’e-6 mission returned 1.935 grams of regolith from the South Pole-Aitken basin on the lunar far side, offering the first opportunity to directly compare solar-wind implantation processes on the near side and far side.

Based on the lunar samples, a research team led by the Institute of Geology and Geophysics (IGG) of the Chinese Academy of Sciences (CAS) conducted a noble-gas isotopic investigation on the Chang’e-6 regolith and determined the concentrations and isotopic compositions of He, Ne, Ar, Kr, and Xe.

The work was carried out by ZHANG Xuhang, a postdoctoral researcher at IGG under the supervision of Professor HE Huaiyu, together with collaborators from the University of Science and Technology of China and the Chang’e-7 volatile payload team.

In the analysis, the researchers first noticed that the Ne isotopic composition of the Chang’e-6 regolith is highly distinctive. The average 20Ne/22Ne ratio is 11.34 ± 0.22, substantially lower than what is reported for all previously analyzed nearside lunar samples yet close to the theoretical isotope composition expected after strong solar-wind fractionation. This implies that the lunar far side underwent stronger isotopic fractionation, resulting in preferential enrichment of the heavier isotope.

As for Kr and Xe, their release behavior also differs from that of near-side samples. In the stepwise-heating experiments, solar-wind-derived Xe in the Chang’e-6 regolith was released predominantly at high temperatures, producing a single high-temperature release peak. In contrast, Chang’e-5 samples exhibited a distinct double-peaked release pattern, with significant Xe release at both low and high temperatures. This indicates that solar-wind ions penetrated significantly deeper into the far-side regolith than into the near side—meaning the far side was exposed to higher-energy particles.

But why do the Moon’s two hemispheres receive solar wind of different energies?

The research team attributes this difference to the “speed-governing” effect of Earth’s magnetosphere. As the Moon orbits Earth, it periodically passes through the magnetosheath—a buffer zone around the magnetosphere—where the ambient solar wind is slowed from its typical velocity of 400 km/s to about 200 km/s.

This slower solar wind primarily reaches the lunar near side, resulting in shallower implantation depths within the near-side regolith. In contrast, the far side, which permanently faces away from Earth, remains directly exposed to undisturbed solar wind, allowing ions to penetrate deeper into the regolith.

The researchers suggest that approximately 25% of the total solar-wind exposure at the Chang’e-5 landing site was influenced by this decelerated solar wind, whereas the Chang’e-6 landing site experienced no such shielding effect.

By providing the first direct empirical evidence from lunar far-side samples, this study confirms the speed-governing effect of Earth’s magnetosphere on solar-wind implantation into the lunar surface, an effect permanently preserved in both the implantation-depth distributions and isotopic signatures of noble gases within the regolith.

Furthermore, the researchers noted that heavy noble gases in lunar soils may serve as “fossil records” of past interactions between Earth’s magnetosphere and the solar wind, offering a novel approach for reconstructing the long-term evolution of Earth’s magnetosphere when combined with paleomagnetic records.

The findings also show that interactions within the Sun–Earth–Moon system are more complex than previously recognized. According to the researchers, these results open a new window into these ancient dynamics, revealing that Earth’s nearest celestial neighbor preserves previously unknown records of these interactions.


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