Edition 2026-05-21 · NewsPhysics

· Applied Physics · 21 · 05 · 2026

Direct Regulation of Plant H+-ATPase by Raf-like Kinases

Researchers have uncovered a fundamental molecular mechanism in plants involving the direct regulation of the plasma membrane H+-ATPase (PM H+-ATPase) by heterocomplexes of Raf-like kinases. This finding is significant because the PM H+-ATPase is a key proton pump that controls cytosolic pH, nutrient uptake, cell growth, and stress responses in plants.…

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§ Today’s briefing

5 dispatches · 21 · 05 · 2026

· General

NASA's AWE Completes Mission to Study Atmospheric Gravity Waves

NASA's Atmospheric Waves Experiment (AWE) instrument has concluded its data collection phase, exceeding its planned two-year mission.… more →

NASACol. 1

· Quantum Physics

Dublin emerges as a hub for quantum science and technology

Dublin is establishing itself as an emerging hub for quantum science and technology in Europe, with Trinity College Dublin (TCD) leading this development.… more →

Physics WorldCol. 2

· General

Ecotypes: A species' genetic memory for rapid adaptation

Evolutionary biologists are unraveling the genomic mechanisms that enable populations to adapt rapidly to local and diverse habitats without speciation occurring.… more →

Quanta MagazineCol. 3

· Astrophysics

Smile satellite launched to study solar wind-magnetosphere interaction

The European Space Agency (ESA) and the Chinese Academy of Sciences (CAS) have successfully launched the Smile (Solar wind Magnetosphere Ionosphere Link Explorer) satellite.… more →

ESACol. 4

· Applied Physics

Room-Temperature Memristive Switching in Charge Density Waves

Scientists have achieved reversible memristive switching between two charge density wave (CDW) states in a two-dimensional material, tantalum diselenide (1T-TaSe₂), at room tempera… more →

NatureCol. 5

§ In depth

Complete evolution of spin glass unveiled: from order to chaos

Researchers have successfully mapped the complete evolution of a spin glass, a disordered magnetic system, from its ordered state to chaos. This breakthrough provides a deeper understanding of how complex systems transition between different phases, offering new insights into the nature of disorder and its underlying organizing principles. The research addresses a fundamental question in physics: how disorder emerges in a universe governed by seemingly ordered physical laws at the elementary particle level.

Spin glasses are magnetic materials characterized by frustrated interactions between their magnetic moments (spins), which prevents them from reaching a unique, ordered ground state. Instead, they exhibit a multitude of nearly degenerate energy states, which gives them unique properties and makes them ideal models for studying the behavior of complex systems with disorder. Understanding the phase transition in these systems is crucial for unraveling phenomena in areas as diverse as neuroscience, materials science, and computation.

“Researchers have successfully mapped the complete evolution of a spin glass, a disordered magnetic system, from its ordered state to chaos.”

§ Technical sheet

Source: Phys.org
Category: Applied Physics
Edition: Nº 1
Date: 2026-05-21
Reading: 1 min
Origin: Source ↗

§ arXiv briefing

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