Tag Archives: crystals

Scientists Uncover 1.4 Billion-Year-Old Salt Crystals with Ancient Bubbles

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In a groundbreaking study, researchers uncovered ancient gases and fluids trapped within 1.4 billion-year-old rock salt crystals in northern Ontario, Canada. Their analysis reveals that oxygen and carbon dioxide concentrations during the Mesoproterozoic Era (1.8 billion to 800 million years ago) were suppressed to just 3.7% of current levels, while carbon dioxide was found to be ten times pre-industrial levels. These findings indicate a period of climatic stability, suggesting atmospheric oxygen levels temporarily exceeded the needs of early animals long before their emergence.

Examples of primary halite, mixed halite, and secondary halite rock inclusion aggregates. Image credit: Park et al., doi: 10.1073/pnas.2513030122.

Scientists have long recognized that liquid inclusions within rock salt crystals preserve samples of Earth’s primordial atmosphere.

However, accurately measuring these inclusions has presented significant challenges. These inclusions encompass both air bubbles and saline water, with gases like oxygen and carbon dioxide interacting differently in liquids compared to air.

“It’s astonishing to crack open a sample of air that is over a billion years older than the dinosaurs,” said Justin Park, a graduate student at Rensselaer Polytechnic Institute.

“Our carbon dioxide measurements are unprecedented,” stated Morgan Schaller, a professor at Rensselaer Polytechnic Institute.

“For the first time, we can trace this era of Earth’s history with remarkable precision. These are authentic samples of ancient air.”

Measurements indicate that Mesoproterozoic atmospheric oxygen levels sat at 3.7%, mirroring today’s levels. This high oxygen concentration was sufficient to support the existence of complex multicellular life, which would not arise for hundreds of millions of years.

Conversely, carbon dioxide was found to be ten times more abundant than present levels, effectively counterbalancing the “weak young sun” and fostering the climate conditions seen today.

One pivotal question arises: if oxygen levels were adequate for animal life, why did evolution take so long?

“This sample represents a snapshot in geological time,” Park explained.

“It may reflect a brief oxygenation event during this lengthy period, humorously dubbed the ‘billion boring years.'”

“This era in Earth’s history was marked by low oxygen levels, geological stability, and minimal evolutionary change.”

“Despite its moniker, direct observational data from this time is crucial for understanding the emergence of complex life and the evolution of our atmosphere.”

Prior indirect estimates suggested low carbon dioxide levels for this epoch, contradicting evidence of a lack of significant glaciation during the Mesoproterozoic.

The team’s direct measurements of elevated carbon dioxide, alongside temperature estimates from the salt, imply that Mesoproterozoic climate conditions were milder and more akin to today’s climate than previously assumed.

“Algae began to flourish during this period, continuing to play a vital role in global oxygen production today,” Professor Schaller remarked.

“The relatively elevated oxygen levels may directly result from the increasing prevalence and complexity of algae.”

“The insights we gained could represent an exciting moment in what is otherwise regarded as a billion years of monotony.”

The team’s research paper has been published today in the Proceedings of the National Academy of Sciences.

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Justin G. Park et al.. 2025. Bringing the Boring Billion to Life: Direct constraints from 1.4 Ga fluid inclusions reveal a favorable climate and oxygen-rich atmosphere. PNAS 122 (52): e2513030122; doi: 10.1073/pnas.2513030122

Source: www.sci.news

New Research Uncovers Small Crystals in Interstellar Amorphous Ice

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Low-density amorphous ice is one of the most prevalent solid materials in the universe and plays a crucial role in deciphering numerous well-known anomalies of liquid water. Despite its significance and discovery nearly 90 years ago, its structure remains a topic of debate. In a recent study, researchers from the University of London and Cambridge found that prior computer simulations of low-density amorphous ice were influenced by a disturbed structure where the ice was not entirely amorphous. Instead, it contained small crystals measuring 3 nm in width, slightly wider than a single DNA strand. In their experimental studies, actual samples of amorphous ice, which formed through different methods, were recrystallized (i.e., warmed up). They observed that the resulting crystal structure varied based on the method used to generate the amorphous ice. The researchers concluded that if the ice was completely disordered, it would not retain any imprint of its previous shape.

Low-density amorphous ice structure: Many small crystals (white) are hidden in the amorphous material (blue). Image credits: Michael B. Davis, UCL & Cambridge University.

“We now have a solid understanding of what the most common ice structures in the universe look like at the atomic level,” states Dr. Michael Davis, a researcher at the University of London and Cambridge.

“This is significant because ice is involved in numerous cosmological processes, including planet formation, galaxy evolution, and the movement of matter throughout the universe.”

For their investigation, Dr. Davis and his colleagues utilized two computer models of water.

They simulated the freezing of water molecules in these virtual “cages” by cooling to -120 degrees Celsius (-184 degrees Fahrenheit) at various rates.

These different cooling rates affected the proportions of crystalline and amorphous ice produced.

The researchers determined that low-density amorphous ice, as evidenced by X-ray diffraction studies, appears to align with a mixture of up to 20% crystallinity and 80% amorphous structure (i.e., researchers fired X-rays at ice and analyzed the deflection patterns).

Using an alternative method, they created a large “box” filled with numerous small ice crystals tightly packed together.

The simulation then disordered the regions between the ice crystals, resulting in structures remarkably similar to those obtained from the initial approach of 25% crystalline ice.

In additional experimental efforts, scientists generated actual low-density amorphous ice samples through various methods, including deposits of water vapor onto extremely cold surfaces (mimicking how ice forms on interstellar dust) and from high-density amorphous ice (ice crushed at very low temperatures).

These amorphous ice samples were then gently heated to provide energy for the formation of crystals.

They noted variations in the structure of the ice depending on its origin, particularly regarding the arrangement of molecules in a hexagonal (6x) formation.

This provided indirect evidence that low-density amorphous ice contained crystalline constituents.

Should it be entirely disordered, the ice would lack any memory of its prior form.

The findings raised further inquiries about the nature of amorphous ice, such as whether crystal size varies based on the formation method, and whether truly amorphous ice is achievable.

“Water is essential to life, yet our understanding is still incomplete,” remarked Professor Michael Ryde from Cambridge University.

“Amorphous ice may be key to explaining many anomalies observed in water.”

“Ice holds potential as a high-performance material in space,” added Dr. Davis.

“It can shield spacecraft from radiation and supply fuel in the form of hydrogen and oxygen.”

“Understanding the various structures and properties is critical.”

Moreover, this research touches upon a speculative theory regarding the origins of life on Earth.

This theory posits that life’s building blocks were transported here on an icy comet, known as Panspermia.

“Our findings indicate that this ice might be a suboptimal transport medium for these biological molecules,” stated Dr. Davis.

“This is due to the reduced space available for partial embedding of these components in the crystal structure.”

“Nonetheless, the theory could still hold merit, as there are amorphous regions within the ice capable of storing and concealing life’s building blocks.”

“Ice on Earth captivates our curiosity due to our warm climate,” observed University College professor Christophe Salzmann from the University of London.

“You can see the intricate order of snowflakes in their symmetry.”

“Ice elsewhere in the universe has long been viewed as a frozen snapshot of liquid water: a disordered arrangement that is fixed in place. Our findings suggest that this perception is not entirely accurate.”

“Our results also prompt questions regarding the properties of amorphous materials in general.”

“Such materials are vital in advanced technologies.”

“For instance, fiberglass used for data transmission must be amorphous or disordered to function.”

“If these materials contain small crystals, their performance can potentially be enhanced by removing them.”

The findings were documented in a paper published today in the journal Physical Review B.

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Michael Benedict Davis et al. 2025. Low-density amorphous ice contains crystalline ice grains. Phys. Rev. B 112, 024203; doi:10.1103/PhysRevB.112.024203

Source: www.sci.news

Scientists Uncover New Varieties of Crystals

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While researching crystal formation, scientists at New York University discovered a unique rod-shaped crystal previously unrecognized.

Zangenite. Image credit: Shihao Zang/Nyu.

Crystals are solid substances composed of particles arranged in repeating patterns.

This self-organization process—often described by researchers as “regulating order from chaos”—was traditionally believed to follow a predictable, classical growth model.

However, they are discovering that crystals can grow through more intricate pathways rather than simply forming building blocks step by step.

To investigate crystal formation, some researchers utilize crystals consisting of small spherical particles known as colloidal particles. These particles are significantly larger than the atoms in other types of crystals.

“Studying colloidal particles allows us to observe the crystallization process at the level of individual particles, which is challenging for atoms due to their small size and rapid movement,” explained Stefano Sacanna, a professor at New York University.

“With colloids, we can visually analyze the shape of the crystal under a microscope.”

To gain insight into how colloidal crystals form, Professor Sacanna and his team conducted experiments observing the behavior of charged colloidal particles under various growth conditions as they transitioned from a salty suspension into a fully developed crystal.

They also conducted thousands of computer simulations to model the growth of the crystals and to explain their experimental observations.

The researchers found that colloidal crystals form through a two-stage process: the initial amorphous mass of particles condenses, followed by a transformation into an ordered crystal structure, resulting in a diverse range of crystal types and shapes.

During the experiments, New York University PhD student Shihao Zan encountered a rod-shaped crystal that he could not identify.

While it appeared similar to a previously discovered crystal, detailed examinations revealed differences in the grain combinations and the presence of a hollow channel at the tips of the crystal.

He compared the unknown structures with over 1,000 crystals found in nature but found no match.

By utilizing computer modeling, the researchers were able to simulate the exact crystals, enabling them to study the elongated, hollow shapes more closely.

“This was somewhat perplexing, as crystals are typically dense; however, this one featured empty channels running throughout its length,” remarked Dr. Glenn Hocky from New York University.

“The combined effects of this experiment and simulation led me to realize that this crystal structure had never been documented before,” added Professor Sacanna.

They named the newly identified crystal l3s4 and informally referred to it as “Zangerite” during a lab meeting, reflecting its composition as per Zang’s discovery.

“We study colloidal crystals to replicate the real-world scenarios of atomic crystals, but we never anticipated discovering crystals that wouldn’t resemble those found in nature,” stated Zan.

The discovery of Zangenite holds potential for exploring applications related to hollow low-density crystals and may lead to the identification of more new crystals.

“The channels within Zangenite resemble characteristics found in other materials and may aid in filtering or enclosing internal contents,” Dr. Hocky noted.

“We once thought it was uncommon to find new crystal structures, but we may now be on the verge of discovering additional, yet uncharacterized, structures,” Professor Sacanna added.

A paper detailing this study was published in the journal Nature Communications.

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S. Zan et al. 2025. Direct observation and control of nonclassical crystallization pathways in binary colloid systems. Nat Commun 16, 3645; doi:10.1038/s41467-025-58959-0

Source: www.sci.news

Ancient Martian hydrothermal fluids leave a mark on meteorite crystals

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Mars meteorite called Black Beauty

Carl B. Agee (University of New Mexico)

Crystals within a Martian meteorite suggest Mars may have had abundant hydrothermal water when the rock formed 4.45 billion years ago.

The rock, called Black Beauty, was blown into space by an impact on Mars' surface and eventually crashed into the Sahara desert.

We already know a lot about Mars from the study of a meteorite discovered in Morocco in 2011, officially known as Northwest Africa 7034.

aaron cabosy Researchers at Curtin University in Perth, Australia, have been studying the tiny fragments, which contain zircon crystals 50 micrometers in diameter, for years.

Kavosie describes Black Beauty as “a rock that looks like a trash can.” Because it was formed by hundreds of pieces smashed together. “This is a great buffet of Martian history, with a mix of very old and very young rocks,” he says. “But much of the debris it contains belongs to some of the oldest rocks on Mars.”

The fragments studied by Kavosy and his team had crystallized in magma beneath Mars' surface. When they tested the zircons, they also found, unusually, that the elements iron, aluminum, and sodium were arranged in thin, onion-like layers.

“We wondered where else could we find elements like this in zircon crystals,” Kabosie says. The answer, he says, lies in South Australia's gold ore deposits. The zircon crystals there were nearly identical to those from Mars, including the same unusual combination of additional elements.

“This type of zircon is known to form only in places where hydrothermal processes or hydrothermal systems are active during igneous activity,” Kabosie says. “The hot water facilitates the transport of iron, aluminum, and sodium into the crystals as they grow layer by layer.”

Zircon has been exposed to multiple large-scale traumas, including the impact of an ancient collision and then another meteorite that hit the surface of Mars 5 to 10 million years ago and blasted Black Beauty into space have experienced. Despite these violent events, the rock's crystal structure is still intact at the atomic scale.

The lack of radiation damage means the extra elements were part of the crystal from the beginning, rather than being contaminated later, Kavosy said.

Eva Scherer Researchers at Stanford University in California believe that if this rock really formed in the presence of hydrothermal fluid and magma beneath the surface of Mars, water vapor entered the Martian atmosphere before rivers and lakes formed. This suggests that it may have been released.

“We're at a very old time, 4.5 billion years, when Mars was formed,” Scherrer said. “So this would be the earliest evidence of water behavior on Mars.”

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Source: www.newscientist.com

Enhancing Quantum Communication Devices with Liquid Crystals

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Quantum light is generated when a laser is shone on certain crystals

Jaka Waxwing

The liquid crystals found in television screens have made it easy to produce quantum light.

Light, with its quantum properties, is important for many future technologies: such entangled particles in light could help build quantum communication networks that support an unhackable internet, as well as quantum imaging techniques for biomedical applications. Matyas Humar Despite these advanced applications, the method for generating quantum light has remained largely unchanged for 60 years, says a researcher at the Jozef Stefan Institute in Slovenia. He and his colleagues have devised a way to generate quantum light using liquid crystals.

Team Members Vitaly Sultanov Researchers at the Max Planck Institute in Germany say that traditionally, researchers shine a laser on special crystals to make them emit quantum light. In this technique, the structure of the crystal determines the properties of the light it emits, which in turn determines how it can be used. The only way to change these properties is to redo the experiment with new crystals, which is costly, time-consuming and impractical.

To get around this, the researchers used liquid crystals, a material made of rod-shaped molecules that can wobble like a liquid but adopt unusual arrangements like more conventional crystals. By exposing the liquid crystal to an electric field, they can tune its structure, and thus the properties of the quanta of light it emits when illuminated with a laser.

“In this respect, liquid crystals are the perfect material,” says Sultanov.

After several experiments, his team found that liquid crystals were much easier to tune than solid liquid crystals, and nearly as efficient at producing light filled with entangled particles.

“While the generated photons could conceivably have been produced using conventional crystals, the tunability of the entanglement could not,” he said. Miles Padgett “These advances are [quantum] “Imaging, Communication, Sensing”

Maria ChekhovaResearchers, also from the Max Planck Institute, say that using liquid crystals in quantum communication devices could make it easier to send information over multiple channels at once, because the liquid crystals can be tuned to produce quantum states of light that can encode large amounts of information in many of their properties.

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Source: www.newscientist.com

Astronomers discover floating crystals preventing cooling in high-mass white dwarf stars

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Astronomers have proposed a new theory to explain why a mysterious population of white dwarfs has stopped cooling for at least 8 billion years.

This diagram shows a white dwarf and the moon. Image credit: Giuseppe Parisi.

White dwarfs are the remains of stars without a nuclear energy source that gradually cool over billions of years, eventually freezing from the inside out to a solid state.

Recently, it was discovered that a population of frozen white dwarfs maintains a constant brightness for a period comparable to the age of the universe, indicating the existence of an unknown, powerful energy source that inhibits cooling.

“We find that the classical picture that all white dwarfs are dead stars is incomplete,” said astronomer Dr Simon Bruin from the University of Victoria.

“To stop these white dwarfs from cooling, we need some way to generate additional energy.”

“We didn’t know how this happened, but now we have an explanation for this phenomenon.”

The researchers say that in some white dwarfs, the dense plasma inside them doesn’t just freeze from the inside out.

Instead, the solid crystals that form when frozen tend to float because they are less dense than the liquid.

As the crystals float upwards, the heavier liquid moves downwards.

As heavy material is transported toward the star’s center, gravitational energy is released, and this energy is enough to interrupt the star’s cooling process for billions of years.

Dr Antoine Bedard, an astronomer at the University of Warwick, said: “This is the first time this transport mechanism has been observed in any type of star, and it’s very interesting because it’s not every day that a completely new astrophysical phenomenon is discovered.”

“We don’t know why this happens in some stars and not others, but it’s probably due to the star’s composition.”

“Some white dwarfs are formed by the merger of two different stars,” Dr Bruin said.

“When these stars collide to form white dwarfs, the star’s composition changes, allowing the formation of floating crystals.”

White dwarfs are routinely used as an indicator of age, and the cooler a white dwarf is, the older it is considered to be.

However, the extra delay in cooling seen in some white dwarfs means that some stars at certain temperatures may be billions of years older than previously thought.

“This new discovery will not only require a revision of astronomy textbooks, but will also require a reexamination of the processes astronomers use to determine the age of stellar populations,” Dr. Blouin said.

of the team paper Published in today’s diary Nature.

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A. Bedard other. Buoyant crystals stop the white dwarf from cooling. Nature, published online March 6, 2024. doi: 10.1038/s41586-024-07102-y

Source: www.sci.news