Saturn's icy moon may host a stable ocean fit for life - Astronomy & Space - Astrobiology - Planetary Sciences - UNIVERSE

A new study has constrained the Enceladus's global conductive heat flow by studying its seasonal temperature variations at its north pole (yellow). These results, when combined with existing ones of its highly active south polar region (red) provide the first observational constraint of Enceladus's energy loss budget (<54 GW) – which is consistent with the predicted energy input (50 to 55 GW) from tidal heating. This implies that Enceladus's current activity is sustainable in the long term – an important prerequisite for the evolution of life, which is thought possible to exist in its global sub-surface ocean. Credit: University of Oxford / NASA / JPL-CalTech / Space Science Institute (PIA19656 and PIA11141)

A new study led by researchers from Oxford University, Southwest Research Institute and the Planetary Science Institute in Tucson, Arizona has provided the first evidence of significant heat flow at Enceladus's north pole, overturning previous assumptions that heat loss was confined to its active south pole.

This finding confirms that the icy moon is emitting far more heat than would be expected if it were simply a passive body, strengthening the case that it could support life.

The research is published in the journal Science Advances.

Enceladus is a highly active world, with a global, salty subsurface ocean, believed to be the source of its heat. The presence of liquid water, heat and the right chemicals (such as phosphorus and complex hydrocarbons) means that its subsurface ocean is believed to be one of the best places in our solar system for life to have evolved outside Earth.

But this subsurface ocean can only support life if it has a stable environment, with its energy losses and gains in balance. This balance is maintained by tidal heating: Saturn's gravity stretches and squeezes the moon as it orbits, generating heat inside. If Enceladus doesn't gain enough energy, its surface activity will slow down or stop, and the ocean could eventually freeze. Too much energy, on the other hand, could cause ocean activity to increase, altering its environment.

"Enceladus is a key target in the search for life outside Earth, and understanding the long-term availability of its energy is key to determining whether it can support life," said Dr. Georgina Miles (Southwest Research Institute and Visiting Scientist at the Department of Physics, University of Oxford), lead author of the paper.

Until now, direct measurements of heat loss from Enceladus had only been made at the south pole, where dramatic plumes of water ice and vapor erupt from deep fissures in the surface. In contrast, the north pole was thought to be geologically inactive.

Using data from NASA's Cassini spacecraft, the researchers compared observations of the north polar region in deep winter (2005) and summer (2015). These were used to measure how much energy Enceladus loses from its "warm" (0°C, 32°F) subsurface ocean as heat travels through its icy shell to the moon's frigid surface (–223°C, –370°F) and is then radiated into space.

By modeling the expected surface temperatures during the polar night and comparing them with infrared observations from the Cassini Composite InfraRed Spectrometer (CIRS), the team found that the surface at the north pole was around 7 K warmer than predicted. This discrepancy could only be explained by heat leaking out from the ocean below.

The measured heat flow (46 ± 4 milliwatts per square meter) may sound small, but this is about two-thirds of the heat loss (per unit area) through Earth's continental crust. Across the whole of Enceladus, this conductive heat loss totals around 35 gigawatts: roughly equivalent to the output of over 66 million solar panels (output of 530 W) or 10,500 wind turbines (output of 3.4 MW).

When combined with the previously estimated heat escaping from Enceladus's active south pole, the moon's total heat loss rises to 54 gigawatts, a figure that closely matches predicted heat input from tidal forces. This balance between heat production and loss strongly suggests that Enceladus's ocean can remain liquid over geological timescales, offering a stable environment where life could potentially emerge.

"Understanding how much heat Enceladus is losing on a global level is crucial to knowing whether it can support life," said Dr. Carly Howett (Department of Physics, University of Oxford and Planetary Science Institute in Tucson, Arizona), corresponding author of the paper. "It is really exciting that this new result supports Enceladus's long-term sustainability, a crucial component for life to develop."

According to the researchers, the next key step will be to determine whether Enceladus's ocean has existed long enough for life to develop. At the moment, its age is still uncertain.

The study also demonstrated that thermal data can be used to independently estimate ice shell thickness, an important metric for future missions planning to probe Enceladus's ocean, for instance using robotic landers or submersibles. The findings suggest that the ice is 20 and 23 km deep at the north pole with an average of 25 to 28 km globally—slightly deeper than previous estimates obtained using other remote sensing and modeling techniques.

"Eking out the subtle surface temperature variations caused by Enceladus's conductive heat flow from its daily and seasonal temperature changes was a challenge, and was only made possible by Cassini's extended missions," added Dr. Miles. "Our study highlights the need for long-term missions to ocean worlds that may harbor life, and the fact the data might not reveal all its secrets until decades after it has been obtained." 

Provided by University of Oxford 

by University of Oxford

edited by Stephanie Baum, reviewed by Robert Egan 

Source: Saturn's icy moon may host a stable ocean fit for life 

New gel restores dental enamel and could revolutionise tooth repair

Electron microscopy images of a tooth with demineralised enamel showing eroded apatite crystals (left) and a similar demineralised tooth after a 2-week treatment showing epitaxially regenerated enamel crystals (right).

A new material has been used to create a gel that can repair and regenerate tooth enamel, opening up new possibilities for effective and long-lasting preventive and restorative dental treatment.

Scientists from the University of Nottingham’s School of Pharmacy and Department of Chemical and Environmental Engineering, in collaboration with an international team of researchers, have developed a bioinspired material that has the potential to regenerate demineralized or eroded enamel, strengthen healthy enamel, and prevent future decay. The findings have been published today in Nature Communications.

The gel can be rapidly applied to teeth in the same way dentists currently apply standard fluoride treatments. However, this new protein-based gel is fluoride free and works by mimicking key features of the natural proteins that guide the growth of dental enamel in infancy. When applied, the gel creates a thin and robust layer that impregnates teeth, filling holes and cracks in them. It then functions as a scaffold that takes calcium and phosphate ions from saliva and promotes the controlled growth of new mineral in a process called epitaxial mineralization. This enables the new mineral to be organized and integrated to the underlying natural tissue while recovering both the structure and properties of natural healthy enamel.

The new material can also be applied on top of exposed dentine, growing an enamel-like layer on top of dentine, which has many benefits including treating hypersensitivity or enhancing the bonding of dental restorations.

Enamel degradation is a major contributor to tooth decay and is associated to dental problems affecting almost 50% of the world’s population. These problems can lead to infections and tooth loss, and can also be associated with conditions such as diabetes and cardiovascular disease. Enamel does not naturally regenerate; once you lose it is gone forever. There is currently no solution available that can effectively regrow enamel. Current treatments such as fluoride varnishes and remineralisation solutions only alleviate the symptoms of lost enamel.

Dr Abshar Hasan, a Postdoctoral Fellow and leading author of the study, said: “Dental enamel has a unique structure, which gives enamel its remarkable properties that protect our teeth throughout life against physical, chemical, and thermal insults. When our material is applied to demineralized or eroded enamel, or exposed dentine, the material promotes the growth of crystals in an integrated and organized manner, recovering the architecture of our natural healthy enamel."

“We have tested the mechanical properties of these regenerated tissues under conditions simulating ‘real-life situations’ such as tooth brushing, chewing, and exposure to acidic foods, and found that the regenerated enamel behaves just like healthy enamel.

Dr Abshar Hasan

“We are very excited because the technology has been designed with the clinician and patient in mind. It is safe, can be easily and rapidly applied, and it is scalable. Also, the technology is versatile, which opens the opportunity to be translated into multiple types of products to help patients of all ages suffering from a variety of dental problems associated with loss of enamel and exposed dentine. We have started this process with our start-up company Mintech-Bio and hope to have a first product out next year; this innovation could soon be helping patients worldwide.

Professor Alvaro Mata, Chair in Biomedical Engineering & Biomaterials

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More information is available from Professor Alvaro: See link below 

University of Nottingham

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