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Comment by Dr. Krishna Kumari Challa on December 18, 2020 at 12:08pm

Why are our tears salty?

Well, all fluids in our bodies have a little bit of salt in them. This salt is made into electricity to help our muscles contract and our brains to think. The amount of salt in our body fluids (like tears, sweat, and saliva) is about the same as the amount of salt in our blood — just under 1%, or about two teaspoons of salt per litre.

The saltiness of your tears can actually vary depending on what kind of tears your eyes are making.

That’s right, your eyes — or a part of your eyes called the lacrimal gland, to be precise — make three different types of tears. These are called basal tears, reflex tears and emotional tears.

• basal tears keep your eyes wet and stop nasty germs infecting your eyes
• reflex tears are made when your eyes need to wash away something harmful that gets in, such as smoke or a grain of sand
• emotional tears are the kind you cry when you’re feeling very happy or sad.

Basal tears and reflex tears have more salt in them than emotional tears, which is important for keeping your eyes healthy. Emotional tears contain more of other things, including a hormone (a special type of chemical in your body) that works like a natural painkiller. This might help to explain why we sometimes feel better after having a good cry.

https://theconversation.com/curious-kids-why-are-our-tears-salty-15...

Comment by Dr. Krishna Kumari Challa on December 18, 2020 at 11:50am

Being Scientists Doesn’t Make Us Science Communicators

Effectively relating science to the public is a science in itself, and expertise on a topic doesn’t guarantee expertise in explaining it.

https://www.the-scientist.com/news-opinion/opinion-being-scientists...

Comment by Dr. Krishna Kumari Challa on December 18, 2020 at 11:25am

Scientist tests new technology for removing, destroying 'forever ch...

University of Rhode Island hydrogeologist Thomas Boving and colleagues at EnChem Engineering Inc. are testing a proprietary new technology for quickly removing and destroying hazardous chemical compounds from soil and groundwater. If proven effective, the technology could soon be applied to cleaning up the abundant per- and polyfluoroalkyl substances, collectively referred to as PFAS and 'forever chemicals,' that contaminate drinking water supplies.

PFAS compounds have been in use for more than 60 years and are found in common household goods like non-stick cookware, stain-proof carpets and pizza boxes, as well as in firefighting foams and other industrial products. Because they do not break down easily in the environment, they find their way into human and animal tissues and can lead to many serious diseases.

First, they flushed the compounds out of the ground by pumping in a sugar molecule that has the ability to remove PFAS from the soil and groundwater. Then they pumped the solution out of the ground and hit it with a chemical oxidation process to destroy the compounds.

https://phys.org/news/2020-12-scientist-technology-chemicals.html?u...

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Comment by Dr. Krishna Kumari Challa on December 18, 2020 at 9:36am

The most consumed species of mussels contain microplastics all arou...

"If you eat mussels, you eat microplastics." 

A research team investigated the microplastic load of four mussel species which are particularly often sold as food in supermarkets from twelve countries around the world. The scientists now present their research results in the journal Environmental Pollution.

All the samples analyzed contained microplastic particles, and the researchers detected a total of nine different types of plastic. Polypropylene (PP) and polyethylene terephthalate (PET) were the most common types of plastic. Both are plastics ubiquitous to people's everyday lives all over the world. To make the analyses of different sized mussels comparable, one gram of mussel meat was used as a fixed reference. According to the study, one gram of mussel meat contained between 0.13 and 2.45 microplastic particles. Mussel samples from the North Atlantic and South Pacific were the most contaminated. Because mussels filter out microplastic particles from the water in addition to food particles, a microplastic investigation of the mussels allows indirect conclusions to be drawn about pollution in their respective areas of origin.

The microplastic particles detected in the mussels were of a size of between three and 5,000 micrometers, i.e. between 0.003 and five millimeters.

B.N. Vinay Kumar et al. Analysis of microplastics of a broad size range in commercially important mussels by combining FTIR and Raman spectroscopy approaches, Environmental Pollution (2020). DOI: 10.1016/j.envpol.2020.116147

https://phys.org/news/2020-12-consumed-species-mussels-microplastic...

Comment by Dr. Krishna Kumari Challa on December 18, 2020 at 9:31am

Popular European football games linked to traffic accidents in Asia

Days when high profile European football matches are played are associated with more traffic accidents in Asia than days when less popular matches are played, finds a study in the Christmas issue of The BMJ.

One explanation may be that Asian drivers stay awake until the early hours of the morning to watch high profile football games and lose sleep as a result.

Football is viewed by more people worldwide than any other sport, but most high profile games are played in Europe, so fans who live outside Europe must watch these games at odd local times owing to differences in time zones.

Asian fans are the most affected, as games scheduled to start at 8 pm in Europe means fans in Beijing, Hong Kong, and Singapore have to stay up until 4 30 am to finish the game, while fans in Seoul and Tokyo have to stay up until 5 30 am.

Given that sleep deprivation is associated with poor attention management, slower reaction times, and impaired decision making, one theory is that drivers are more likely to be involved in traffic accidents on days when high profile football games air early in the morning.

If true, this would have important policy implications, as traffic accidents can result in considerable economic and medical costs.

After taking account of potentially influential factors such as driver age, gender and experience, weather conditions, time of year, and weekend versus weekday effects, the researchers found that days when high profile football games were aired also had higher than average traffic accidents in both Singapore and Taiwan.

Association of high profile football matches in Europe with traffic accidents in Asia: archival study, BMJ (2020). DOI: 10.1136/bmj.m4465

https://medicalxpress.com/news/2020-12-popular-european-football-ga...

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Based on these figures, the researchers estimate that football games may be responsible for at least 371 accidents a year among taxi drivers in Singapore (this figure is likely to be much larger across all drivers in Singapore) and around 41,000 accidents per year among the Taiwanese general public.

In terms of annual economic losses, they estimate these to be more than €820,000 among Singapore taxi drivers and almost €14m among Taiwanese drivers and insurance companies, although they stress that these figures should be interpreted with caution.

This is an observational study, so can't establish cause, although the researchers were able to rule out many alternative explanations such as roadside conditions and driver characteristics. The researchers also point to some limitations, such as a lack of data on the severity of the accidents reported and being unable to compare match days against non-game days.

Nevertheless, they suggest that football's governing bodies could consider scheduling high profile games on Friday or Saturday evenings local European time (Saturday or Sunday early mornings local Asian time) when fans can sleep in immediately after watching games.

Comment by Dr. Krishna Kumari Challa on December 18, 2020 at 7:27am

Scientists set a path for field trials of gene drive organisms

The modern rise of gene drive research, accelerated by CRISPR-Cas9 gene editing technology, has led to transformational waves rippling across science.

Gene drive organisms (GDOs), developed with select traits that are genetically engineered to spread through a population, have the power to dramatically alter the way society develops solutions to a range of daunting health and environmental challenges, from controlling dengue fever and malaria to protecting crops against plant pests.

But before these gene drive organisms move from the laboratory to testing in the field, scientists are proposing a course for responsible testing of this powerful technology. These issues are addressed in a new Policy Forum article on biotechnology governance, "Core commitments for field trials of gene drive organisms," published Dec. 18, 2020 in Science by more than 40 researchers.

The new commitments that address field trials are to ensure that the trials are safely implemented, transparent, publicly accountable and scientifically, politically and socially robust.

A multidisciplinary group of gene drive organism developers, ecologists and con¬servation biologists joined experts in social science, ethics and policy to outline several commitments that they deem "critical for responsible conduct of a field trial and to ensure that these technologies, if they are introduced, serve the public interest." Twelve core commitments were developed under the following broad categories: fair partnership and transparency; product efficacy and safety; regulatory evaluation and risk/benefit assessment; and monitoring and mitigation.

K.C. Long el al., "Core commitments for field trials of gene drive," Science (2020). science.sciencemag.org/cgi/doi … 1126/science.abd1908

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 "gene drive" has been used both to describe a process (the biological activity of gene drive spreading in a population) and to describe an object (the development of a "gene drive" engineering tool).

https://phys.org/news/2020-12-scientists-path-field-trials-gene.htm...

Comment by Dr. Krishna Kumari Challa on December 17, 2020 at 10:00am

A pair of lonely planet-like objects born like stars

A pair of lonely planet-like objects born like stars

An international research team led by the University of Bern has discovered an exotic binary system composed of two young planet-like objects, orbiting around each other from a very large distance. Although these objects look like giant exoplanets, they formed in the same way as stars, proving that the mechanisms driving star formation can produce rogue worlds in unusual systems deprived of a Sun.

Star-forming processes sometimes create mysterious astronomical objects called brown dwarfs, which are smaller and colder than stars, and can have masses and temperatures down to those of exoplanets in the most extreme cases. Just like stars, brown dwarfs often wander alone through space, but can also be seen in binary systems, where two brown dwarfs orbit one another and travel together in the galaxy.

Clémence Fontanive et al. A wide planetary-mass companion to a young low-mass brown dwarf in Ophiuchus, arxiv.org/abs/2011.08871 accepted for publication in The Astrophysical Journal Letters, DOI: 10.3847/2041-8213/abcaf8

https://phys.org/news/2020-12-pair-lonely-planet-like-born-stars.ht...

Comment by Dr. Krishna Kumari Challa on December 17, 2020 at 9:32am

Where does the Earth's heat come from?

Earth generates heat. The deeper you go, the higher the temperature. At 25km down, temperatures rise as high as 750°C; at the core, it is said to be 4,000°C. Humans have been making use of hot springs as far back as antiquity, and today we use geothermal technology to heat our apartments. Volcanic eruptions, geysers and earthquakes are all signs of the Earth's internal powerhouse.

The average heat flow from the earth's surface is 87mW/m² – that is, 1/10,000th of the energy received from the sun, meaning the earth emits a total of 47 terawatts, the equivalent of several thousand nuclear power plants. The source of the earth's heat has long remained a mystery, but we now know that most of it is the result of radioactivity.

The birth of atoms

To understand where all this heat is coming from, we have to go back to the birth of the atomic elements.

The Big Bang produced matter in the form of protons, neutrons, electrons, and neutrinos. It took around 370,000 years for the first atoms to form—protons attracted electrons, producing hydrogen. Other, heavier nuclei, like deuterium and helium, formed at the same time, in a process called Big Bang nucleosynthesis.

The creation of heavy elements was far more arduous. First, stars were born and heavy nuclei formed via accretion in their fiery crucible. This process, called stellar nucleosynthesis, took billions of years. Then, when the stars died, these elements spread out across space to be captured in the form of planets.

The earth's composition is therefore highly complex. Luckily for us, and our existence, it includes all the natural elements, from the simplest atom, hydrogen, to heavy atoms such as uranium, and everything in between, carbon, iron—the entire periodic table. Inside the bowels of the earth is an entire panoply of elements, arranged within various onion-like layers.

We know little about the inside of our planet. The deepest mines reach down 10km at the most, while the earth has a radius of 6,500km. Scientific knowledge of deeper levels has been obtained through seismic measurements. Using this data, geologist divided the earth's structure into various strata, with the core at the center, solid on the inside and liquid on the outside, followed by the lower and upper mantles and, finally, the crust. The earth is made up of heavy, unstable elements and is therefore radioactive, meaning there is another way to find out about its depths and understand the source of its heat.

Radioactivity is a common and inescapable natural phenomenon. Everything on earth is radioactive—that is to say, everything spontaneously produces elementary aprticles (humans emit a few thousand per second).

There are various kinds of radioactivity, each involving the spontaneous release of particles and emitting energy that can be detected in the form of heat deposits. Here, we will be talking about "beta" decay, where an election and a neutrino are emitted. The electron is absorbed as soon as it is produced, but the neutrino has the surprising ability to penetrate a wide range of materials. The whole of the Earth is transparent to neutrinos, so detecting neutrinos generated by radioactive decay within the Earth should give us an idea of what is happening at its deepest levels.

These kinds of particles are called geonutrinos, and they provide an original way to investigate the depths of the Earth. Although detecting them is no easy matter, since neutrinos interact little with matter, some detectors are substantial enough to perform this kind of research.

https://theconversation.com/where-does-the-earths-heat-come-from-15...

Comment by Dr. Krishna Kumari Challa on December 17, 2020 at 8:30am

New type of atomic clock could help scientists detect dark matter and study gravity's effect on time

Atomic clocks are the most precise timekeepers in the world. These exquisite instruments use lasers to measure the vibrations of atoms, which oscillate at a constant frequency, like many microscopic pendulums swinging in sync. The best atomic clocks in the world keep time with such precision that, if they had been running since the beginning of the universe, they would only be off by about half a second today.

Still, they could be even more precise. If atomic clocks could more accurately measure atomic vibrations, they would be sensitive enough to detect phenomena such as dark matter and gravitational waves. With better atomic clocks, scientists could also start to answer some mind-bending questions, such as what effect gravity might have on the passage of time and whether time itself changes as the universe ages.

Now a new kind of atomic clock designed by MIT physicists may enable scientists explore such questions and possibly reveal new physics.

The researchers report in the journal Nature that they have built an atomic clock that measures not a cloud of randomly oscillating atoms, as state-of-the-art designs measure now, but instead atoms that have been quantumly entangled. The atoms are correlated in a way that is impossible according to the laws of classical physics, and that allows the scientists to measure the atoms' vibrations more accurately.

The new setup can achieve the same precision four times faster than clocks without entanglement.

Entanglement on an optical atomic-clock transition, Nature (2020). DOI: 10.1038/s41586-020-3006-1 , www.nature.com/articles/s41586-020-3006-1

https://phys.org/news/2020-12-atomic-clock-precisely.html?utm_sourc...

Comment by Dr. Krishna Kumari Challa on December 17, 2020 at 7:19am

Quantum insulators create multilane highways for electrons

New energy-efficient electronic devices may be possible thanks to research that demonstrates the quantum anomalous Hall (QAH) effect—where an electrical current does not lose energy as it flows along the edges of the material—over a broader range of conditions. A team of researchers from Penn State has experimentally realized the QAH effect in a multilayered insulator, essentially producing a multilane highway for the transport of electrons that could increase the speed and efficiency of information transfer without energy loss.

Tuning the Chern number in quantum anomalous Hall insulators, Nature (2020). DOI: 10.1038/s41586-020-3020-3 , www.nature.com/articles/s41586-020-3020-3

https://phys.org/news/2020-12-quantum-insulators-multilane-highways...

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