There’s a saying that goes “The speed of light is greater than the speed of sound, which is why some people appear bright before they open their mouths”. Whilst I’m sure that we can all remember someone who fits that description exactly not many people appreciate just how vast the difference is between the speed of light really is. Indeed in everyday life you can pretty much consider light to travel instantaneously since it could reach any point on earth in under a millisecond. That also means that visually observed phenomena can help us determine other things, like how far away the boat in the below video was from the volcano that erupted:
From the first point where you can see the eruption beginning to the time when the shockwave hits the camera approximately 13 seconds elapses. Taking into account that the speed of sound in air (roughly 341 m/s, although it could be slightly faster depending on the temperature) that gives us an approximate distance of 4.4 km from the eruption site. To put that in perspective the light that brought the picture traveled the same distance in about 0.01 milliseconds, an imperceptibly short amount of time. If you were so inclined you could also figure out all sorts of other kinds of information from this video (like the height of the plume, it’s velocity, etc.) but they’re an exercise I’ll leave up to the reader.
This video also showcases one of the coolest (in my opinion) visual phenomena related to massive explosions like this. You can see the shock wave propagating out from the epicenter very clearly, something which always happens but isn’t usually visible to the naked eye. Here you can see it travelling outwards thanks to it compressing the air in front of it which changes the refractive index of light. With explosions of this magnitude the amount of compression, and the resulting shock wave, are enough to produce a significant bend in the light passing through it.
I probably wouldn’t want to be that close to the explosion though!
How much do you know about where we are in the universe? I’d hazard a guess that nearly everyone can say that we’re the 3rd planet from our sun and that we reside in a large spiral galaxy called the Milky Way. You might not know though that we’re towards the end of one of the Milky Way’s tendrils and that we’re part of a larger group of galaxies called the Local Supercluster. However the definition of what constitutes the Local Supercluster had always been a little loose, essentially just a sphere of space in which all contained galaxies were defined as part of it. Scientists in Hawaii though, led by R. Brent Tully, have come up with a new way of defining superclusters and have dubbed our new home Laniakea.
It’s reminiscent of when the International Astronomical Union refined the definition of what constitutes a planet. Sure the new definition might mean that some previously neighbouring galaxies will get excluded, and new ones included, however rigorous definitions like these are what form the basis of good science. We might feel some kind of attachment to the ideas (I was honestly surprised by how many people were outraged by Pluto losing its planet status) however science abhors hand waving and sometimes we have to accept some loss in order to make further progress.
However I find the science behind Laniakea to be incredibly beautiful. Instead of our local group of galaxies being defined by some arbitrary points we’re now a group of celestial bodies all sharing the same journey. We might not ever see each other, nor ever cross paths, but the idea that we’re sharing the same galactic journey with billions and billions of other balls of matter is, to me, incredibly poetic.
The sun is an amazing celestial object. Even though it looks about the same size as our moon when viewed from Earth’s surface it’s almost 400 times further away which should give you an idea of just how unfathomably large the sun is. It also heavily influences nearly every aspect of our Earth, providing nearly all of the energy that we, and all other lifeforms on this planet, consume on a daily basis. You’d be forgiven for thinking that we understood it completely however as whilst nearly anyone would be able to tell you that the sun is powered by fusion we, funnily enough, didn’t actually have proof of this.
That is, until now.
It sounds silly right? The theory of the sun being a giant ball of fusion has been around for 75 years and is pretty much established as a scientific fact. Indeed many of the observations that we’ve made of the sun support that theory and the small scale replicas we’ve made also seem to exhibit similar properties. However the surface of the sun, as we see it, doesn’t really tell us the whole story. Indeed the light emitted from the surface of the sun is hundreds of thousands of years old, spending most of its life worming its way out of the deeper layers of the sun. Should we want to verify that for sure we need to observe the products of fusion reactions happening now and, bar venturing into the sun itself, there’s only one way to do that: by observing one of our universe;’s most elusive particles, the neutrinos.
Specifically the neutrinos are called PP neutrinos, those which arise from the fusion of two protons to form helium. A fusion reactor on the scale of the sun generates countless numbers of these particles every second and, thanks to their near massless nature, they rush out unimpeded directly from the sun’s core. However the same properties which allow them to move at such great velocity away from the sun also prevents them being easily detected. Combine this with the fact that PP neutrinos carry less energy than regular neutrinos do you can see why definitive proof of fusion happening within the sun as eluded us for so long. Researchers in Italy though crafted an experiment to capture these ever elusive particles and their research has finally bore fruit.
The Borexino experiment uses a large device called a scintillator, essentially a large array of light detecting devices immersed in ultrapure water. It’s then buried deep underground (about 1.4KM) in order to shield it from cosmic rays and other stray radiation. This experiment was specifically designed to verify the solar output of neutrinos against the standard solar model in order to verify that fusion was indeed occurring within our sun. It began collecting data about 7 years ago and at the beginning of this year they had enough data to submit their final report. The results line up perfectly with what the standard solar model predicts which, for the first time, verifies that fusion is indeed occurring within our sun and has been for a very long time.
It may seem like a silly thing to do but verifying things like this is the key to ensuring that our understanding of the universe is in line with reality. We might have known that fusion was going on the sun for decades but without definitive proof we just had a good model that matched some of the observed behaviours. Now we know for sure and that means that our standard solar model is far more robust than it was previously. Thus, with this new information at hand, we can dive even deeper into the model, probing the various curiosities and figuring out just what makes our sun tick. We might not ever know everything about it but part of the fun of science is finding out what you don’t know and then trying to figure it out.
The Sailing Stones of Death Valley have been a scientific curiosity for numerous decades. These rocks seemingly spring to life at various times throughout the year, blazing long trials across the desert’s floor before coming back down to rest. Whilst there have been numerous theories as to what causes this movement, ranging from the plausible to the downright insane, no one had managed to verify just what exactly was going on with these strange rocks. Well now thanks to researchers at the Scripps Institute of Oceanography we now have evidence of just what’s causing this to happen and it’s pretty fascinating.
The video largely supports the theory put forth by Ralph Lorenz some years ago whereby the the rocks are trapped within ice sheets which are then moved by the prevailing winds. What’s interesting about this video is that it shows why the previous experiments, which were largely inconclusive as to ice sheets being responsible, produced the data that they did. It also shows why there seems to be similarities between some movements whilst others seem to be completely random. Pretty much all of these can now be explained by the ice sheets breaking up and bumping off each other, leading to the wide variety of patterns and behaviours.
Like the video says this might not be the most exciting experiment to conduct however it’s always interesting when a long standing phenomena like this finally gets explained. We might not be able to use this knowledge to further other research or develop some novel product, however as we begin to explore further out into our universe knowledge of strange things like this becomes incredibly valuable. When we see phenomena like this elsewhere we’ll be able to deduce that similar processes are in action over there and thus further our understanding of the places we explore.
The need for organs for transplants has always outstripped demand and this has pushed the science in some pretty amazing directions. Indeed one of the most incredible advances is the ability to strip away host tissue from organs, leaving behind an organ scaffold, that we can then regrow with the recipient’s own cells. This drastically reduces the chance of rejection and hopefully avoids the patient having to take the harsh anti-rejection drugs. However such a process still relies on a donor organ which still leaves us with the supply problem to deal with. Whilst we’ve made some advances in creating parts of organs (some even done with biomedical 3D printers) growing a full organ has still proven elusive.
That is until recently.
Researchers at the University of Edinburgh have, for the first time, managed to grow a full functioning organ within a mouse using only a single injection. The organ that they created was the thymus, an organ that plays a critical role in the production of T-cells. These cells are the ones that are responsible for hunting down cells in your body that are either showing abnormalities or signs of infection and then eradicating them. What’s so incredible about this recent achievement is that the functional thymus developed after the injection of modified cells, requiring none of the additional work that’s previously been associated with creating functional organs.
The process starts off with cells from a mouse embryo, which from what I can gather were likely to be embryonic stem cells, which were then genetically programmed to form into a type of cell that’s found in the thymus. These, along with supporting cells, were then injected into the mice and the resultant cells developed into a fully functioning thymus. Interestingly though this didn’t seem to be the outright goal of the program as the researchers themselves stated that the result was surprising. Indeed whilst it’s been theorized that stem cells could be used in this manner it was never thought to be as straight forward as this and with these results further research is definitely on the table.
Whilst this research is still many years away from being useful in human models it does pave the way for research into how far this typical method can be applied. The thymus is a relatively simple organ when compared to others in the body so the next steps will be to see if this same process can be used to replicate them. If say a liver or heart can be reproduced in this manner then this has the potential to completely solve the transplant organ supply issue, allowing patients (or a surrogate) to grow their own organs for transplants. There’s a lot of research to be done before that happens however but this latest advance is incredibly promising.
I was never a particularly fit or active child. It wasn’t for lack of encouragement from my parents, they had me try all sorts of different activities in the hopes I’d find something that I enjoyed, more it was that I just never felt as capable as other kids when it came to physical endeavours. This, of course, fed into my love of all things gaming and other sedentary activities. It wasn’t until over a decade ago that I started to take my health seriously, transforming myself from a chronically underweight individual (BMI 17) to the more athletic person that I am today. Mostly I did this for myself however I always had a view that I needed to do this for my future children and today brings word of new research that shows I was on the right track.
It’s common knowledge that your parent’s genetics play a major role in your development and health throughout your life. Indeed it’s to the point now where we can identify many genes that are precursors for many conditions and diseases, allowing us to engage in preventative treatment long before the condition manifests itself. It’s also well known that the mother’s health, as well as the conditions she exposes herself to during pregnancy, have long lasting effects on the child after birth. However many believe that beyond those two factors the health of the parents doesn’t really factor into the child’s long term health, I.E. that your health prior to conceiving doesn’t have much influence over the child’s long term wellbeing. The latest research out of our own University of Adelaide turns that assumption on its head showing that the parents’ health before conception plays a significant role in the child’s well being throughout their life.
Essentially it boils down to the accumulation of environmental factors in the egg and sperm of the parents which are then passed on to any progeny. The good news is for parents that are looking to conceive is that this mechanism works both ways and that improvements in your health before conception will then also lead to better outcomes for your child. Whilst the study says that the impacts can be seen even months before conception effecting real change in such a short time frame is highly unlikely and such changes should be undertaken much earlier. Unfortunately since I don’t have journal access anymore I can’t comment on just how effective such intervention is but the researchers comments don’t seem to indicate that it’s small.
For me this just reinforces the view that your health is far more important than a lot of people give it credit for. Whilst I always lament when people derive motivation from a wake up call like this I can’t deny that it’s an effective mechanism for most. Indeed it seems for many that their child’s health is a primary motivator for a lot of decisions, even if some of them are rather ill-informed. So if improving your own health could vastly improve your childs then I’m sure many parents would take the initiative and live better lives as a result. Hopefully that would then lead onto keeping those improved habits long after the children were born as whilst your genetic influence may have ceased you will still have huge impact on their habits, many of which they will carry with them for life.
We Australians are leaders in many things we shouldn’t be, like our climbing obesity rates or per-capita carbon emissions. As it is with a lot of things like this the causes are readily preventable and it is up to us to take action in order to ensure that we lose our world leader status in these less-than-desirable categories. However there is one issue that, even despite years of campaigning and education programs, we Australians just never seem to get: we are the most likely people in the world to get skin cancer. This is an almost entirely preventable condition, one that requires almost no effort to ensure that you’re highly unlikely to suffer from it.
The video below shows just how effective sunscreen is at doing it’s cancer preventing job, blocking harmful UV rays:
Now the shocking discovery of UV freckles that many of the people in this video saw isn’t necessarily a bad thing (those are simply concentrated spots of melanin, your skin’s natural defence mechanism) however the application of sunscreen, as well as the glasses appearing to be opaque, should drive home the message that sunscreen does indeed work as advertised. UVA and UVB are both completely blocked by your regular over the counter sunscreens, providing full protection against the damaging rays of the sun. Sunglasses are also a vital if you’re spending a lot of time outdoors as continued exposure can lead to things like cataracts.
I know I’m probably preaching to the choir here but honestly when our incident rate of melanoma and other skin cancers is this high I feel it bears repeating. We’re a nation of people who love our beaches, sports and the outdoors and there’s really no reason that we should subject ourselves to unnecessary risks like this. Really taking 5 minutes to lather yourself up before hitting the beach isn’t a big ask and it could save you years of pain down the line.
You don’t have to end up as a statistic.
Many moons ago, when I was still a poor uni student working multiple jobs to make ends meet, I remember one of my fellow childcare workers would rarely be seen outside without his sunglasses. It became something of a recurring joke as, even when it wasn’t particularly bright outside, he’d be sporting them. He later explained that he kept them on constantly because sunlight would make him sneeze and indeed upon taking them off he proceeded to prove his point. I had always thought that explanation was a most likely bunk however a couple years later I started to develop similar symptoms. Whilst the coincidence felt undeniable to me I had never really looked into it, until I saw this video:
Unfortunately whilst it’s a well established phenomena the lack of known cause is a little bit disappointing. I mean it’s not exactly a debilitating condition, all it takes is a half decent pair of sunglasses to negate any effect the sun might have in this regard, but still it seems like something that should have a simple explanation. Alas investigating why sunlight makes people sneeze probably isn’t the most sexy of research topics so I’m not holding my breath for any scientific breakthroughs.
All this talk of sneezing has made my nose itch, maybe I should pop outside to clear it out
Quantum Mechanics is…weird. Anyone who’s had a passing education in the world of physics will know of certain principles that hold true for pretty much everything but the second you dive into the quantum world all that knowledge and understanding won’t help you one bit. Even simple things like “2 objects can’t exist in the same place at the same time” aren’t true when you’re down at that level, destroying any sense of logicality you might have had when approaching the subject. Indeed there’s a quote famously attributed to Richard Feynman that “If you think you understand quantum mechanics, you don’t understand quantum mechanics”, although I’ve yet to find anyone say that they do understand it (I sure as heck don’t). Worse still even when you think you’ve got one principle figured out an experiment will come around and turn it on its head, like quantum entanglement recently was.
Quantum entanglement, in its simplest form (at least in my understanding) is the phenomena whereby two particles are linked together at the quantum level. Should you attempt to measure some attributes of one of the particles, say an electron’s spin, the other particle will instantaneously assume the same observed state regardless of the distance separating them. Whilst we don’t know the exact speed at which that state travels we do know it’s at least 10,000 times faster than the speed of light, something which would appear to violate the cosmic speed limit. However no information is actually transferred between the two particles, they simply assume the same state at the exact same time, and indeed any applications you might think of to use it to transfer information will, unfortunately, fail. Up until recently it was thought that such entangled particles needed to be close to, or create with, each other in order for entanglement to happen. However that’s not the case anymore as particles can be entangled even without knowing each other.
I think I actually ended up understanding less about quantum mechanics after finding this out.
The research, done at Chapman University, attempted to explore what’s called the Pigeonhole Principle in the realm of quantum mechanics. It’s a relatively simple mathematical concept to explain: say you have 3 pigeons and 2 pigeonholes, if you were to put all the pigeons into those holes at least one of them would contain 2 pigeons. Simple right? Well it is and simple proofs like this have a multitude of uses in mathematics, however when it’s applied to quantum mechanics some…strange things happen. Essentially the research team found out that you could put infinite pigeons into only 2 different holes and none of them would end up in the same hole. If that sounds confusing that’s because it is, but this has what lead the research team to demonstrate that particles, even those which had no idea their entangled partner existed, could in fact be entangled.
Like most discoveries in the area of quantum mechanics the potential practical applications of this discovery aren’t readily apparent. The big issue we have with using quantum entanglement for anything currently is that making entangled particles is ridiculously hard. However if there’s potential for particles to be entangled without them needing to be near each other, or having even known each other at all, there’s potential to do away with the expense of creating them ourselves. Just how we go about harnessing these naturally entangled particles, and whether or not they have any practical uses, is something that will have to be worked on.
I have no doubt that quantum mechanics is a fertile ground for research to be conducted however I sometimes wish it wasn’t so weird. It took me the better part of 2 hours just to make sure I was understanding what the hell was actually going on and to verify that what the various reports were saying lined up with the actual research. Don’t get me wrong though, this kind of stuff is incredibly exciting, but it feels like you have to be wired in a slightly weird fashion for any of it to make sense to you the first time around. I’m sure it won’t be long before I’m thoroughly confused again, especially if anyone out there points out some factual inaccuracies in this post.
I think I need to lie down…
I really don’t understand the mistrust a lot of people have for the medical profession. Whilst I try my darndest to be informed in all matters that concern me I know when I’ve reached the limits of my understanding and that’s when I reach out to experts. In terms of my health there really isn’t anyone better qualified than a medical professional to give me advice on that subject and there are numerous specialists available to give me the information I require. Yet everywhere I go I meet people who believe that modern medicine has it all wrong and we should trust some whacko who’s being kept down by Big Pharma. The latest incarnation of this mistrust has come down to the vitamin K shot that’s routinely given to infants which apparently has all sorts of bad consequences for your child.
A standard treatment for newborns is an injection, or sometimes orally administered drops, of a high dose of vitamin K shortly after birth. The reason behind this is pretty simple, newborns have a severe lack of blood clotting factors being on the order of 30% to 60% lower than what they’ll have in adulthood. What this means is when a newborn starts bleeding, for whatever reason, it will continue to do so for a much longer time which poses significant risks to the child. Breast milk is unfortunately quite deficient in the amount of vitamin K provided with formulas having about 100 times more for this exact reason. The incident rate of bleeding resulting from deficiency of this nature isn’t high, about 1.7% or so, but it’s entirely preventable which is why the shot, or drops, are used. However because of reasons I’ll never understand some of the anti-vax crowd has started rallying against it, which has led to an increased prevalence of this entirely preventable condition.
Digging into the “controversy” around the shots shows that the roots of this new dissent with a long practiced and safe procedure stems from a (shockingly) discredited study that linked the shots to an increased rate of childhood cancer. A review of that study done in 2000 revealed that there was no link between the two and the results were born out of poor testing methods and small sample sizes. Other sites seem to rely on other, less scientific things like the injection causes pain, the amount of vitamin K is too high and that an injection is apparently an opportune time for an infection to get in.
Those reasons don’t really stand up to casual scrutiny however. Sure there’s studies that say sustained neonatal pain causes problems down the line but drawing conclusions that any kind of pain, even if only temporary, leads to the exact same effects. Dosages of vitamin K have shown to be safe and effective to orders of magnitude higher than the ones given to infants, even over sustained durations. The jab at the injection site being an opportune time for infection to get in is the last grab at straws as this is most likely going to happen in a hospital where the sterile conditions are likely to be much more guaranteed than a doctor’s office. If the argument was purely for drops over injections then I’d have little issue with it but that doesn’t seem to be the case with this latest bout of crazy.
Honestly we’ve got decades of research behind many of the things we’re giving to our children and the proof is in the results we’ve got. Infant mortality has been reduced to it’s lowest levels in all of human history thanks to modern medicine and to simply throw that away on the back of emotional arguments is, at best, foolish. If you really think that these things that modern medicine recommends are as bad as they sound I’d encourage you to get educated and ask the experts in the field about it. Present them the evidence you have and see how they react. More often than not you’ll find good answers to your questions and your children’s health will be all the better for it.