E2science

Take, for instance, a wombat. A perfectly normal, everyday wombat, apparently unaware of his future place in the Annals of History as part of the most important animal-based experiment since we discovered the joys of thalidomide. Place this wombat on a reasonable flat, reasonably solid surface. Take another, seemingly innocuous wombat. He will need to be somewhat smaller than the previous wombat, for as we are about to see, you must now place this second wombat on top of the first. Amazing as this may seem to you, please, stop gawking. The really clever part is next.

Now, do this with an infinite amount of wombats. I say infinite, but in actuality the number needed is finite, only inversely proportional to the speed of the actual wombats.

I should probably also head off the PETA activists right now and say that since this is a hypothetical situation, my concern is not with the treatment of these wombats. Let us assume that they are perfectly happy wombats, well rested, and fed on the finest wombat food money can buy. In a real world scenario, you would obviously have some manner of wombat wrangler to look after the creatures, protect them from rabies, and generally keep them in a state fit to be stacked. They would not even be needed for any large amount of time; as you shall see, the experiment, bar stacking time, is over very quickly, and thus the animals can be sent back to their happy wombat lives secure in the knowledge that their intrinsically comedic appearance and ease-of-stack quotient has helped mankind break the final barrier to finding other civilizations, subjugating them under our ruthless expansionist principles, and sending them blankets covered in smallpox.

Right. Now. Once we have this infinite, or at least variably random (based on external wombat movement speed) amount of stacked wombats, we need to make them move forward at exactly the same time. This can be achieved through the use of cattle prods tear gas provocative pictures of lady wombats as incentive.

At this crucial stage in the hypothesis, one must imagine the scene: one average, albeit well built and gourmet-fed wombat, moving forward at a rate of, let's say, 10 km per hour. The second wombat, moving forward on top of the first, also moving at the hypothetically maximum wombat speed of 10 km per hour. Ditto the third. And the fourth. Thus, if we call the first wombat's speed x, the speed of any given wombat in the stack (k) can be deduced with the formula yx = k, where y is the number of the wombat's position in the stack. Therefore, the 10th wombat in the stack in the above example would, at a certain point in time in the wombat-stack's forward motion, be moving at a speed of 10(10) = 100 km per hour. Since we have our finite, but undeniably tall stack of wombats, eventually we shall reach a point in this stack where a particular wombat reaches, and then exceeds, the speed of light. If the speed of light is at or around 1,071,360,000 kilometers per hour, we can judge that this would be the wombat approximately 107,136,000 wombats up.

Obviously, we must give or take a couple of wombats due to what is scientifically termed 'wombat error', or, in applied thermodynamics, 'dumbass goddamn wombats'. This term applies to the phenomenon whereby some of the wombats will do one or more of the following:

• Fall off the stack during the stacking process. This is less common after actually being stacked, as it is somewhat difficult to hurl yourself to the ground when there are 100,000,000 other wombats above you.
• Slip, lose footing, and therefore speed. This can be solved with the use of special wombat-shaped running shoes. I would recommend those with rubber soles, not spikes, so as to preserve the beautiful coat of the wombat below, and maintain our PETA-friendly status.
• Need the bathroom. You're on your own here.

Now, I understand that there are those who put forward Einstein's Theory of Relativity, which dictates that the faster an object travels, the larger its mass becomes, and therefore our top wombat would, before reaching the speed of light, collapse into itself, reach infinite mass, and destroy the stack, the wombat wranglers, and a large part of our solar system. I think I speak for all of us when I say that these amateur physicists are nothing but godless heathens, and should be ignored. Besides which, if he really was as cool as these people think, why haven't we heard more about this 'Einstein' fellow? What has he ever done for the realm of theoretical physics?

To other nay Sayers, who dispute the lowly wombat's ability to hold the weight of an infinite amount of other wombats on his or her well-groomed back, I also have plans for a complicated harness/pulley system, the details of which I shall not bore you with, only to reassure you that not only does it render these wombats weightless, but also performs calculus equations, advocates the widespread promotion of world peace, and can sort underwear into lights and darks.

This experiment also then answers the question of 'What is faster than the speed of light?': a wombat, running on the back of a wombat already going at the speed of light.

For 80 years I lived with a mental disorder of which I was unaware until I bought a copy of The Oxford Reference to the Mind with a book voucher present. I suddenly found myself reading a description of myself.

From childhood I resented going to parties. On my first invitation to a street birthday party I asked Mum if I could take a book to read. Mum thought I was joking until I came out with my favourite book under my arm. I have always felt uneasy among groups as I could never identify friends. I suffered frequent embarrassment as I could not know if I had previously met people who obviously knew me.

Prosopagnosia, also known as Faceblindness is a deficit of the mind which prevents one from registering the image of people's faces for future recognition. Most people on seeing someone approaching will see an image of a face as opposed to a "thing". The image is sent to the fusiform gyrus, a part of the cortex in the left temple where the image is compared with a "file" of known faces. If the face is identified, motor neurons arrange a smile and outstretched hand to acknowledge recognition. Meanwhile, another "file" is searched to give the brain subjects for conversation, (recollection of last meeting, health of wife, members of family, &c.).

I have watched people walking towards me and giving me a quick glance before looking away. I estimate that within 1/50 second my face image has been examined and rejected as unknown. This extraordinary speed of mental activity is probably the fastest work called on by the mind.

Faceblindness is a misnomer as I can see eyes, noses and mouths the same as others but cannot recognise differences from one to another. I would prefer "facial amnesia" as a more accurate term. Prosopagnosia is not malignant, contagious, painful nor life threatening to sufferers nor to their acquaintenances. It therefore does not attract research grants.

Nevertheless, for sufferers it is very embarrassing. I can identify family members and a small circle of close friends. When I go to the butchers I greet Garry, who has his name outside, and wears a blue apron. But if I met Garry in Myers (Melbourne Department store), I would walk past him without acknowledging him. I repeat this snubbing of friends daily. When I walk in my local shopping strip I wear a half smile, ready for someone to identify me first. When they stop for a chat I have to desperately scan for a reference that I can respond to. Many are already aware of my problem as I have described the symptoms to them.

I was outside the chemists (pharmacists, drug store) talking to a couple who were aware of my trouble when a chap walked past us and called out, "Hi Ken!" and I replied, "Hi!" My friend asked who he was and laughed out loud when I replied, "I've never seen him before in my life!" I then walked into the chemists. I was followed by the man, who said "Hi Ken. I'm Daryl!" I immediately knew he was a regular visitor to our house when my wife was typing notes for him for the Neighborhood Watch group we shared in common! He had heard my reply and the loud laugh outside.

When we go to see a movie it always worries me if there are more than three characters as I cannot identify any more. We recently saw a movie called "Lantana" which seemed to consist of three couples who recklessly jumped in and out of each other's partners bed. This means there were 9 possibilities of sharing a bed with someone different (assuming the men avoided hopping into bed with another man). I kept whispering to my wife "Is he the man who was in bed with the blonde (or brunette)?" and similar questions throughout the performance. It was a strain for her to follow the plot with me whispering and was not too good for nearby patrons either. You can see how I used to enjoy Mickey Mouse and Donald Duck with their well defined faces.

I am certain that there are many who, like me are unaware of their condition. There is a support group website, FACEBLIND@MAELSTROM.STJOHNS.COM. I suggest if you recognise this deficit in yourself, you contact this group who will be sympathetic and supportive. I also would be pleased to hear from any other Australian who may recognise themselves here. Write to me here and tell me about it Ken Green aka Caligital.

Also known as antivenene or antivenom, antivenin is an antitoxin produced in the blood by repeated injections of venom.

Antivenin for venomous creatures is produced by gradually injecting livestock (usually horses) with the venom of a particular species. The animal gradually produces antibodies to the venom, and its blood plasma is harvested and refined to produce antivenin suitable for use in humans and other animals. This is the only proven method of treating venomous snake bites, and the venom of many other poisonous creatures. The production of antivenin in this way requires constant supplies of venom.

In the late 1800’s, Albert Calmette, a French physician, developed a method of producing antibodies to snake venom by slowly injecting livestock with non-fatal doses of the venom. Regular doses were given, with the volume slowly increasing, until the animal reached a state of “hyper-immunity” to the venom of that particular species of snake. Serum removed from the blood of the animal could transfer immunity to another animal, and reverse the effects of a bite from that snake species.

While various modernisations have been made to the process – it remains essentially the same today as it was over a century ago. The venom is now neutralised before use – the antibodies are still produced, but the animal does not undergo unnecessary suffering. After the serum is removed from the collected blood, the remainder of the blood is transfused back into the animal – preventing dramatic drops in red blood corpuscule and white blood cell count.

Production:

Antivenin is produced using the reconstituted freeze-dried venom from each particular snake species in order to gain an antivenin specific to that species. The process is as follows:

An animal (usually a horse in the case of snake antivenins) is injected on a regular basis with increasing non-fatal doses of venom. The venom has been treated to render it less harmful – the treating agent is often formaldehyde. This part of the process lasts from 10 to 12 months. The gradual increase of the tiny amounts of venom allows the animal’s immune system to produce antibodies to the venom. Blood tests determine when this has occurred. Once the animal has become hyper-immune to that form of venom, blood is taken from it – around 6 – 8 litres at a time – nowhere near a life-threatening amount.

The serum is separated from the blood solids – the latter are often transfused back into the animal. The serum is then treated and refined before it is suitable for use in humans. Immunoglobulins in the serum are digested by pepsin to isolate the specific antigen that will neutralise the venom of that species of snake. This product is stored in vials for rehydration for use in treating snake bite.

Polyvalent antivenins are produced by simultaneously exposing the horse to venoms from several different species of snake. They are usually related species whose venom acts in a similar way, and which can all be found in one area. Polyvalent antivenins are often less effective than monovalent (specific to one species) antivenins, but have the advantage that they can be used where the species of the attacking snake is unknown. The two antivenins generally used in the United States are both polyvalent.

Other methods of producing antivenin simply vary the animal used to produce the antibodies. Horses are generally used because their large size makes it easy to administer a non-fatal dose, and to harvest sufficient blood. Sheep are used in one of the main production facilities in the United States, and some work is being done with chickens. The beauty of using chickens to produce antivenins is that the antibodies are found in the eggs of envenomated chickens, and can be separated from the yolks. To create Funnel-web spider antivenin, rabbits are used rather than larger animals. The majority of information available is for snake antivenin. The theory and production is the same for other types of venomous creatures.

More about antivenin:

In Australia alone (ok, so we’ve got a stack of venomous snakes…) there are around 3,000 recorded incidents where humans are bitten by snakes per year. Of these, around 200 to 500 receive antivenin, and on average 2 are fatal. In the United States, around 8,000 people are bitten each year – and around 5 incidents will prove fatal. Surprisingly, in up to 50% of cases no venom is released – and the victim suffers no more than mild discomfort (and the pain of tetanus injections and so forth).

To treat snake bites, up to 40 vials of antivenin can be required for very severe cases. It seems to be that a reasonable amount of antivenin is around 5 – 20 mg for every mg of venom injected – depending on the species of snake. Since the larger snakes can deliver up to 100 mg of venom – a significant amount of antivenin is required. Hundreds of milkings can be required to produce a single dose.

With these figures in mind, it is no wonder that snake venom goes for a fairly hefty price, and that there is a constant shortage of antivenin in the developing nations. Snake venom prices vary, but the Australian Reptile Park – the sole provider of terrestrial species’ venoms to the Commonweath Serum Laboratories – sells dried Eastern brown snake venom for US$2000 per gram.

The shelf life of an antivenin can be up to three years if refrigerated. Antivenin should not be frozen.

Health hazards:

Antivenin, while often the only chance for life many bite victims have, is not without its risks. An equine-derived product, the chance of allergic reaction in recipients is alarmingly high. The most common snake antivenin in the United States is Antivenin (Crotalidae) Polyvalent (ACP) – used for rattlesnake, cottonmouth, and copperhead bites. Derived from horse serum, studies have shown that the chance of acute allergic reaction in a recipient (including anaphylaxis) ranges from 23% to 56%. In cases of only slight envenomation, the risk from the antivenin is higher than the risk from the bite itself – and antivenin will not be administered unless necessary. The newer and more expensive antivenin emerging in the states is CroFab – derived from sheep, and demonstrating a far lower incidence of acute allergic reaction – possibly around 14%. The reported risk in Australia was lower still.

Antivenin is always administered in carefully controlled situations, along with a cocktail of antibiotics, antihistamines, tetanus vaccine, and painkillers. It is usually given over a period of time in a saline drip, so that reactions can be monitored and dealt with.

Another phenomenon is “serum sickness” – a delayed reaction to the antivenin. This may occur several days or weeks after treatment, and is found in about half the recipients of antivenin.

Symptoms of serum sickness may include:

• Fever
• Chills
• Rash
• Itching
• Muscle aches
• Swollen lymph nodes
• Blood in urine

Available antivenins:

A specific antivenin is available for all of Australia and the United States’ most venomous snakes. Polyvalent antivenins cover all of the more obscure species, as far as I was able to ascertain. Sea snakes have specific antivenin, and some species respond well to Tiger snake antivenin. Britain’s only venomous snake: the adder (Vipera berus) has a specific antivenin. Red back funnel web, and black widow spiders all have specific antivenins, as do scorpions, stone fish and box jellyfish. There is no antivenin for cone shells (conus species) or the Blue ringed octopus.

Basically put – there are very few common venomous animals in the developed countries that do not have a specific antivenin in production. So in general – we’re pretty safe. The risk for collectors and owners of exotic species is higher though - as many of the more rare species have no antivenin.

Thanks to BlakJak and Ascorbic for helping me out with tricky bits of research.

http://www.azer.com/aiweb/categories/magazine/ 32_folder/32_articles/32_vipers.html
http://www.usyd.edu.au/su/anaes/venom/snakebite.html
http://hvelink.saint-lukes.org/library/healthguide/IllnessConditions/topic.asp?hwid=tm6541
http://www.abc.net.au/btn/scripts/2002/10-29/snakes.htm
http://mysite.mweb.co.za/residents/net12980/toxins.html
http://news.bbc.co.uk/1/hi/health/890305.stm
http://www.bio.davidson.edu/biology/kabernd/seminar/studfold/MUVT/history.html
http://www.barrierreefaustralia.com/the-great-barrier-reef/stonefish.htm
http://news.nationalgeographic.com/news/2003/01/0106_030108_snakewrangler.html
http://www.aafp.org/afp/20020401/1367.html

Structure

A ketone is an organic (carbon-based) compound, that can generally be written in the form R₁-CO-R₂. A ketone is essentially an alkane of length greater than two, that contains an oxygen atom bonded to a carbon atom that is not on one of the ends of the chain.

Consider the shortest ketone, propanone (acetone). The root is propane, C₃H₈.

  H
  |
H-C-H
  |
H-C-H
  |
H-C-H
  |
  H

To form a ketone from this, remove two hydrogen atoms bonded to the middle carbon (recall, the carbon-oxygen bond must not be at the end of the chain) and replace it with an oxygen (the combining capacity of oxygen is two, so it must be double bonded with the carbon to be stable). This forms the carbonyl bond that defines a ketone.

  H
  |
H-C-H
  |
  C=O
  |
H-C-H
  |
  H

It is now a ketone, with the IUPAC name propanone, or 2-propanone.

Naming a Ketone

1. Name the longest chain of carbons as if it were an alkane. Use this as the root.
2. Determine which carbon the oxygen is double bonded to (count so that the bonded atom has the lowest number possible). Prepend this number to the root.
3. Replace the ending of the root "-e" with the ending "-one"

Properties of Ketones

The properties of ketones are similar to the properties of aldehydes. Due to the polar nature of the carbonyl bond, ketones are polar molecules, decreasing in polarity as the size of the root chain increases. Due to the polar nature of the molecule, ketones may participate in hydrogen bonding, especially with water. They will not, however, hydrogen bond with themselves, as they lack a polar bond with hydrogen. Due to the hydrogen bonding with water, ketones are highly soluble. Ketones generally have a strong scent, often pleasant and sweet, and may be used in perfumes. Like aldehydes, ketones are highly flammable, although they are generally both less reactive and less toxic than aldehydes.

Formation of Ketones

Ketones are generally formed via the oxidation of secondary alcohols, in the presence of a strong oxidising agent.

See Also

A guide to naming organic compounds : Functional Groups, ketosis

The concept of relative simultaneity is a major part of understanding the special theory of relativity. If you don't know anything about special relativity yet you might want to check out either the node of the same name or theory of relativity. There isn't really much math here beyond algebra, and a lot of that can be skipped if you don't like it. I hope that just reading the descriptions you can get an idea of what's going on.

In special relativity, the same event will be observed to have happened at different times by different observers if they are moving relative to one another. The basic idea of relative simultaneity is that two events that are simultaneous to observer Alice will not be simultaneous according to observer Bob if Bob is moving relative to Alice. This comes from the fact that the speed of light is the same for both Alice and Bob (in fact, all inertial observers). This doesn't destroy the concept of simultaneity altogether. All observers in the same reference frame (ie. stationary with respect to one another, in special relativity) will still agree on whether two events are simultaneous or not. Furthermore, there is still a definite relationship between the timing of events in one frame of reference and in another frame of reference.

The relationship is given by the Lorentz transformations and tells us that if an event happens at position x and time t in reference frame S, then in reference frame S' (which has t' = 0 and x' = 0 when t = 0 and x = 0) moving at velocity u in the positive x direction the event occurs at t' = γ(t - ux/c²). That means that if S' is moving toward the event according to S, then it will occur at an earlier time in S' than it did in S. Likewise, if S' is moving away from the event, then it will occur later in S' than in S. For two events that are a distance Δx apart in space and Δt in time as observed in frame S, we can use the Lorentz transformation we just listed to find that in S' the time difference between the events is

Δt' = γ(Δt - uΔx/c²)

Understanding Relative Simultaneity

Suppose that Alice is sitting in a space station that is exactly between two stars, each 5 light years away. Alice is approximately at rest relative to the stars. Let us suppose that Alice sees each star has a flare simultaneously. Since the light from each flare reached Alice simultaneously and she knows it would have taken light from each star 5 years to reach her, Alice can then determine that the two stars had flares simultaneously 5 years ago. Let's call that time when the flares occurred according to Alice t = 0. So remember, that means Alice observed the flares simultaneously at t = 5 years.

Now, suppose at t = 0 Bob passed Alice's space station flying in a space ship at 2/3 c (meaning 2/3 the speed of light in vacuum). If Bob is moving toward star 1, then from Alice's point of view he will hit the light from star 1 first, since it is also moving toward him. Specifically, at t = 3 years, the light from star 1 will have traveled 3 light years toward Alice, and Bob will have traveled 2 light years toward star 1. Since the total distance is 5 light years, that means that Bob will be met at that point by the light from star 1. Meanwhile, he is moving away from star 2, so according to Alice it will take the light from star 2 longer to catch up with Bob. Specifically, the light from star 2 won't catch Bob until t = 15 years, when Bob has traveled 10 light years away from Alice and the light from star 2 has traveled the 5 light years to Alice and then the extra 10 to get to Bob. That may be confusing. I've made some crude ASCII diagrams below to help explain. All the action is happening along one line, but I've put things offset one line vertically at times, in order that you can make out the separate light beams.

Alice    A
Bob      B
Stars    *
Light    ~~

t = 0        *          A          *
                        B->

t = 3 yrs    *~~~~~~
                        A
			     ~~~~~~*
                            B

t = 5 yrs    *~~~~~~~~~~
                        A
			 ~~~~~~~~~~*
                              B

t = 15 yrs   *~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
                        A
                                            B

In the last diagram I've removed star 1, since it's not of any interest in that diagram.

Ok, so all we've determined so far is that according to Alice, light from star 1 must reach Bob before light from star 2. So we know that Bob will see star 1 flare before star 2. If we wanted to know exactly how much before, though, we'd have to account for time dilation, which makes time pass more slowly for Bob, according to Alice. Still, we can't dispute that Bob will see star 1 flare first.

Now we must use our rules of relativity to figure out what this means for Bob. When Bob passes Alice in her space station, he sets his clock to t'= 0, so his watch is synchronized initially with Alice's. According to him, the two stars also have the same distance from him at t'= 0. For Bob, star 1 appears to be moving toward him at 2/3 c, and star 2 appears to be moving away from him at 2/3 c. Now, if we were to tell Bob that star 1 and star 2 each had a flare at t' = 0, then he would conclude the following: Each star had the same distance at t' = 0, and the light each star lets off will approach Bob at the speed of light in his frame of reference, regardless of how the star is moving. So, just as Alice did, Bob concludes that light traveling from two equidistant sources at the same speed must reach him at the same time. Since Bob sees the light from star 1 first, he must therefore conclude that star 1 actually flared first.

At first it might seem like this is just screwy reasoning, but in fact it is a direct consequence of our statement that light always travels the same speed. The result is unintuitive because light does not obey the normal addition of velocities. By that I mean that if a stationary star emits light, it goes at c. If a star moving at speed v emits light, it still moves at c not at v+c! That may well seem strange and counterintuitive, but it's the way nature works. See special relativity and relativistic addition of velocities for more details.

A possible misconception

I know that when I first learned about this idea, I thought that the idea was the following: The time of an event A for an observer S is the time when the light from A reaches S. In that case Alice would say the flares happened at t = 5 years in the example above. I want to emphasize that that is not what we have been saying. When an observer receives light from an event, she takes the time the light arrived and how far away the event was (we assume she can tell this from the light she receives), and then she uses the fact that the speed of light is always the same to figure out when the light must have originated from that event. That is why Alice knows the flares happened at t = 0 years, not at t = 5 years. Again, the weird effects with time here are from the unintuitive fact that the speed of a light beam will be the same for any two observers, even if one is moving relative to the other.

What can we say about temporal relationships?

Δt' = γ(Δt - uΔx/c²)

That is generally what we know about the relationship in time for two events according to different observers. We can get a bit more information from this formula, though. First, let's re-write it as

Δt' = γΔt(1 - (u/c)*(Δx/Δt)/c)

So, if you can't get between two events going at less than c (meaning Δx/Δt > c), then there is an observer with a velocity u such that the two events are simultaneous in his frame. Mathematically, if (Δx/Δt)/c > 1, then there's a u < c where (u/c)*(Δx/Δt)/c = 1, making Δt' = 0. More than that, you could choose u large enough that Δt' has the opposite sign from Δt. That means there's a frame where the two events have the other order in time. This isn't as bad as it might seem at first, because at least if no one can get between the events going less than the speed of light, then the two events can't influence one another.

On the other hand, in the case that you can get between two events going at less than c (in which case Δx/Δt < c), then there's no u value that makes Δt' go to zero or switch signs, meaning that the two events have the same order in time for all observers (though the actual length of time between them might be different). When this is the case and the time order is unambiguous, the events are said to have a time-like separation or be connected by a time-like trajectory. Two events like this, where you can get from one to the other going less than the speed of light, can be causally connected (meaning event A could have caused event B), so it's good that all observers agree on their order in time, otherwise we could end up with all sorts of time paradoxes.

A geometric view

One can also take a geometric view of all this. I won't attempt to draw the spacetime diagram here (due to the limitations of ASCII art), but, if you were to make a spacetime diagram in terms of the coordinates of a frame of reference S with time on the vertical axis and space on the horizontal, then a pair of simultaneous events would both fall on the same horizontal line, representing the same value of t. Now, using the Lorentz transformations, we could draw on another set of axes, representing the coordinates of S'. Lines of constant time t' would have the form γ(t - ux/c²) = constant, which would be a line with a positive slope. In that case, the two events that fall on the same horizontal line (and are, thus, simultaneous in S) will not fall on the same line of constant t', so they will not be simultaneous in S'.

Relative simultaneity in everyday life

You might ask, "If this is all true, how come I've never noticed this?" As with many things in relativity, part of the answer is that the effects don't appear until you start dealing with velocities comparable to the speed of light, which we almost never do (except in particle accelerators, etc). If we go back to the formula for the relationship of the time difference in different frames of reference, written in the form

Δt' = γΔt(1 - (u/c)*(Δx/Δt)/c)

then we see that for u small enough Δt' and Δt are approximately the same. Specifically, it looks like we need u*(Δx/Δt) << c² for the order in time not to switch. The change in the length of the time interval also depends on γ, which becomes 1 for u << c. Generally, unless Δx/Δt is large compared to c, u << c will make this effect of relativity disappear, and we know we can always choose a range of u small enough so that the effect is negligible.

Let's try some real world numbers to get an idea for the size of this effect. Let's say that according to an observer stationary relative to the earth's surface two events happen simultaneously at opposite sides of the earth, that's about 12,000 km. That will be our reference frame S, which is approximately inertial if we only consider a short period of time and neglect gravitational effects. Let us also suppose there's an SR71 jet carrying a second observer that is flying directly above the first observer at a speed of 1 km/s. This is probably the one of the situations in which the effects of relative simultaneity should be most apparent to people on earth. In that case, it turns out that Δt' ≅ 0.13 μs, so it would only be detectable with a fairly sensitive time measurement. Needless to say that in our day to day lives, these effects are completely imperceptible.

A paradox

Want to test out whether you've understood all this? Then check out The Barn And The Pole: A Relativity Paradox, which is a writeup of a classic relativity paradox. You may want to check out the writeups on the Lorentz transformations and on length contraction.

Sources: My own knowledge of special relativity.

Though I didn't really consult any sources to write this, if you want to look at some, here are some suggestions:

The book I originally learned from (not necessarily recommended)

A. P. French, Special Relativity

A well respected introduction to special relativity from the view of geometry (spacetime diagrams) at an introductory/intermediate college level

Taylor and Wheeler, Spacetime Physics

Finally, most general physics text books will have a chapter somewhere near the back about relativity, which generally will contain a section on this subject. For example

Serway and Jewett, Physics for Scientists and Engineers 6th ed. chapter 39, section 4.