Category Archives: Time

Einstein Passes, Again

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Most precise test yet of Einstein’s gravitational redshift

When the cesium atom matter wave enters the experiment, it encounters a carefully tuned flash of laser light. The laws of quantum mechanics step in, and each cesium atom enters two alternate realities, Müller said. In one, the laser has pushed the atom up one-tenth of a millimeter – 4/1000 of an inch – giving it a tiny boost out of Earth’s gravitational field. In the other, the atom remains unmoved inside Earth’s gravitational well, where time flies by less quickly.

While the frequency of cesium matter waves is too high to measure, Müller and his colleagues used the interference between the cesium matter waves in the alternate realities to measure the resulting difference between their oscillations, and thus the redshift.

This is the UC Berkeley press release, and if one can ignore the use of the “many worlds” reference of alternate realities, is otherwise pretty good. It also includes some laser table porn which has been filtered out of the other stories I’ve run across. I’ve only had a chance to glance at the article, but there’s a lot of interesting physics in there that is not mentioned in the press release, or in the Nature summary story that ran in addition to the article (and was somewhat disappointing in terms of how it recapped the experiment).

The basic experiment is a decade old; the original idea was to measure the local value of g, because the two paths of the atoms have an energy difference of PE = mgh, and that gives you a phase difference for the two paths. The trick here is in reinterpreting the results in terms of relativity. I’ll try and summarize the details soon.

It's Easy When Someone Else Does It

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Starts With a Bang: A Brief History of Time… in the New World!

It was only about a week before people noticed that the Sun and Moon weren’t rising and setting at the times they were supposed to! Apparently, the clock was running at the wrong speed, and was running slow by somewhere around a minute per day. This brilliant clock, which was accurate to within two seconds a day in Holland, must have broken somehow during the journey.

So what were the colonists to do? There was no clockmaker (or clock repairman) in the new world, and this clock was handmade and very valuable. They had no choice; the clock needed to be shipped back to Europe for repair.

So they ship the clock back to Europe, and they go to take the clock into the clockmaker, and it does the exact thing that your car does when you take it to the mechanic because it’s making a noise. It starts behaving like it’s perfectly fine. The clockmaker winds up the clock, and it immediately starts working properly, and keeps time to within two seconds per day!

The needed to appreciate the gravity of the situation, of course.

A very nice story, up until the last sentence:

So go ahead and take your standardized time for granted, but remember that it wasn’t always as easy as it is today!

Easy for whom? The dragons currently live at several picoseconds per day instead of several seconds per day. Scientists doing research are always trying to be on the part of the map that says “Here be dragons.”

Recycled Headlines

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The world’s most precise clock

We get this headline every six months or so. The experiment is cool, and drives down the precision to new levels, but I’ll give the standard disclaimer: it’s a frequency standard, not a clock.

The logic clock is based on a single aluminum ion (electrically charged atom) trapped by electric fields and vibrating at ultraviolet light frequencies, which are 100,000 times higher than microwave frequencies used in NIST-F1 and other similar time standards around the world. Optical clocks thus divide time into smaller units, and could someday lead to time standards more than 100 times as accurate as today’s microwave standards. Higher frequency is one of a variety of factors that enables improved precision and accuracy.

Update: an article from Wired which has the virtue of calling it a frequency standard. Unfortunately, it sort of implies that we haven’t already measured gravitational time dilation, which of course we have, and (as I mentioned previously) has even been measured by amateur time nuts.

Countdown

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Want to know how many seconds are left in the year (presumably according to your computer clock)? Go to Google and click the “I’m feeling lucky” button.

Nature v Integers

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A brief history of calendars

Q: “Once in a blue moon” is a rare event. But what does “blue moon” really mean?

Don’t fall for the trendy answer.

This was the final question last week at Pub Trivia, and our team won the evening with the same answer to this question that almost everyone else gave, probably the answer you’ve heard before: a blue moon means two full moons in one calendar month. This month, December 2009, has a blue moon on the 31, since it also had a full moon on the 2nd. But I had the nagging feeling that I’d read or heard somewhere (probably on QI) that the popular definition is wrong, that the real blue moon isn’t that straightforward. When I got home, Google confirmed it: We were wrong, quizmasters and all.

Astronomical Clocks – Literally and Metaphorically

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Astronomical Clocks – Literally and Metaphorically

The term astronomical clock is one that is used fairly loosely. Effectively any clock that shows astronomical information – as well as the time – can be so classified. They can show the location of the sun in the sky, for example. In addition to that they can show the position of the moon – and further information such as its phase and its age. Others go further and show the current sign of the zodiac or even go as far as showing a rotating map of the stars.

It's About Time, Part III

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I was supposed to give a talk on timekeeping this past weekend, but it got shot down (Mendozaaaa! Congress!), and I also see that Chad has posted slides on a talk he recently gave on the topic, entitled A Brief History of Timekeeping. That gives me a nudge to try and finish my series.

Posting slides is great, but that tells you little about the actual talk — the slides for good talks are an outline, and diagrams/pictures that save you the thousands words of description; when the speaker just reads the slides it’s generally not a particularly good talk. (I’ve never attended a talk by Chad, but given his track record with his blog, I imagine they are good.) I’ll start this with a comment, and I don’t know what the narrative was for those slides — so Chad might have mentioned this, but perhaps not.

A clock is something that ticks. This is true, but it doesn’t tell the whole story; a clock is something more than that. You need a recording device, too. Time is the phase of an oscillation, and as that phase accumulates you need to keep track of it, which is why we have displays that get updated with each “tick,” or something equivalent to that. If you lose the phase information, or never had it, you don’t know what time it is. A pendulum clock without the hands, gearing, etc. is just a pendulum. Think of it this way: a clock that is powered up (new, or after an interruption) isn’t a particularly useful device. What’s the first thing you do at that point? You check a working device, because you want to synchronize your clock, i.e. you want to transfer the phase information, and set the phase of your device. And that’s an important distinction, because most devices that are called “clocks” are really frequency standards. They get turned on an off regularly, running only part of the time; the phase information is recorded by other devices that stay on continuously, as a sort of flywheel. The overall performance is going to depend on how often your frequency standard runs, and how good your flywheel is.

We’ve used numerous devices to build clocks over the course of history, including the earth’s rotation and orbit. The earth is not really a great clock, because the orbit is elliptical and the axis is inclined, which leads to variation in the length of the day and having the sun not be overhead (or on the line going overhead) at noon. But you can correct for these effects, and that’s an important point — a bad clock that is predictably bad is actually a better clock, because you can make the corrections to figure out what time it is. Some of us have experience with this — the people that set their clocks ahead to try and trick themselves into not being late. The problem is that they know that their clock is 10 minutes fast, and they do the math to figure out what time it really is. (This is similar conceptually to a paper clock, where you have a calculated time, but not an actual device displaying it.) NYC does this in reverse (as it were) with trains; they set the departure time a minute late. How will it work now that the cat is out of the bag?

When the earth was the “master clock,” the other devices (pendulum clocks, water clocks, candles, hourglasses, etc.) were the flywheels to carry us through to the next day (or next sunny day), at which time you could recalibrate your flywheel device. Eventually these other devices got better, and we realized that the earth had limitations, and with the maturation of atomic clocks, we made a transition from having the earth (a single artifact) represent the “truth” of time, to having a recipe for building a standard, based on Cs-133’s ground-state hyperfine transition at 9192631770 Hz. This is the way it has proceeded for other standards as well — once experimental realizations are better than a physical artifact, we’ve abandoned the artifact for a recipe on how anyone can realize the standard. We’ve gotten rid of the meter, which used to be a metal bar, and once the technology improves enough, we will abandon the physical kilogram.

What we gain in this is better precision and accuracy, but what we lose is that there is no “truth” anymore. To answer that old question asked by Chicago, nobody really knows what time it is (though lots of people do, in fact, care). We have these devices, which we use to measure time as precisely as possible, but none of them is “right.” We arrive at a solution for time by intelligently measuring and averaging clock signals, but it’s now a “voted” quantity, rather than there being a defined truth. However — and this goes for all science — the important thing is that “not knowing exactly” is not the same as “have no idea whatsoever.” Time (or a time interval) is perhaps the most precisely measured phenomenon, with fractional frequency stabilities for the latest frequency standards measured at parts in 10^18.

Another nit I had with Chad’s slides is that he didn’t show enough variety in his fountain clocks. Some images are hard to find, but not impossible (though the resolution isn’t great). Here’s one of the USNO Rubidium Fountain clocks (actual clock, not frequency standard)

rubidiumfountain

The Speed of Information

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Kottke: The speed of information travel, 1798 – 2009

The included link is chart showing the time it took for news of various events to reach London, and the resulting speed of that information. Kottke adds a couple of present-day data points to that.

[W]e’re not accustomed to news taking days or even hours to go around the world now, and even when reading history you usually get the impression that events were known immediately. (The dramatic speeding up of news reports around 1880 was a result of the invention and deployment of the telegraph.)

Certainly anyone growing up now, with access to twitter and the like, will have some difficulty appreciating this.

I think it’s easy to forget that it also takes time to gather information, especially for complex events. We have virtually instant access these days with electronic communication, but instant access to what? You can tell me that X happened, but then there’s a whole lot of dead air to fill while you figure out what the details were, and we shouldn’t forget that bad information travels just as fast.