1 00:00:00,680 --> 00:00:03,760 Speaker 1: Get smarter in sixty seconds with brain Stuff from how 2 00:00:03,840 --> 00:00:09,040 Speaker 1: stuffworks dot com Hi Marshall Brain. Atomic clocks are important 3 00:00:09,080 --> 00:00:12,480 Speaker 1: to a variety of scientific endeavors. You can even buy 4 00:00:12,560 --> 00:00:15,840 Speaker 1: wall clocks and wrist watches that will synchronize with an 5 00:00:15,840 --> 00:00:20,720 Speaker 1: atomic clock in Colorado. So what exactly is an atomic clock. 6 00:00:21,400 --> 00:00:24,640 Speaker 1: Let's start with the general notion of a clock. A 7 00:00:24,800 --> 00:00:27,960 Speaker 1: clock's job is to keep track of the passage of time. 8 00:00:28,480 --> 00:00:32,200 Speaker 1: All clocks do this by counting the ticks of some 9 00:00:32,360 --> 00:00:36,440 Speaker 1: kind of resonator. In a pendulum clock, the resonator is 10 00:00:36,520 --> 00:00:39,600 Speaker 1: the pendulum. The gears in the clock keep track of 11 00:00:39,640 --> 00:00:43,720 Speaker 1: the time by counting the resonations, those swingings back and 12 00:00:43,800 --> 00:00:47,720 Speaker 1: forth of the pendulum. The pendulum usually resonates at a 13 00:00:47,800 --> 00:00:52,159 Speaker 1: frequency of one swing per second. A digital clock uses 14 00:00:52,320 --> 00:00:55,560 Speaker 1: either the oscillations of the power line, which is sixty 15 00:00:55,600 --> 00:00:59,240 Speaker 1: cycles per second in the United States, or the oscillations 16 00:00:59,280 --> 00:01:02,960 Speaker 1: of a quartz crystal as the resonator. It counts the 17 00:01:03,000 --> 00:01:08,200 Speaker 1: oscillations using digital counters. The accuracy the clock is determined 18 00:01:08,240 --> 00:01:12,000 Speaker 1: by the accuracy of the resonator. In an atomic clock, 19 00:01:12,600 --> 00:01:17,640 Speaker 1: the clock uses the resonant frequency of atoms as its resonator. 20 00:01:18,200 --> 00:01:20,880 Speaker 1: There are many different ways to get atoms to oscillate, 21 00:01:21,240 --> 00:01:24,760 Speaker 1: and you can then detect and count those oscillations. The 22 00:01:24,840 --> 00:01:28,360 Speaker 1: advantage of this approach is that the atoms resonate at 23 00:01:28,400 --> 00:01:33,280 Speaker 1: extremely consistent frequencies. If you take any atom of caesium 24 00:01:33,360 --> 00:01:36,319 Speaker 1: and ask it to resonate, for example, it will resonate 25 00:01:36,400 --> 00:01:40,440 Speaker 1: at exactly the same frequency as any other atom of caesium. 26 00:01:40,920 --> 00:01:45,520 Speaker 1: Caesium one thirty three oscillates at nine billion, one nine 27 00:01:45,800 --> 00:01:49,160 Speaker 1: two million, six hundred thirty one thousand, seven hundred seventy 28 00:01:49,200 --> 00:01:54,040 Speaker 1: cycles per second period. This sort of accuracy is completely 29 00:01:54,080 --> 00:01:57,000 Speaker 1: different from the accuracy of a Courts clock. In a 30 00:01:57,080 --> 00:02:00,680 Speaker 1: quartz clock, the Courts crystal is manufact extured so that 31 00:02:00,720 --> 00:02:05,240 Speaker 1: it's oscillating frequency is close to some standard frequency. But 32 00:02:05,440 --> 00:02:10,120 Speaker 1: manufacturing tolerances cause every crystal to be slightly different, and 33 00:02:10,280 --> 00:02:14,440 Speaker 1: things like temperature will change the frequency. A caesium atom 34 00:02:14,520 --> 00:02:18,640 Speaker 1: will always resonate at the same known frequency. That is 35 00:02:18,680 --> 00:02:22,080 Speaker 1: what makes atomic clock so precise. Do you have any 36 00:02:22,120 --> 00:02:25,800 Speaker 1: ideas or suggestions for this podcast? If so, please send 37 00:02:25,800 --> 00:02:29,160 Speaker 1: me an email at podcast at how stuff works dot com. 38 00:02:29,200 --> 00:02:31,480 Speaker 1: For more on this and thousands of other topics, go 39 00:02:31,600 --> 00:02:35,279 Speaker 1: to how stuff works dot com,