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==Explanation== | ==Explanation== | ||
+ | {{incomplete|Created by a CONSTANT PLANCK. Links to resources would be good. Do NOT delete this tag too soon.}} | ||
− | + | On the day of this comic, the {{w|International Committee for Weights and Measures|International Committee for Weights and Measures}} voted to redefine the kilogram by fixing it to the value of Planck's Constant. This is done by passing a measured current through an electromagnet to exert a force to balance 1 kg. The change will take effect on May 20, 2019, when the platinum cylinder International Prototype Kilogram that defines the unit will be retired. This means that the mass of a kilogram will no longer be calibrated by comparing the relative mass of two physical objects, but by measuring the influence of an electromagnetic field relative to local gravitational forces. | |
− | + | The previous method of confirming that a kilogram is accurate is to use physical metal weights measuring exactly one kilogram, periodically transporting them around the world to an official weight lab to confirm they still weigh the same. Over time these physical objects have changed very slightly in their mass making them unreliable in the long run -- thus running into the issue that a kilogram did not stay a constant measure of mass. Note that these weights and comparisons are so precise that a fingerprint on one of the weights could throw them off. | |
− | + | In this comic, Black Hat announces that the kilogram has been redefined as equal to one pound. Ponytail and Cueball seem to think this makes things simpler, but Megan is rightfully alarmed. The metric system of measurement is the one used by most of the world and is the standard system used in science. It is considered superior to the {{w|United States Customary System}} and the {{w|Imperial system}} (both of which the pound is part of). Therefore, redefining the kilogram to be based on the pound would make things much, much worse and outrage supporters of the metric system. More to the point, the pound is still often defined by metal weights, thus running right back into the very same problem they tried to escape from. | |
− | + | In real life, the pound is officially defined as 0.45359237 kilograms, or less than half a kilogram. This makes defining a kilogram as one pound even more impossible as they are then stuck in a loop, as the pound must weigh less than half of a kilogram, meaning the value of each would be equal to zero. | |
− | In | + | In addition, the pound is a unit of weight, whereas the kilogram was a unit of mass, thus fixing the kilogram to the pound would make even less practical sense. |
− | + | The title text continues the joke by saying that the meter has been defined as exactly three feet. The yard, the closest US measurement to the meter, is three feet. However, a meter is about 9 centimeters longer than a yard. As with the pound, the metric system is used to define the yard as it is officially defined as 0.9144 meters. | |
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− | The title text continues the joke by saying that the meter has been defined as exactly three feet. The yard, the closest US measurement to the meter, is three feet. However, a meter is about 9 centimeters | ||
==Transcript== | ==Transcript== | ||
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Nevertheless, there really are constants of nature. For example, one of them is ‘''c''’, the speed of light in a vacuum. The expressed value of ''c'' depends on your choice of the unit of distance and the unit of time, but it’s a constant in those units. Now just suppose we all had a reproducible way to define a specific unit of time, which just for fun we call a ‘second’. You might not know the length of a ‘meter’, but if I told you that measured in meters per second the universal constant value of ''c'' is exactly 299792458 meters per second, then I would have fixed the length of a meter to be exactly the distance light travels in a vacuum in 1/299792458 seconds. And in fact this is what the international body responsible for defining our SI units has done. | Nevertheless, there really are constants of nature. For example, one of them is ‘''c''’, the speed of light in a vacuum. The expressed value of ''c'' depends on your choice of the unit of distance and the unit of time, but it’s a constant in those units. Now just suppose we all had a reproducible way to define a specific unit of time, which just for fun we call a ‘second’. You might not know the length of a ‘meter’, but if I told you that measured in meters per second the universal constant value of ''c'' is exactly 299792458 meters per second, then I would have fixed the length of a meter to be exactly the distance light travels in a vacuum in 1/299792458 seconds. And in fact this is what the international body responsible for defining our SI units has done. | ||
− | + | One second is defined to be a specific number of certain state transitions of a cesium 133 atom. The specific number was set in the year 1965, so as to match a previous astronomical standard called Ephemeris Time to the limit of human measuring ability at the time. The 1965 definition didn’t change the actual duration of a second, but it did make its measurement forever reproducible. | |
In 1983 the value of ''c'' was fixed to the value noted above. Prior to that it had been measured with respect to existing definitions of a meter, and had to be expressed with a measure of uncertainty. For example in 1973 a team at the US National Bureau of Standards refined ''c'' to 299,792,457.4 m/s ± 1 m/s. But from 1983 onwards, with an exact integer value for ''c'' that is quite close to that Bureau measurement, the length of a meter is now fixed with no plus/minus uncertainty. Furthermore, both the second and the meter match their predecessor definitions for all intents and purposes. | In 1983 the value of ''c'' was fixed to the value noted above. Prior to that it had been measured with respect to existing definitions of a meter, and had to be expressed with a measure of uncertainty. For example in 1973 a team at the US National Bureau of Standards refined ''c'' to 299,792,457.4 m/s ± 1 m/s. But from 1983 onwards, with an exact integer value for ''c'' that is quite close to that Bureau measurement, the length of a meter is now fixed with no plus/minus uncertainty. Furthermore, both the second and the meter match their predecessor definitions for all intents and purposes. | ||
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To expand on this even further, three additional universal constants that were previously measured and that had uncertainty values have been assigned fixed values, resulting in exact definitions of three corresponding units of measurement without affecting their applicability. Fixing the unit of elementary charge, ''e'', serves to define the unit of electric current, the Ampere. Fixing the unit of luminous efficacy ''K<sub>cd</sub>'' serves to define the unit of luminous intensity, the candela. And fixing the Avogadro constant ''N<sub>A</sub>'' serves to define the unit of amount of substance, the mole. | To expand on this even further, three additional universal constants that were previously measured and that had uncertainty values have been assigned fixed values, resulting in exact definitions of three corresponding units of measurement without affecting their applicability. Fixing the unit of elementary charge, ''e'', serves to define the unit of electric current, the Ampere. Fixing the unit of luminous efficacy ''K<sub>cd</sub>'' serves to define the unit of luminous intensity, the candela. And fixing the Avogadro constant ''N<sub>A</sub>'' serves to define the unit of amount of substance, the mole. | ||
− | A Wikipedia article about redefining the SI units of measure in terms of newly fixed values of things taken to be universal constants is {{w| | + | A very recent Wikipedia article about redefining the SI units of measure in terms of newly fixed values of things taken to be universal constants is {{w|Redefinition of SI base units}}. |
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{{comic discussion}} | {{comic discussion}} |