When and Why Was the Definition of the Meter Changed?

In summary: SI units, sure.If a unit such as ##10^5## were really useful, then sure, I would be in favor of its inclusion. However, as it currently stands, I do not see why this unit should be included in the SI. It does not seem to me to be very useful or convenient.
  • #36
Once we are listing our pet peeves with the SI, here is mine: I think it's awful that Avogadro's number is now an arbitrarily chosen constant. This number, or rather its reciprocal, once represented an important physical quantity: the mass of a baryon in grams. Of course both "baryon" and "gram" require further specification, but the choice of Carbon-12 selects the baryons in a satisfactory way, and we had just gotten around to a solid definition of the gram. So Avogadro's number should be an experimental fact, not open to definition by fiat.
If they would have gone the other way and set a number for ##N_A## while keeping the Carbon-12 standard, thereby defining the gram and kilogram, I would be happy with that too. But fixing both the kilogram and the mole numerically removes the physical meaning of the mole/amu/Avogadro number, and so makes the system more arbitrary rather than less.

Of course, I am also offended that they used ##h## rather than ##\hbar## for the kilogram definition. Can you imagine, ##\hbar## is now an irrational number!
 
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  • #37
maline said:
This number, or rather its reciprocal, once represented an important physical quantity: the mass of a baryon in grams.
We can now write the mass of a baryon directly in the new kilogram standard. Why does Avogadro’s number need to be tied to the mass of a baryon?
 
  • #38
Dale said:
We can now write the mass of a baryon directly in the new kilogram standard. Why does Avogadro’s number need to be tied to the mass of a baryon?
Of course it doesn't need to be. But it pains me that something that once had physical meaning has been redefined as a mere convention.
The mole is not just "some big number that we divide our quantities by to make them manageable". It is the conversion factor between amu and grams, and amu is/was (a more rigorous form of) "number of baryons". The new definitions lose contact with that structure.
 
  • #39
maline said:
Of course, I am also offended that they used ##h## rather than ##\hbar## for the kilogram definition. Can you imagine, ##\hbar## is now an irrational number!
In SI base units, yes. In reasonable units ##\hbar = 1##. 😉
 
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  • #40
maline said:
Once we are listing our pet peeves with the SI, here is mine: I think it's awful that Avogadro's number is now an arbitrarily chosen constant. This number, or rather its reciprocal, once represented an important physical quantity: the mass of a baryon in grams. Of course both "baryon" and "gram" require further specification, but the choice of Carbon-12 selects the baryons in a satisfactory way, and we had just gotten around to a solid definition of the gram. So Avogadro's number should be an experimental fact, not open to definition by fiat.
The mass difference between different nucleons (not to speak of baryons in general) and even between the mass for the same nucleon in different nuclei is far greater than the deviations of the true mass of N_A C-12 atoms from 12g. Hence, I don't see a problem here.
 
  • #41
The SI didn't knowingly change the values of any of the units, so I expect that the mass of 1 mol of Carbon-12 is still exactly 12g, to within current measurement accuracy. What bothers me is that this fact no longer play any definitional role.
I think that as much as possible, units should be values with specific physical relevance. Of course we are limited by the need to keep fixed the values currently in use, so we are forced to use large, ugly multiples of the physical values. The mole was the one case where the old value actually did have significance, and they went and stuck in a big ugly number anyway!
 
  • #42
maline said:
I think that as much as possible, units should be values with specific physical relevance.
As far as I know none of the SI units satisfy that criterion. I think only natural units would.
 
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  • #43
Dale said:
As far as I know none of the SI units satisfy that criterion. I think only natural units would.
They don't now, but they were originally intended to. The metre was ##10^{-7}## times the length of a curve from the Earth's equator to its north pole. The gram was the mass of a cubic centimeter of water at standard atmospheric pressure and freezing temperature. And the (older) second, of course, was ##\frac 1{24\times 60\times 60}## of the Earth's mean solar day.
The ideal of choosing units based on Nature is what gave us the SI in the first place. Unfortunately the old definitions failed, due to the values involved not being truly fixed nor easy to measure, and the newer definitions were constrained to be equal to the old ones in value. if we were creating new units today, we would probably use natural units times powers of ten, and perhaps the Cesium hyperfine transition frequency times a power of ten. We certainly would not use numbers like 299,792,458!
 
  • #44
maline said:
They don't now, but they were originally intended to. The metre was ##10^{-7}## times the length of a curve from the Earth's equator to its north pole. The gram was the mass of a cubic centimeter of water at standard atmospheric pressure and freezing temperature. And the (older) second, of course, was ##\frac 1{24\times 60\times 60}## of the Earth's mean solar day.
Honestly, those were horrible definitions as they relied on arbitrary artefacts and resulted in units that were not very well defined.
 
  • #45
Orodruin said:
Honestly, those were horrible definitions as they relied on arbitrary artefacts and resulted in units that were not very well defined.
Of course we know they didn't work well, and perhaps people should have foreseen that. But the motive was to make the units as non-arbitrary as possible, and I think that's still an admirable ideal.
And yes, nowadays our perspective is so broad that we think of the planet Earth as an "arbitrary artifact". So much the better!
 
  • #46
To argue that the 'Mole' is not dimensionless is like arguing that the number 1 is not dimensionless, because you have to have one of something?

Errr... no, not really.

A Mole is dimensionless, whereas a mole of [something] has the dimension [something].
 
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  • #47
maline said:
The mole is not just "some big number that we divide our quantities by to make them manageable". It is the conversion factor between amu and grams, and amu is/was (a more rigorous form of) "number of baryons". The new definitions lose contact with that structure.
No, they don't. All they do is make the conversion factor exact.

If you had an apparatus that you used to measure the conversion factor you would continue to use the same apparatus in the same way. It's just that the apparatus now calibrates rather than measures. There's nothing less physical about that.
 
  • #48
maline said:
They don't now, but they were originally intended to. ...
You and I have very different opinions on what constitutes a physically meaningful quantity. To me all of those quantities you have identified as being physically meaningful are not, while the fundamental constants of nature are physically meaningful.

I mean, the mass of a cubic centimeter of water is only physically meaningful to me if I am weighing a volume of water. Planck’s constant is physically meaningful then, but it is also physically meaningful if I am measuring other things besides a volume of water.
 
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  • #49
Dale said:
I mean, the mass of a cubic centimeter of water is only physically meaningful to me if I am weighing a volume of water.
I think the idea was to define the gram in terms of the centimeter, with the conversion factor being the most "natural" density available. Pure water was seen as the archetypical 'measurable substance".
Dale said:
To me all of those quantities you have identified as being physically meaningful are not, while the fundamental constants of nature are physically meaningful.
I probably don't disagree with you on most of those judgements. The difference is the difference in perspective between the eighteenth and twenty-first centuries. Things like the details of our planet, or the freezing point of water, were once seen as primal and indispensable elements of Reality. Nowadays we know a bit more about with things are truly fundamental, so the old Tremendously Important Facts have become contingent bits of trivia.
My point is the ideal that I think they were aiming for with these definitions: to describe our quantities relative to fundamental aspects of Nature, with a minimum of arbitrary choice. I admire that goal, and I think that the old definition of Avogadro's number was the last piece of the SI to still exemplify that, without the ugly numbers.
 
  • #50
maline said:
without the ugly numbers.
The entire point of the "ugly" numbers is to ensure that all of the archaic definitions hold to measurement accuracy (or at least very close to it). As such, those "ugly" numbers appear as a relic of the old definitions.

The main point of the definitions is to make the units as well defined as possible, thus referring to measurements with as little measurement uncertainty as possible (and also not subject to changes over time as artefacts are prone to).
 
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  • #51
Note: If we wanted "nice" numbers, then we would probably define a reasonably sized length unit such that the speed of light would be ##10^9## of that length unit per second ... Oh wait! That is within 2% of a foot, can't have that ...
 
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  • #52
maline said:
I admire that goal, and I think that the old definition of Avogadro's number was the last piece of the SI to still exemplify that, without the ugly numbers.
Avagadro's Number looks a lot less ugly to me now than it did before. Now it's an integer. It used to have an uncertainty to it, that seems more ugly to me.
 
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  • #53
Orodruin said:
Note: If we wanted "nice" numbers, then we would probably define a reasonably sized length unit such that the speed of light would be ##10^9## of that length unit per second ... Oh wait! That is within 2% of a foot, can't have that ...
Bwa Ha Ha! You caught on to my sinister plot for Imperial supremacy!
 
  • #54
Mister T said:
Avagadro's Number looks a lot less ugly to me now than it did before. Now it's an integer. It used to have an uncertainty to it, that seems more ugly to me.
Well yes... meaningful quantitative statements do tend to have uncertainty... only tautological ones don't.
 
  • #55
I prefer 'Avogadro's Constant (Na) = 6.022E23/mol

the "mole" is not defined as a number; it is defined as an 'amount of substance' (symbol, n)

and 1 mol of anything is the amount of that thing that has 6E22 entities.

Somebody mentioned that the mole is a conversion unit. It surely is. It is a miracle constant. It instantly converts atomic mass numbers into grams. From the micro world to the macro world. What is the value of this constant? Who gives a damn'? (OK, it's the inverse of the atomic mass unit expressed in grams)

If the value of Avogadro's constant were 42/mol, a chemist's life would be horrible. The poor chemist would have to deal with one number if he/she is thinking about atoms and molecules, and a different number if he/she were in the lab with bottles of stuff. It doesn't bear thinking about.
 
  • #56
killinchy said:
the "mole" is not defined as a number; it is defined as an 'amount of substance' (symbol, n)
Nobody has said otherwise. It has been argued that it would be more natural to define it as a number or symbol.
 
  • #57
killinchy said:
I prefer 'Avogadro's Constant (Na) = 6.022E23/mol

the "mole" is not defined as a number; it is defined as an 'amount of substance' (symbol, n)

and 1 mol of anything is the amount of that thing that has 6E22 entities.

Somebody mentioned that the mole is a conversion unit. It surely is. It is a miracle constant. It instantly converts atomic mass numbers into grams. From the micro world to the macro world. What is the value of this constant? Who gives a damn'? (OK, it's the inverse of the atomic mass unit expressed in grams)

If the value of Avogadro's constant were 42/mol, a chemist's life would be horrible. The poor chemist would have to deal with one number if he/she is thinking about atoms and molecules, and a different number if he/she were in the lab with bottles of stuff. It doesn't bear thinking about.
You should update your notion of how the SI defined today. Don't worry, the change officially got into effect only in May this year :-).
 
  • #58
Orodruin said:
Nobody has said otherwise. It has been argued that it would be more natural to define it as a number or symbol.
But it IS defined as a number:

The mole, symbol mol, is the SI unit of amount of substance. One mole contains exactly ##6.02214076 \cdot 10^{23}## elementary entities. This number is the fixed numerical value of the Avogadro constant, NA, when expressed in the unit ##\text{mol}^{−1}## and is called the Avogadro number.[7][49] The amount of substance, symbol n, of a system is a measure of the number of specified elementary entities. An elementary entity may be an atom, a molecule, an ion, an electron, any other particle or specified group of particles.

For details about the new SI, see the Wikipedia article

https://en.wikipedia.org/wiki/2019_redefinition_of_the_SI_base_units
 
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  • #59
vanhees71 said:
But it IS defined as a number:

The mole, symbol mol, is the SI unit of amount of substance. One mole contains exactly ##6.02214076 \cdot 10^{23}## elementary entities. This number is the fixed numerical value of the Avogadro constant, NA, when expressed in the unit ##\text{mol}^{−1}## and is called the Avogadro number.[7][49] The amount of substance, symbol n, of a system is a measure of the number of specified elementary entities. An elementary entity may be an atom, a molecule, an ion, an electron, any other particle or specified group of particles.

For details about the new SI, see the Wikipedia article

https://en.wikipedia.org/wiki/2019_redefinition_of_the_SI_base_units
It is not defined as a number in the sense we typically use in the meaning of having no physical dimension. Although the Avogadro number is defined by its numerical value and represents the number of entities in a mole by definition, amount of substance (and hence the unit mole) has its own physical dimension within SI. A mole is therefore not dimensionless and neither is Avogadro's number (even if it is called "number").

The argument that some (including myself) have made in this thread is that it would be more natural not to give substance amount its own physical dimension and having the mole be a symbol like % or making it actually represent a dimensionless number (which would in essence be ##N_A##).

Edit: The physical dimensions of the base units are also discussed in the SI brochure section 2.3.3:
Physical quantities can be organized in a system of dimensions, where the system used is decided by convention. Each of the seven base quantities used in the SI is regarded as having its own dimension.
It is clear from this that the mole (which is a unit of the base quantity amount of substance) has non-trivial physical dimension and therefore is not just a number under the current SI definition. The argument made here is that it would be more natural to define it as being dimensionless.
 
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  • #60
The SI is not supposed to provide "natural units" but well-defined precise units that can be reproduced everywhere (by assumption of the cosmological principle even everywhere in the entire universe) to be used FAPP under everyday circumstances.

According to the definition 1 mole is the amount of substance consisting of a specific number of entities (relevant degrees of freedom I'd translate it). That's why the Avogradro number in the SI has the dimension 1/mol, i.e., you have ##\simeq 6 \cdot 10^{23}## entities per mole.
 
  • #61
vanhees71 said:
The SI is not supposed to provide "natural units" but well-defined precise units that can be reproduced everywhere (by assumption of the cosmological principle even everywhere in the entire universe) to be used FAPP under everyday circumstances.

According to the definition 1 mole is the amount of substance consisting of a specific number of entities (relevant degrees of freedom I'd translate it). That's why the Avogradro number in the SI has the dimension 1/mol, i.e., you have ##\simeq 6 \cdot 10^{23}## entities per mole.
The dimension of Avogadro's number is 1/N, not 1/mol. The mole is a unit for quantities of dimension N.

But this is completely irrelevant to the issue of whether the mole should be dimensionful or not, it is the same whether or not [mol] = N or [mol] = 1.
 
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  • #62
Well, in the SI the electric charge has a dimension, though the natural dimension is 1. Read the official text: The Avogadro number in the SI has the dimension 1/mol. In natural units the Avogadro number is simply the above quoted number, i.e., it's dimensionless.

The same is true for angles: I'm not sure what's the status in the SI. I remember there was some debate concerning angles and solid angles, i.e., whether you should write rad or sr in the sense of units. If you do so, angles and solid angles get a dimension of rad or sr, respectively though the natural measure is again dimensionless.

You can, in principle, drive it to the extreme of using Planck units (in various variants around in the literature), which is only not done, because the Gravitational Constant is so difficult to be measured accurately. Then everything is dimensionless, and you have no more units for any quantity.
 
  • #63
vanhees71 said:
The Avogadro number in the SI has the dimension 1/mol
I suggest you read the official document where it is made clear that mol is a unit of dimension N (amount of substance), it is not a dimension in and of itself. Saying that something has dimensions of mol is like saying that a distance has dimensions of meters (it does not, it has dimensions of length L). This is described in section 2.3.3 of the SI brochure. Units are not the same thing as physical dimension although the concepts are somewhat related.

vanhees71 said:
The same is true for angles: I'm not sure what's the status in the SI. I remember there was some debate concerning angles and solid angles, i.e., whether you should write rad or sr in the sense of units. If you do so, angles and solid angles get a dimension of rad or sr, respectively though the natural measure is again dimensionless.
Angles are dimensionless in the SI so the situation is not equivalent. Again, there is a distinction between the physical dimension and the units used to describe quantities of those dimensions.

vanhees71 said:
Then everything is dimensionless, and you have no more units for any quantity.
This is not entirely true. You can still express a meter in Planck units. It would just be a number used to relate to other numbers, much like mol would be a number used to relate to other numbers if you define amount of substance to be dimensionless.
 
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  • #64
Interesting, I guess I've to read the bruchure again.

But why then do they write
$$N_A=6.xxx \cdot 10^{23} \frac{1}{\text{mol}}$$
oif ##\text{mol}## had the dimension of ##N## (which dimension is in fact 1). That's very confusing. Maybe I get something wrong here.

But let's take the "natural units" used in HEP physics. There you have ##\hbar=c=k_{\text{B}}=1##. Then everything is measured in principle using only one unit, e.g., GeV. In addition for some quantities one uses fm. The conversion is simply ##1 fm \simeq \frac{0.197}{\mathrm{GeV}}##.

Maybe I'm using the expression "dimension" wrong, but which dimension a quantity takes, depends on the system of units used, i.e., in the HEP natural units masses, energies, momenta, and temperatures have the same dimension. The same holds for lengths and times. Velocities are dimensionless.

Another example is electromagnetism, where the quantities have different dimensions depending on whether you use Gaussian/Heaviside Lorentz or SI units. In Gaussian or Heaviside units the components ##\vec{E}## and ##\vec{B}## of the electromagnetic field-strength tensor take the same dimension, while they are different in the SI. The reason is that in the SI an additional unit for electric charge, C (or equivalently electric current, the Ampere) is introduced, which enforces the introduction of one more conversion factor, ##\mu_0## in addition to ##c##, which is used in Gaussian and Heaviside units es well.

In Planck units all quantities would have the same dimension, namely 1, i.e., all quantities are dimensionless.

Of course, you can also specify "dimensions" independent from units. Is it this sense the SI brochure uses the word "dimension"? Than it's clear that I used the wrong meaning in context of the SI.
 
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  • #65
Somewhat tangentially related to the recent discussion. Perhaps a chemist can answer.

For mass it makes sense to add a kg of glucose and a kg of NaCl to get a total mass. Would you ever add a mol of glucose to a mol of NaCl to get a total amount of substance?

Or if you add 1 mol of Na and 1 mol of Cl would you ever say you had 2 mol of anything?
 
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  • #66
Well, my chemistry is quite rusty, but wouldn't I get some Na, Cl but also NaCl? I'd say I've less than 2 moles of substance, depending on the conditions. For full equilibrium the question, how many moles I get is answered by the mass-action law.

Then the issue with mass is also not that trivial. According to relativity mass is not conserved, i.e., if you have an exothermic (endothermic) reaction your total mass gets smaller (larger) by the amount ##\delta Q/c^2## (the true meaning of the most misunderstood but most famous formula of physics ##E=mc^2##). In chemistry that's of course usually negligible, not so in nuclear reaction like fission!
 
  • #67
Dale said:
Somewhat tangentially related to the recent discussion. Perhaps a chemist can answer.

For mass it makes sense to add a kg of glucose and a kg of NaCl to get a total mass. Would you ever add a mol of glucose to a mol of NaCl to get a total amount of substance?

Or if you add 1 mol of Na and 1 mol of Cl would you ever say you had 2 mol of anything?
I admit I was a floating voter here, but this post suggests to me that the dimensions of a mole, if it is to make any sense, must be different for every substance.

If you have a mole of oranges, then either you have a dimensionless number of you have a unit of orange.

This SI unit of "a number of whatever thing you are talking about" seems to me neither one thing nor the other.

What's the counterargument?
 
  • #68
vanhees71 said:
Well, my chemistry is quite rusty, but wouldn't I get some Na, Cl but also NaCl? I'd say I've less than 2 moles of substance, depending on the conditions. For full equilibrium the question, how many moles I get is answered by the mass-action law.

Then the issue with mass is also not that trivial. According to relativity mass is not conserved, i.e., if you have an exothermic (endothermic) reaction your total mass gets smaller (larger) by the amount ##\delta Q/c^2## (the true meaning of the most misunderstood but most famous formula of physics ##E=mc^2##). In chemistry that's of course usually negligible, not so in nuclear reaction like fission!
I'm not convinced. In principle you can add lengths or masses. A physical process may not support simple addition, but that's not the issue. Another example would be relativistic velocity addition. It's not simple addition, but you can manipulate velocities mathematically regardless of what's moving.

You can't in principle add moles of different things, which suggests (to me anyway) it's not the same unit in each case.
 
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  • #69
vanhees71 said:
But why then do they write

NA=6.xxx⋅10231molNA=6.xxx⋅10231mol​

N_A=6.xxx \cdot 10^{23} \frac{1}{\text{mol}}
oif molmol\text{mol} had the dimension of NNN (which dimension is in fact 1). That's very confusing. Maybe I get something wrong here.
In the SI Avogadro’s number is dimensionful. If you would instead make amount of substance dimensionless, 1 mol would be exactly the number that the SI currently defines as the avogadro number’s measured value in 1/mol. The Avogadro number is then just a conversion factor with value 1 just like c in natural units but it is still 1 = 6.xxxe23 / mol.

vanhees71 said:
Maybe I'm using the expression "dimension" wrong, but which dimension a quantity takes, depends on the system of units used, i.e., in the HEP natural units masses, energies, momenta, and temperatures have the same dimension. The same holds for lengths and times. Velocities are dimensionless.
Sure, it is a matter of convention what you give physical dimension to. The argument here is that it is more natural not to give amount of substance a physical dimension contrary to the SI convention. Much similar to it being natural to have dimensionless velocities in natural units.

vanhees71 said:
Of course, you can also specify "dimensions" independent from units. Is it this sense the SI brochure uses the word "dimension"? Than it's clear that I used the wrong meaning in context of the SI.
The SI brochure first defines all of the units and then define the physical dimensions used by stating that each base unit has its own independent physical dimension. This was by no means necessary. The SI could just has well just have defined meters and seconds to be different units for length, which would make velocities dimensionless but have c as a dimensionless conversion factor.
 
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  • #70
Dale said:
Somewhat tangentially related to the recent discussion. Perhaps a chemist can answer.

For mass it makes sense to add a kg of glucose and a kg of NaCl to get a total mass. Would you ever add a mol of glucose to a mol of NaCl to get a total amount of substance?

Or if you add 1 mol of Na and 1 mol of Cl would you ever say you had 2 mol of anything?
That two numbers have the same physical dimension is a prerequisite for an addition to make sense. However, there is no guarantee that having the same physical dimension implies that the sum makes sense. For this, we need modelling.

Example: The x- and y-components of velocity ##v_x## and ##v_y##, respectively. The sum ##v_x + v_y## makes little physical sense. However, ##\sqrt{v_x^2 + v_y^2}## does have a physical meaning as the total speed.
 
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<h2>1. When was the definition of the meter changed?</h2><p>The definition of the meter was changed on May 20, 2019.</p><h2>2. Why was the definition of the meter changed?</h2><p>The definition of the meter was changed to align with the International System of Units (SI) and to provide a more precise and consistent measurement.</p><h2>3. What was the previous definition of the meter?</h2><p>The previous definition of the meter was based on a physical object, the International Prototype of the Meter, which was a platinum-iridium bar stored in Paris, France.</p><h2>4. What is the new definition of the meter?</h2><p>The new definition of the meter is based on the speed of light in a vacuum, which is a fixed and measurable constant.</p><h2>5. How does the new definition of the meter affect scientific measurements?</h2><p>The new definition of the meter allows for more accurate and consistent measurements, as it is based on a fundamental constant of nature. This will help advance scientific research and technology in various fields.</p>

1. When was the definition of the meter changed?

The definition of the meter was changed on May 20, 2019.

2. Why was the definition of the meter changed?

The definition of the meter was changed to align with the International System of Units (SI) and to provide a more precise and consistent measurement.

3. What was the previous definition of the meter?

The previous definition of the meter was based on a physical object, the International Prototype of the Meter, which was a platinum-iridium bar stored in Paris, France.

4. What is the new definition of the meter?

The new definition of the meter is based on the speed of light in a vacuum, which is a fixed and measurable constant.

5. How does the new definition of the meter affect scientific measurements?

The new definition of the meter allows for more accurate and consistent measurements, as it is based on a fundamental constant of nature. This will help advance scientific research and technology in various fields.

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