Buckleymanor said:How do they extract the mass .What do they scale it against if gravity is a non- entity.Do they imagine a figure and divide by five.
Surely they must have a baseline derived from the effects of gravity which makes little sense of your argument.
ZapperZ said:Start with something simpler. Look up that e/m experiments that I had mentioned (googling it will give you several). Now where is gravity involved in those? Note that these are experiments that are typical for undergraduate intro physics courses, so it is not THAT exotic and unfamiliar.
Zz.
Charge and Mass of the Electron 7
Consider a latex sphere of mass m and charge q, falling under the influence of
gravity between two horizontal plates. In falling, the sphere is subjected to an opposing
force due to air resistance. The speed of the sphere quickly increases until a constant
terminal speed is reached, at which time the weight of the sphere, mg, minus the buoyant
force is exactly equal to the air resistance force. The value of the air resistance force on a
sphere was first derived by Sir George Stokes and is given as 6 π η r s where η is the
coefficient of viscosity of air, r is the radius of the sphere and s is its terminal speed. If
the buoyant force of the air is neglected, the equation of motion of the sphere is:
mg − 6πηrs = 0
So buoyancy can be ignored.I don't see how gravity is however.ZapperZ said:Er... No. You are looking at the oil drop experiment! The e/m experiment done with Helmholtz coil is done inside an evacuated vacuum. There is no buoyancy in vacuum.
http://wanda.fiu.edu/teaching/courses/Modern_lab_manual/em_ratio.html
Zz.
What do you compare your magnetic field with to allow it to have a magnitude.The field exerts a magnetic force with a magnitude of
Buckleymanor said:So buoyancy can be ignored.I don't see how gravity is however.
What do you compare your magnetic field with to allow it to have a magnitude.
You could say other magnetic fields but ultimately you arrive at the pull of gravity.
And you won't answer the question and are being extreamly obtuse.It's been put to you a number of times that whatever device is used to measure the mass of an electron.Gravity plays a part in the calculation.ZapperZ said:You last statement is a guess work. Since when do I need gravity to determine magnetic field strength? I can even just calculate it! You obviously have not understood the physics behind the experiment.
Next time, please cite the theory to back your claim. This is no longer making any sense and you are just shooting in the dark.
Zz.
Do your calculations ignore field strenth or as stated before do you imagine a figure and divide by five.Beam of electrons moving in a circle in a Teltron tube, due to the presence of a magnetic field. Purple light is emitted along the electron path, due to the electrons colliding with gas molecules in the bulb. The mass-to-charge ratio of the electron can be measured in this apparatus by comparing the radius of the purple circle, the strength of the magnetic field, and the voltage on the electron gun. The mass and charge cannot be separately measured this way—only their ratio.
Sounds like nonsense. Reference please? I'd love to see how gravity affects the calculation.Buckleymanor said:It's been put to you a number of times that whatever device is used to measure the mass of an electron.Gravity plays a part in the calculation.
Well, there you go. Is it negligible or not?It might be negligable as a physical quantity far as particles are concerned because of there very small mass.
There are other, much stronger, forces involved.As far as calculating the electrons mass how can you do it without reference to gravity and field strength.
Buckleymanor said:And you won't answer the question and are being extreamly obtuse.It's been put to you a number of times that whatever device is used to measure the mass of an electron.Gravity plays a part in the calculation.
It might be negligable as a physical quantity far as particles are concerned because of there very small mass.
As far as calculating the electrons mass how can you do it without reference to gravity and field strength.
Do your calculations ignore field strenth or as stated before do you imagine a figure and divide by five.
My magnet has a pull of five pounds what does yours have?
Calm down souds like I have trod on a nerve.ZapperZ said:This is silly. Look at the experiment. I've not only done it, I've taught it! Where exactly does gravity comes in? You said it comes in the calculation. WHERE EXACTLY?
I could do this experiment in outer space. How would the experiment be any different? The e/m values can't be decoupled in this experiment. So what? It still doesn't mean gravity is necessary to do the experiment. I can determine the magnetic field strength using a gauss probe or calculate the field strength using the geometry of the coil and the current. Where is gravity here? Will the field change if I do this in the ISS? Really?
The experiment I showed contains NO g in the physics. Go ahead and look! Unless you can show me THEORETICALLY where this value comes in EXPLICITLY, then I have no more interest in trying to either educate you, or correct this faulty knowledge. It is no longer of any concern to me that you believe in a wrong set of information. I've tried all I can to correct it, so I'm done.
Zz.
You give the mass a value what exactly is that value related to.If it has no relation then it has no value.Doc Al said:Sounds like nonsense. Reference please? I'd love to see how gravity affects the calculation.
ProbablyWell, there you go. Is it negligible or not?
But that does not mean gravity does not exist.There are other, much stronger, forces involved.
So you don't need a test mass to start with.mfb said:@Buckleymanor: All experiments that are done with gravity can be done in a centrifuge in space.
And you don't need the oil drop experiment. Atom counting and electrolysis are another approach to get the Avodradro constant and the elementary charge.
The elementary charge is indeed an important quantity if you want to know particles masses in kg (note that this is not necessary), but you don't need gravity to measure it.
Buckleymanor said:Calm down souds like I have trod on a nerve.
But can't see why.
You could do the experiment in outer space but you would still be taking your values with you.
What I would like to know but realize it's probably too sensitive to ask is in when you calculate your field strength useing whatever method available what is the strength be related to and why only that.
Dumb as I am, I can relate it the amount of effort against the force of gravity.
The amount of pull or push an e/m field has can be related to weight.How were field strengths expressed when first discovered.
Why is this a problem to your sensitivities?
I am probably just as dumb in not apreciating the terminology and classification of the subject but can't see for the life of me how the field strength has no relation to g and why you should wan't to divorce it from the calculation with such agression.
Does it not sit well with a more explicite explanation. Or is it wrong to ask.