Understanding Mass & Resistance: Basics Explained

In summary, there are two types of mass: inertial mass, which is just like you described it, resistance to change in speed, and gravitational mass, which is the magnitude of the gravitational force an object exerts and experiences.
  • #1
nouveau_riche
253
0
well i am trying to understand the basic of mass and i got myself into a deadlock of questions
firstly the definition of mass as i know is :quantitative measure of an object's resistance to the change of its speed.

assumption:particle have charge but no mass and they just fall into the significant field of each other,there is nothing they interact with except each other and a force F.

now consider a situation where a particle with charge say -q comes into significant field influence of another particle with charge +Q,it then follow a particular path P,suppose a force F is used to the bring a change in path of -q,the force F does so in two ways:at first it tries to change the path of -q by change it's state of motion(either by accelerating or deceleration him) ,thus the resistance offered to F relative to him appeared because of the electromagnetic interaction between the charges.
In the second case the force F tries to change the trajectory of -q but by not changing it's state of motion(maintaining it's velocity),in this case also the resistance offered was due to the electromagnetic interaction.

so according to the definition of mass the resistance offered in first scenario should add to mass but not second,though it can be clearly seen that the resistance offered is because of the electromagnetic interaction under action.

SO WHAT IS WRONG WITH THE PICTURE DEPICTED?
 
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  • #2
nouveau_riche said:
well i am trying to understand the basic of mass and i got myself into a deadlock of questions
firstly the definition of mass as i know is :quantitative measure of an object's resistance to the change of its speed.

There are two "types" of mass. The first, inertial mass, is just like you described it, resistance to change in speed. The second is gravitational mass, which is the magnitude of the gravitational force an object exerts and experiences.
now consider a situation where a particle with charge say -q comes into significant field influence of another particle with charge +Q,it then follow a particular path P,suppose a force F is used to the bring a change in path of -q,the force F does so in two ways:at first it tries to change the path of -q by change it's state of motion(either by accelerating or deceleration him) ,thus the resistance offered to F relative to him appeared because of the electromagnetic interaction between the charges.

No, the charge on the particles causes a force to be felt on each of them. It does not cause a resistance. It is the mass of the particles that causes them to resist the force applied and thus taking time to accelerate. (A particle of zero mass would accelerate instantly to infinite speed)
 
  • #3
The word "resistance" is not the best one to use because that implies dissipating / losing energy - as with electrical resistance. A better word would be "reaction against", which also ties in with Newton's Third Law - 'Action and reaction are equal and opposite'.

Also, you may find it easier to talk of purely mechanical forces (pulling with a force meter or string) so that we don't get bogged down with electric forces, which is just adding more complication because the Coulomb force depends upon separation.

I can't actually see the distinction between your two scenarios. If you are trying to change a particle's "state of motion" then you need to apply a force, by some means or another. Acceleration is a rate of change of Velocity, which is a vector quantity, in which direction and magnitude are both important.
f=ma does not distinguish between change of speed or change of direction. The existence of mass will be equally apparent if either quantities is changed.
 
  • #4
Drakkith said:
There are two "types" of mass. The first, inertial mass, is just like you described it, resistance to change in speed. The second is gravitational mass, which is the magnitude of the gravitational force an object exerts and experiences.
No, the charge on the particles causes a force to be felt on each of them. It does not cause a resistance. It is the mass of the particles that causes them to resist the force applied and thus taking time to accelerate. (A particle of zero mass would accelerate instantly to infinite speed)

the electromagnetic force causing an opposition to force F will be measured as resistance,what you suggest applies well to object that has mass,but in the situation i gave you the particles have no mass initially they just have started to feel the field of the other one
or what i mean to speak of is inertial mass of particles observed knowing the fact that before the moment of observation they were mass less
 
  • #5
sophiecentaur said:
I can't actually see the distinction between your two scenarios. If you are trying to change a particle's "state of motion" then you need to apply a force, by some means or another. Acceleration is a rate of change of Velocity, which is a vector quantity, in which direction and magnitude are both important.
f=ma does not distinguish between change of speed or change of direction. The existence of mass will be equally apparent if either quantities is changed.

i am applying a force F as mentioned
 
  • #6
nouveau_riche said:
i am applying a force F as mentioned
Sorry, I am looking for a 'distinction'. That answer has only 'one side' to it. CAn you explain the difference?
 
  • #7
nouveau_riche said:
the electromagnetic force causing an opposition to force F will be measured as resistance,what you suggest applies well to object that has mass,but in the situation i gave you the particles have no mass initially they just have started to feel the field of the other one
or what i mean to speak of is inertial mass of particles observed knowing the fact that before the moment of observation they were mass less

If there is no mass then there will be no force - the movement will be instantaneous and can't be discussed in the context of Mass. I think you may be making some implied assumptions in the model you have in your head.
 
  • #8
sophiecentaur said:
If there is no mass then there will be no force - the movement will be instantaneous and can't be discussed in the context of Mass. I think you may be making some implied assumptions in the model you have in your head.

you are still missing the electromagnetic interactions(giving an perception of force)
 
  • #9
nouveau_riche said:
you are still missing the electromagnetic interactions(giving an perception of force)

But even the effects of "electromagnetic interactions" depend on mass, F=ma hold regardless of what is the cause of F, if there is no mass there can't be a force,
 
  • #10
f95toli said:
But even the effects of "electromagnetic interactions" depend on mass, F=ma hold regardless of what is the cause of F, if there is no mass there can't be a force,

suppose there are two particles(mass less but have charge)
when they just start to interact,describe the situation
 
  • #11
You cannot deal with massless particles in the framework of Newtonian Mech. If there is ANY net force, and mass is zero, there would need to be infinite acceleration. That is silly when dealing with classical mechanics, but you can probably convince yourself the a massless particle, when considered in the framework of relativity, would move at the speed of light.

so according to the definition of mass the resistance offered in first scenario should add to mass but not second,though it can be clearly seen that the resistance offered is because of the electromagnetic interaction under action.

Lets pretend the particle is not massless, but instead has very little mass.
There is no "resistance" from the EM interaction, just another force. The "resistance" to acceleration from mass is intrinsic and is called inertia. The EM interaction is an external force that will accelerate the particle, not keep it moving at constant speed.

Note that you don't have mass because you are on Earth in a gravitational field. You have mass no matter where in the universe you are. Your inertia is the same if you were speeding along through empty space, but when on earth, there is also a force (which oddly is also proportional to your mass) that keeps you on the surface of earth.

There is no answer to your question, but I hope this clears up why there is no answer.
 
  • #12
DrewD said:
You cannot deal with massless particles in the framework of Newtonian Mech. If there is ANY net force, and mass is zero, there would need to be infinite acceleration. That is silly when dealing with classical mechanics, but you can probably convince yourself the a massless particle, when considered in the framework of relativity, would move at the speed of light.



Lets pretend the particle is not massless, but instead has very little mass.
There is no "resistance" from the EM interaction, just another force. The "resistance" to acceleration from mass is intrinsic and is called inertia. The EM interaction is an external force that will accelerate the particle, not keep it moving at constant speed.

Note that you don't have mass because you are on Earth in a gravitational field. You have mass no matter where in the universe you are. Your inertia is the same if you were speeding along through empty space, but when on earth, there is also a force (which oddly is also proportional to your mass) that keeps you on the surface of earth.

There is no answer to your question, but I hope this clears up why there is no answer.

so according to you there should be no place for any mass less charged particle?
 
  • #13
so according to you there should be no place for any mass less charged particle?

No: Massless particles cannot be dealt with in classical mechanics.
 
  • #14
nouveau_riche said:
the electromagnetic force causing an opposition to force F will be measured as resistance,what you suggest applies well to object that has mass,but in the situation i gave you the particles have no mass initially they just have started to feel the field of the other one
or what i mean to speak of is inertial mass of particles observed knowing the fact that before the moment of observation they were mass less

No, you are adding TWO forces to the issue, not just one. This is covered in classical physics. You have to find the magnitude and vector of the net force from adding the two forces and their vectors together.
 
  • #15
DrewD said:
No: Massless particles cannot be dealt with in classical mechanics.

and if you go outside classical mechanics?
 
  • #16
Drakkith said:
No, you are adding TWO forces to the issue, not just one. This is covered in classical physics. You have to find the magnitude and vector of the net force from adding the two forces and their vectors together.

then how is the mass of a quantum particle measured?
 
  • #17
nouveau_riche said:
and if you go outside classical mechanics?

You need to use some fairly advanced QM, such as the Dirac equation.

That said, there are as far as we know no charged, massless, particles. The only thing I can think of that comes close is e.g. quasiparticles in graphene (which are described by the Dirac equation), but they are of course not "real" particles.
 

FAQ: Understanding Mass & Resistance: Basics Explained

1. What is mass and resistance?

Mass is a measure of the amount of matter in an object, while resistance is a measure of how difficult it is for electric current to flow through a material.

2. How are mass and resistance related?

Mass and resistance are not directly related. However, an object with a larger mass may have a greater resistance to movement or acceleration, and a material with a higher resistance may impede the flow of electric current more.

3. How is mass measured?

Mass is typically measured by using a scale or balance that compares the weight of an object to a known standard, such as the weight of a kilogram or pound.

4. How is resistance measured?

Resistance is measured in units called ohms (Ω) using a device called an ohmmeter. The ohmmeter sends a small current through the material and measures the voltage drop across it to determine the resistance.

5. How does mass and resistance affect everyday life?

Mass and resistance play important roles in many aspects of our daily lives. For example, mass affects how much effort is needed to move an object, and resistance can impact the performance of electronic devices. Understanding these concepts can help us make informed decisions and solve problems in various situations.

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