Small=high mass at quantum level, but big=high mass at classical level. Why?

In summary, at a classical physics level, physically big equates to big mass, but at the sub-atomic level, small seems to equate to big mass due to the different approaches to understanding density and energy in classical and quantum physics. Additionally, the behavior of particles at the quantum level is not as intuitive as at the classical level. When considering multiple particles, the total energy and length scale differently depending on whether the particles are fermions or bosons, leading to the observed contrast in size and mass at the sub-atomic level.
  • #1
SteveinLondon
10
0
At a classical physics level, physically big equates to big mass, but at the sub-atomic level, small seems to equate to big mass i.e. (short wavelength big mass relationship. "momentum=h/wavelength"). Any ideas why there is this complete contrast?
 
Physics news on Phys.org
  • #2
because all subatomic particles have (roughly) the same angular momentum (ħ)

http://en.wikipedia.org/wiki/Bohr_model

7b15bb0e886212c070b6b20d8f7eeb89.png


so radius is inversely proportional to mass
 
Last edited:
  • #3
granpa said:
because all subatomic particles have the same angular momentum (ħ)

No they don't.

If you don't know the answer, it's not necessary to reply.
 
  • #4
In classical physics you have an intuition that all objects have constant density. So bigger size with the same density yields bigger mass.

In quantum physics "density" is not constant. You rather have some constant amount of something (aether, waves) and you squeeze it. The classical intuition would be that the mass of a squeezed body remains constant, but from special relativity you get that the energy of the body gets higher. And higher energy means higher mass.

Those two approaches can be considered at the same time. You get then the balance between classical and quantum physics. This yields the definition of Planck mass and the Bekenstein bound.
 
  • #5
SteveinLondon said:
At a classical physics level, physically big equates to big mass, but at the sub-atomic level, small seems to equate to big mass i.e. (short wavelength big mass relationship. "momentum=h/wavelength"). Any ideas why there is this complete contrast?
It is not so much classical vs quantum, but rather one vs many particles. For one quantum particle, smaller length x means more energy e, as you said. But if you have MANY (say N) such small particles at DIFFERENT positions, then total energy and total length scale like
E=Ne
X=Nx
so bigger N means both bigger E and bigger X.
 
  • #6
Demystifier said:
It is not so much classical vs quantum, but rather one vs many particles. For one quantum particle, smaller length x means more energy e, as you said. But if you have MANY (say N) such small particles at DIFFERENT positions, then total energy and total length scale like
E=Ne
X=Nx
so bigger N means both bigger E and bigger X.
But if you use DeBroglie's wave/particle formula on a large object, say a rock, you get momentum=h/wavelength, so a big rock, at the same speed as a little rock, has bigger momentum yet smaller wavelength - yet it's made up from more than one particle.
 
  • #7
Becuase on a quantum-level, the universe isn't intuitive?
 
  • #8
SteveinLondon said:
But if you use DeBroglie's wave/particle formula on a large object, say a rock, you get momentum=h/wavelength, so a big rock, at the same speed as a little rock, has bigger momentum yet smaller wavelength - yet it's made up from more than one particle.
Yes, but it is incorrect to apply the DeBroglie's wave/particle formula on an object consisting of many particles. For example, the nucleus of an atom is very small (much smaller than the atom itself), and yet a heavier nucleus is bigger than a lighter one. That's because the nucleus consists of many particles.

More precisely, it is not enough to have many particles. In addition, these particles must be FERMIONS (which protons and neutrons in the nucleus are), so that you cannot put all them at the same place.

If you have BOSONS (e.g., photons), then you can put many of them in the same state, so with a fixed wavelength (fixed energy of one particle) the size of N bosons may not depend on the total energy of N particles.
 

1. Why does small size equate to high mass at the quantum level?

The concept of "mass" at the quantum level is not the same as the classical definition of mass. At the quantum level, particles are described by wave functions and have both wave-like and particle-like properties. The mass of a particle in this context is related to its energy and momentum, which can be affected by its size. Therefore, smaller particles with higher energies can have a higher mass at the quantum level.

2. How does classical physics explain high mass for larger objects?

Classical physics follows the laws of Newtonian mechanics, where mass is a property of matter that is independent of its size. In this framework, the mass of an object is constant and does not change with size. This is why larger objects have a higher mass in the classical sense.

3. What causes the change in mass between the quantum and classical levels?

The change in mass between the quantum and classical levels is due to how mass is defined and understood in each framework. In classical physics, mass is a constant property of matter, while in quantum mechanics, it is a more complex and dynamic concept that takes into account the energy and momentum of particles.

4. Can we observe this difference in mass between the quantum and classical levels?

Yes, we can observe the difference in mass between the quantum and classical levels through experiments and observations. For example, the mass of an electron in its ground state is different from its mass when it is in an excited state, which can be observed through spectroscopy. Similarly, the mass of a macroscopic object can be measured using classical methods and compared to its mass at the quantum level.

5. How does the concept of mass at the quantum level affect our understanding of the universe?

The concept of mass at the quantum level has played a crucial role in our understanding of the universe. It has helped us explain and predict the behavior of subatomic particles and has led to groundbreaking discoveries in the fields of quantum mechanics and particle physics. Additionally, it has also contributed to our understanding of the structure of matter and the fundamental forces that govern the universe.

Similar threads

B Frequency of an EM wave in Classical and Quantum Physics
    • Quantum Physics
Replies
6
Views
809
B Relationship between a material wave and the uncertainty of position and momentum
    • Quantum Physics
Replies
11
Views
820
I Frequency of EM waves in classical and quantum physics
    • Quantum Physics
Replies
26
Views
2K
A How useful are quantum-classical hybrid theories?
    • Quantum Physics
Replies
5
Views
1K
I Electromagnetic radiation, photons, quantized energy levels
    • Quantum Physics
Replies
1
Views
354
Insights The Classical Limit of Quantum Mechanical Commutator
    • Quantum Physics
Replies
8
Views
2K
I Does an electron have a quantum phase frequency?
    • Quantum Physics
2
Replies
36
Views
2K
A Renormalization (Electron self energy)
    • Quantum Physics
Replies
4
Views
2K
B Exploring Solids: Classical Physics & Quantum Mechanics
    • Quantum Physics
Replies
3
Views
980
A Cause of spontaneous emission?
    • Quantum Physics
Replies
15
Views
2K

Hot Threads

Recent Insights

Back
Top