What does a quantum state represent in quantum theory?

In summary, the conversation discusses the concept of energy quantization and its relation to the Einstein-Planck equation. It is mentioned that if a photon could have any frequency, energy would not be quantized. The discussion also touches on the minimum value of energy and the idea of photons as quanta of energy or amplitude. It is clarified that quantization conditions are constraints on the amplitude of the wave, not the frequency or energy of the individual photon. The conversation ends with some confusion about the relationship between energy and photon number.
  • #1
jaumzaum
434
33
Everybody says energy is quantized. But for einstein-plank equation
E = h.f

If a photon could have any values of f, E would not be quantized
I know bohr orbits only accept some frequencies, but hydrogen frequencies are different from lithium or nytrogen frequencies. So what is the MINIMUM value of E? As far as I know, a photon is a quanta of energy, so what would be the quantum?
 
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  • #2
The energy in general can be arbitrary, because you can choose arbitrary frequency. But if you decide to work with one specific frequency fchosen, then h*fchosen is the quantum of that specific frequency.
 
  • #3
Also please note one thing: the fact that only certain photons (with specific energies) can be emitted / absorbed by an atom, is not limiting the possible photon energies. The atomic energy levels are features of these atoms, but electromagnetic field does not care about that. The free e-m field can have any frequency. It is just that only certain frequencies will be absorbed by atoms, while other photons will not be affected.
 
  • #4
mpv_plate said:
The energy in general can be arbitrary, because you can choose arbitrary frequency. But if you decide to work with one specific frequency fchosen, then h*fchosen is the quantum of that specific frequency.

is there no minimum value for the quantum?
or
is frequency quantized?
or
does quantization only make sense when in a bounded state at a specific orbital/energy level/shell in an atom?
 
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  • #5
jaumzaum said:
Everybody says energy is quantized. But for einstein-plank equation
E = h.f

If a photon could have any values of f, E would not be quantized
I know bohr orbits only accept some frequencies, but hydrogen frequencies are different from lithium or nytrogen frequencies.
I am not sure what you are talking about. You are talking about different elements. So what you wrote sounds like a contradiction.

What are the "hydrogen frequencies" of "lithium" and nitrogen?

jaumzaum said:
So what is the MINIMUM value of E?
There is a minimum value for particle number for fixed values of frequency, volume and total energy. There is also a minimum amplitude of the wave for fixed values of frequency, volume and total energy. There is no absolute value for minimum energy. If you want a smaller total energy, then you can increase the frequency and decrease the volume.
jaumzaum said:
As far as I know, a photon is a quanta of energy, so what would be the quantum?
The photon is generally defined as a quanta of energy. However, that definition is a little ambiguous. When working through the mathematics, I have found it more useful to think of the photon as a quantum of amplitude. The amplitude of the wave is forced to be discrete because the number of particles is discrete. Thus, the de Broglie relations (which includes the Einstein-Planck relation) should be thought of as constraints on the amplitude of the wave.

The two definitions for "photon" often give the same final results. There is usually little experimental difference in the photon being a quantum of energy and a photon being a quantum of amplitude. However, there is a shade of difference that occasionally causes confusion especially when one counts photons.

One thing that is unclear from introductory courses in quantum mechanics is that the number of particles can be uncertain. The total energy of a wave is often precisely determined even though the frequency is not. Therefore, an uncertainty in photon energy is often manifested as an uncertainty in photon number.


"Quantization conditions" are actually constraints on the amplitude of the wave associated with the particle. They don't constrain the frequency of the wave nor do they constrain the energy of each individual photon. So there is no absolute minimum in photon energy.

The number density of particles associated with a wave increases with the square of the amplitude of the wave. The total energy is proportional to the number of particles. The number of particles is basically the total energy of the wave divided by the energy of each particle. The total energy of the wave is proportional to the amplitude squared. The Einstein-Planck equation only determines the energy density for each type of each particle. The Einstein-Planck equation does not determine the total energy of the wave. I don't fully understand your question, but maybe I partially understand the general confusion. I conjecture that your confusion concerns issues of amplitude and photon number.

Does this sound like it could be the problem?
 
  • #6
Darwin123 said:
I am not sure what you are talking about. You are talking about different elements. So what you wrote sounds like a contradiction.

What are the "hydrogen frequencies" of "lithium" and nitrogen?


There is a minimum value for particle number for fixed values of frequency, volume and total energy. There is also a minimum amplitude of the wave for fixed values of frequency, volume and total energy. There is no absolute value for minimum energy. If you want a smaller total energy, then you can increase the frequency and decrease the volume.



The photon is generally defined as a quanta of energy. However, that definition is a little ambiguous. When working through the mathematics, I have found it more useful to think of the photon as a quantum of amplitude. The amplitude of the wave is forced to be discrete because the number of particles is discrete. Thus, the de Broglie relations (which includes the Einstein-Planck relation) should be thought of as constraints on the amplitude of the wave.

The two definitions for "photon" often give the same final results. There is usually little experimental difference in the photon being a quantum of energy and a photon being a quantum of amplitude. However, there is a shade of difference that occasionally causes confusion especially when one counts photons.

One thing that is unclear from introductory courses in quantum mechanics is that the number of particles can be uncertain. The total energy of a wave is often precisely determined even though the frequency is not. Therefore, an uncertainty in photon energy is often manifested as an uncertainty in photon number.


"Quantization conditions" are actually constraints on the amplitude of the wave associated with the particle. They don't constrain the frequency of the wave nor do they constrain the energy of each individual photon. So there is no absolute minimum in photon energy.

The number density of particles associated with a wave increases with the square of the amplitude of the wave. The total energy is proportional to the number of particles. The number of particles is basically the total energy of the wave divided by the energy of each particle. The total energy of the wave is proportional to the amplitude squared.


The Einstein-Planck equation only determines the energy density for each type of each particle. The Einstein-Planck equation does not determine the total energy of the wave. I don't fully understand your question, but maybe I partially understand the general confusion. I conjecture that your confusion concerns issues of amplitude and photon number.

Does this sound like it could be the problem?

Yeah. Actually the question was if a single photon energy was quantized, and as you and mpv_plate said, it is not, cause a single photon can have any frequency.

But I still have a question. I mentioned the hydrogen, lithium and nitrogen frequencies as the energy levels for these atoms. As there are a finite number of elements in the periodic table, there have to be a finite number of energy levels as well as a finite number of frequencies that can be absorbed or emitted by an atom. So by that I thought frequency was quantized too. But as mpv_plate said, that works only for atoms. And the em field can have any frequency. So here is the question: How can we produce an electromagnetic wave not being by an electron jumping to another electron shell/energy level and emitting a photon? Is there any other method to do that?
 
  • #7
San K said:
is there no minimum value for the quantum?
or
is frequency quantized?
or
does quantization only make sense when in a bounded state at a specific orbital/energy level/shell in an atom?

For electromagnetic field, there is no minimum value of energy, but there is minimum value for amplitude. (However, if you study the quantum field theory deeper, this becomes more complicated)

Frequency is not quantized. You can have any frequency.

Bound states tend to be quantized in energy, because they may impose constraints on the possible states.

Another example: you can activate a wave in electromagnetic field inside a small metal box. You cannot have any photon (any frequency) in the box, because only specific (discrete) frequencies can fit in the constrained space.
 
  • #8
jaumzaum said:
there have to be a finite number of energy levels as well as a finite number of frequencies that can be absorbed or emitted by an atom.

No: even a hydrogen atom has an infinite number of energy levels. For hydrogen these energy levels are -13.6 / n^2 electron volts for any integer n greater than or equal to 1.


jaumzaum said:
How can we produce an electromagnetic wave not being by an electron jumping to another electron shell/energy level and emitting a photon? Is there any other method to do that?

Jiggle an electron back and forth: that is, run an alternating electric current through a wire. This is how we produce radio waves. The frequency of the emitted wave is equal to the frequency with which the current alternates (and we can tune this frequency to be whatever we want).
 
  • #9
jaumzaum said:
Everybody says energy is quantized. But for einstein-plank equation
E = h.f

If a photon could have any values of f, E would not be quantized
I know bohr orbits only accept some frequencies, but hydrogen frequencies are different from lithium or nytrogen frequencies. So what is the MINIMUM value of E? As far as I know, a photon is a quanta of energy, so what would be the quantum?

In a vibrating string can have generic length L but the harmonics spectrum only assumes quantized wavelengths lambda_n = n lambda = n / L. An electromagnetic is like a string vibrating with arbitrary periodicity T, but the it can assume discretized energy values E_n = n E = n h /T. The energy gaps of the harmonics of this string are the photons.

bohm2 said:
We interpret the relativistic quantum behavior of elementary particles in terms of elementary cycles. This represents a generalization of the de Broglie hypothesis of intrinsically “periodic phenomenon”, also known as “de Broglie internal clock”. Similarly to a “particle in a box” or to a “vibrating string”, the constraint of intrinsic periodicity represents a semi-classical quantization condition, with remarkable formal correspondence to ordinary relativistic quantum mechanics. In this formalism the retarded local variations of four-momentum characterizing relativistic interactions can be equivalently expressed in terms of retarded local modulations of de Broglie space-time periodicity, revealing a geometrodynamical nature of gauge interaction.

On the intrinsically cyclic nature of space-time in elementary particles
http://arxiv.org/pdf/1206.1140.pdf
 
  • #10
San K said:
is there no minimum value for the quantum?
No.

San K said:
or
is frequency quantized?
The frequencies of a system are very often constrained to discrete values.

This is true even in classical mechanics. For instance, the resonant modes of a violin string have discrete frequencies. The boundary conditions of the string cause the wavelengths of the string to change by discrete values. This results in the frequencies changing by discrete values.

This discrete division between notes of a stringed instrument have been known since Aristotle. Probably even before Aristotle. Newton understood frequencies of vibrations on strings. However, the separate frequencies on a string were not called quanta.

The resonant frequencies of a hydrogen atom are caused by the periodic boundary conditions of the electron-wave. In that sense, they are like the waves on a violin string. However, the discrete values of frequency are not the direct result of an ad hoc hypothesis.

What is really quantized in a hydrogen atom is radius of the electron's orbit. The radius of the electrons orbit is a type of amplitude. You can think of the radius as the limit of the back and forth motion of the electron. It is this radius, which is a type of amplitude, which is quantized. The discrete values of frequency are an indirect consequence of the fact that the radius is "quantized". The frequencies aren't quantized, but the radii are quantized.

You have to be careful about the word quantized. The word is not quite synonymous with discrete. Quantization is a type of discreteness.

Maybe the word "digitized would be better. No, I take that back. There are certain qualifications to a digital system.

The "quantization" first hypothesized by Planck referred to


or
San K said:
does quantization only make sense when in a bounded state at a specific orbital/energy level/shell in an atom?

Discrete values for frequency usually make sense for bounded states. The real reason frequencies change in discrete values is because of the boundary conditions on the wave. The violin string is a good analog.

The reason that the notes of a violin string are discrete is because the violin string is fixed on both ends. Thus, the violin string has to be "bounded" in order to produce notes. Notes are bounded states! A violin string that isn't tied down does not produce separate notes.

A propose that frequencies should never be called quantized. Frequencies are merely discrete.
 
  • #11
http://www.amacad.org/publications/winter2002/wilczek.pdf
Darwin123 said:
No.




What is really quantized in a hydrogen atom is radius of the electron's orbit. The radius of the electrons orbit is a type of amplitude. You can think of the radius as the limit of the back and forth motion of the electron. It is this radius, which is a type of amplitude, which is quantized. The discrete values of frequency are an indirect consequence of the fact that the radius is "quantized". The frequencies aren't quantized, but the radii are quantized.

This is wrong. Orbitals are obtained by the Bohr-Sommerfeld quantization, which is a periodicity boundary condition for a deformed string. It is not necessary to require circular orbits. It is sufficient to ask for orbits with integer number of wavelengths, just as in a vibrating string.

see http://www.amacad.org/publications/winter2002/wilczek.pdf
 
  • #12
naturale said:
http://www.amacad.org/publications/winter2002/wilczek.pdf

This is wrong. Orbitals are obtained by the Bohr-Sommerfeld quantization, which is a periodicity boundary condition for a deformed string. It is not necessary to require circular orbits. It is sufficient to ask for orbits with integer number of wavelengths, just as in a vibrating string.

see http://www.amacad.org/publications/winter2002/wilczek.pdf
Sorry. I didn't mean to imply that the orbit was necessarily circular.

The Bohr-Sommerfield condition is not a periodic boundary condition for a deformed string. The Bohr-Sommerfeld condition was hypothesized before the de Broglie relationships were hypothesized. Therefore, there was no "wavelength" associated with them.

The Bohr-Sommerfeld condition (BSC)as first formulated involved orbital-angular momentum. It was a constraint on the size of the orbits. The word "radius" was perhaps wrong. However, the visual picture was of an electron in a Keplarian orbit around the nucleus. The size of that orbit had nothing to do with wavelength.

The frequency of a Keplarian orbit decreases with the size of the orbit. The size of the orbit and Kepler's Laws is what basically determines the frequency. However, the size of the orbit can vary continuously in classical physics. The reason that the frequency does not vary continuously in "old quantum theory" is that the size of the orbit can't vary continuously.

BSC was a generalization of the Planck rule for quantization. Planck assumed the atom was a harmonic oscillator. The electron in the atom was just a point charge connected to the nucleus by a type of "spring". The amplitude of this harmonic oscillator was constrained to specific and discrete values which resulted in the energy of the harmonic oscillator being constrained to discrete values. There was no electromagnetic wave and no electron wave. The frequency of the harmonic oscillator was not determined by any boundary condition. The natural frequency of the atom was the square root of the spring constant divided by the mass.

De Broglie came up with this "explanation" for the Bohr-Sommerfeld condition where the an integer number of complete cycles had to fit in on the orbit. The de Broglie explanation makes it look a bit like a string. Einstein came up with the idea that the quantization had something to do with particles. In all cases, the quantum constraints act upon the amplitude of a wave not the frequency of the wave.

The Bohr-Somerfeld quantization condition does not determine the frequency of the electromagnetic wave. BSQ applies to the electron, not to the photon. BSQ is not the same as the Einstein condition, E=hf.
 
  • #13
Darwin123 said:
De Broglie came up with this "explanation" for the Bohr-Sommerfeld condition where the an integer number of complete cycles had to fit in on the orbit. The de Broglie explanation makes it look a bit like a string. Einstein came up with the idea that the quantization had something to do with particles. In all cases, the quantum constraints act upon the amplitude of a wave not the frequency of the wave.

The amplitude of a quantum wave is fixed by the Born rule, i.e. unitary modulo square. That is, we have string vibrating always with amplitude 1. The only variables are the fundamental frequency of the vibration (length of the string) and how the harmonics are populated.

The Bohr-Somerfeld quantization condition does not determine the frequency of the electromagnetic wave. BSQ applies to the electron, not to the photon. BSQ is not the same as the Einstein condition, E=hf.

To obtain the frequency spectrum of a string you can use BSQ without the Planck constant. If the fundamental period is T and the string is homogeneous
[itex]\int f_n dt = f_n T = n[/itex], that is [itex]f_n = n / T[/itex]
the quantization of the mode with period T, say, in a Black Body radiation is
[itex]\int E_n dt = E_n T = h n[/itex], that is [itex]E_n = n h / T[/itex]

BSQ can be used to quantize photon, in this case the difference is the bose statistic in the population of the harmonics, and the fact that the photon is a particle with zero mass lambda = c T. The effect of the Coulomb potential of an hydrogen atom is a distortion of the spectrum. In our analogy this correspond to a non homogeneous string
 
  • #14
mpv_plate said:
Also please note one thing: the fact that only certain photons (with specific energies) can be emitted / absorbed by an atom, is not limiting the possible photon energies. The atomic energy levels are features of these atoms, but electromagnetic field does not care about that. The free e-m field can have any frequency. It is just that only certain frequencies will be absorbed by atoms, while other photons will not be affected.

This gets to an issue I was asking elsewhere. Is there an electromagnetic frequency independent from the frequency contained within the photons? It seems odd that the photon's probability wave is one in the same as the wave that we think of that focuses in cameras, or makes colors in our brain. Somebody told me that Maxwell’s equations deal with electromagnetic radiation, which has nothing to do with the probability waves of the photons, but nobody can show me any distinction.
 
  • #15
jaumzaum said:
Everybody says energy is quantized. But for einstein-plank equation
E = h.f

If a photon could have any values of f, E would not be quantized
I know bohr orbits only accept some frequencies, but hydrogen frequencies are different from lithium or nytrogen frequencies. So what is the MINIMUM value of E? As far as I know, a photon is a quanta of energy, so what would be the quantum?

This is also my exact question, but I'm still confused after reading the answers. All kinds of equations have constants; that doesn’t mean all those things are quantized. Pi is a constant relating the circumference of a circle to its diameter. Does that mean circles are quantized? Of course not. There has to be some relationship between frequency and energy, so Planck’s constant just turned out to be that number. I just don't understand how Planck's constant is identified with quantum amounts. Please explain and give clear examples.
 
  • #16
marksesl said:
This is also my exact question, but I'm still confused after reading the answers. All kinds of equations have constants; that doesn’t mean all those things are quantized.

In many cases it does. While we dont' talk about quantized for purely mathematical relationships, there are number of quantized phenomena in physics. In electromagnetics you have the abovementioned photon but also charge (1e=1.6022e-19 C or 2e depending on whether or not ou are working with normal metals or superconductor) and the magnetic flux quanta (2e^-15 Wb). Sometimes we also talk about resistance quanta (from the Hall effect)
All of of these can be directly measured because there are periodic phenomena where the period is set by the the quanta or a fraction thereof.
Note that the fact that they are periodic does not stop you from measureing e.g. a charge of 0.2e (which can happen because of screening).


In the case of e you have e.g. Coloumb blockade, for resistance the quantized Hall effect and for the magntic flux quanta Aharononv-Bohm rings or (more common) superconducing SQUIDs.
 
  • #17
Ok, I got it figured out. It's explained here:


In E=hv that number can only be multiplied by a whole number.
So, the equation actually becomes E=nhv. For blue light, for example, the value for hv is about 3. So, only 3, 6, 9, 12 electron volts are allowed for blue light.
 
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  • #18
marksesl said:
Ok, I got it figured out. It's explained here:


In E=hv that number can only be multiplied by a whole number.
So, the equation actually becomes E=nhv. For blue light, for example, the value for hv is about 3. So, only 3, 6, 9, 12 electron volts are allowed for blue light.


This is not correct. Blue light has an energy of around 3 eV, 6eV would be outside the visible par of the spectrum. Again, "quantized" does not mean that the light can only take on values that are integer multiplies of a specific number.

Your equation is the equation for e.g. multi-photon excitation of a transition in an atom.
 
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  • #19
Ok, so a blue photon is just always 3eV. Correct?


"The classical frequency of your light determines the quantization of the photons (as packets of h*nu energy). You can vary the classical frequency of your light continuously, and for every value it takes, you get a different quantized energy for your photons."

So what is the classical frequency of light as opposed to the frequency contained in the photons?
 
  • #20
The frequency associated with the photon equals the classical frequency of the light that it corresponds to.

The n=3 to n=2 transition in hydrogen produces photons with energy 1.9 eV, frequency f = E/h = 4.59 x 10^14 Hz, and wavelength λ = c/f = 6.53 x 10^-7 m = 653 nm.

If we have a few bazillion of these photons (give or take), we have a classical electromagnetic wave with that frequency and wavelength.

How much is a bazillion? Consider sunlight at the Earth's surface. Hold up a 1 m^2 screen facing directly towards the sun on a clear day, and in one second it will receive about 1500 joules of electromagnetic energy. The light contains all visible wavelengths, of course, but let's pretend it's monochromatic with wavelength 653 nm. Then each photon carries 1.9 eV = 3.04 x 10^-19 J of energy, so one second's worth of light on the screen contains about 1500 / (3.04 x 10^-19) = 4.93 x 10^21 photons.
 
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  • #21
Ok, so a classical electrometric wave is just lots of photons. The frequency of the photons is the same as the classical wave which they make. Now here's the clincher that I've been trying to get straight here for some time. Isn't the wave in a photon essentially a probability wave, or a De Broglie wave? So, does not the everyday characteristics of classical electromagnetic waves: color, focus ability, diffraction, etc. all come from photons’ probability waves?
 
  • #22
Basically, yes, but the connection is not simple. A large collection of photons with given frequency corresponds to a classical electromagnetic wave with that frequency, but don't fall into the trap of thinking of a photon as a tiny little bundle of classical electric and magnetic fields.

The "photon field" is actually the quantized version of the classical electric potential and magnetic vector potential, which in relativity theory combine to form the "four-potential" Aμ. In quantum field theory, Aμ gets turned into an operator and quantized.
 
  • #23
Isn't the wave in a photon essentially a probability wave, or a De Broglie wave?

I'd say the "The wave 'in a photon' is a physical wave; the probability wave, or wave function, is a probability function consisting of both real and imaginary components..."
but I think these words would/could still be debated today...

I came across nice dynamic illustration and introductory explanation here:

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



from

http://arxiv.org/PS_cache/hep-th/pdf/9702/9702027v1.pdf

my adds inside {}...

In 1926, in one of the very first papers on quantum mechanics, Born, Heisenberg and Jordan presented the quantum theory of the electromagnetic field... Born et al. gave a formula for the electromagnetic field as a Fourier transform {classical, continuous} and used the canonical commutation relations to identify the coefficients in this Fourier transform as operators that destroy and create photons, {annihilation and creation operators} so that when quantized this field theory became a theory of photons. Photons, of course, had been around (though not under that name) since Einstein’s work... but this paper showed that photons are an inevitable consequence of quantum mechanics as applied to electromagnetism.



Also, what we today call Planck's constant started out as the "quantum of action". As usual in science evolution, such discrete interactions were not grandly theorized all at once, and I don't know which led to which, but Planck apparently needed a 'h' factor via the development of
"Classical statistical mechanics which requires the existence of h (but does not define its value)." apparently he was not at all sure any of this was a wise move:

To save his theory, Planck had to resort to using the then controversial theory of statistical mechanics,[6] which he described as "an act of despair … I was ready to sacrifice any of my previous convictions about physics."[7] One of his new boundary conditions was

In 1923, Louis de Broglie generalized the Planck relation by postulating that the Planck constant represents the proportionality between the momentum and the quantum wavelength of not just the photon, but any particle. This was confirmed by experiments soon afterwards.


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



All the while Einstein's 1905 paper on the Photoelectric effect provided further theoretical support:

In 1905, Albert Einstein ... by describing light as composed of discrete quanta, now called photons, rather than continuous waves. Based upon Max Planck's theory of black-body radiation, Einstein theorized that the energy in each quantum of light was equal to the frequency multiplied by a constant, later called Planck's constant. A photon above a threshold frequency has the required energy to eject a single electron, creating the observed effect. This discovery led to the quantum revolution in physics and earned Einstein the Nobel Prize in Physics in 1921.

Heisenberg also utilized the Planck constant in his uncertainty principle [1927] and this became more theoretically developed in the following years.

Exactly what some of the means is still debated/discussed in these forums...a LOT.
 
  • #24
Here is a different view I finally found in my notes:

psi here the the quantum wave function...of the Schrodinger wave equation...

No one can understand this theory [Bohmian mechanics] until he is willing to think of psi as a real objective field… Even though it propagates not in 3-space but in 3N-space. There is nothing in this theory but the wavefunction. It is in the wave function that we must find an image of the physical world, and in particular of the arrangement of things in ordinary three-dimensional space.
[John Bell, 1987]


https://www.physicsforums.com/showthread.php?t=551554&page=2

ABSTRACT: Quantum states are the key mathematical objects in quantum theory. It is therefore surprising that physicists have been unable to agree on what a quantum state represents. There are at least two opposing schools of thought, each almost as old as quantum theory itself. One is that a pure state is a physical property of system, much like position and momentum in classical mechanics. Another is that even a pure state has only a statistical significance, akin to a probability distribution in statistical mechanics.
 

1. What is a quantum state in quantum theory?

A quantum state in quantum theory represents the set of all physical properties that can be attributed to a quantum system. It describes the state of a system in terms of its position, momentum, and other physical quantities.

2. How is a quantum state represented?

In quantum theory, a quantum state is represented by a mathematical object called a wave function. This wave function is a complex-valued function that describes the probability of finding a particle at a particular location.

3. What is the significance of a quantum state?

The significance of a quantum state is that it contains all the information about a quantum system. It determines the behavior and properties of the system and allows for predictions to be made about its future state.

4. Can a quantum state change?

Yes, a quantum state can change over time. This is known as quantum evolution and is governed by the Schrödinger equation. The state of a system can also change when it interacts with other quantum systems.

5. How is a quantum state different from a classical state?

A quantum state is fundamentally different from a classical state as it describes the probabilistic nature of quantum systems. In classical physics, the state of a system is fully determined and can be predicted with certainty, whereas in quantum theory, the state is described by probabilities.

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