Certainly any change of a physical system represented by a single physical event is connected with some interval of time Dt. This is a rather trivial statement concerning both the classical and quantum physical theory. However, the approach to Dt offered by each of these two theoretical formalisms is quite different.

In brief one can say that Dt given by the classical physics is usually of a definite character. On the other hand, the quantum theory provides systematically Dt of a probabilistic, or statistical nature.

This kind of discrepancy began to exist already on the level of the old quantum theory [1] - [3] , it became however, more acute in the modern quantum mechanics [4] - [6] . For example, when concerning the spectroscopy phenomena, it is hardly possible to define the time moment in which the transition of the electron particle from one of the quantum levels to another begins, as well as the time moment when this transition ends. Nevertheless the exsistence of a finite interval Dt between these two limiting events seems intuitively to be rather evident.

An approach to Dt connected with a single electron transition of a quantum system becomes easy to effectuate when, for example, the interval DE of the system energy is known together with the time rate of this energy change. Such knowledge is offered, for example, by the Joule-Lenz dissipation law for energy [7] [8] .

The law is of a typical classical nature, nevertheless its inspection done on the basis of quantum parameters, shows a posteriori its formal behaviour much similar to the Heisenberg uncertainty principle specialized for the case of quantum intervals belonging to energy and time.

In the first step we show the quantum aspect of the Joule-Lenz law and its effect on the uncertainty principle. This approach allowed us to obtain a minimal admissible interval of time associated with the electron transition process. In the next step, a maximal limit of the electron transition energy could be calculated. As a final result, due to the existence of a minimal interval of time, a minimal geometrical size of a distance parameter entering small quantum systems could be estimated.

A complementary character of the intervals of energy and time concerning a given physical phenomenon has found its well-known representation in the Heisenberg principle of uncertainty [4] [9] . Mathematically the principle states that the product of DE and Dt should not provide a number smaller than the Planck constant:

The Formula (1) has been outlined parallelly to the Heisenberg rule of uncertainty concerning a product of the change of a Cartesian coordinate of the particle position and the particle momentum, for example

Evidently the Formula (2) can be extended equally to the Cartesian coordinates y and z.

But a mathematical and historical background of (1) and (2) became much different: the Formula (2) found its wide justification in numerous approaches [10] [11] contrary to the rule of (1) which was strongly objected on several occasions [12] - [14] . In effect, in some textbook presentations (see e.g. [15] [16] ), the Formula (1) contrary to (2) did not appear at all.

A characteristic point is that shortly after (1) and (2) have been published, some proposals concerning the limits of the observables entering (1) and (2) were done. These limits concerned in particular and. According to [17] - [20] , should be not smaller than the Compton wave length

and should satisfy the relation

An essential change of (1) can be attained when the velocity condition of the special theory of relativity, namely

is applied in the motion analysis of the fermion particles [21] - [23] . In this case the transition energy done within the time interval should satisfy instead of (1) the formula

By assuming that

where is the electron momentum

because of the Hamilton equation

we obtain from (8)

This expression substituted into (6) together with (7) gives the relation

from which

By dividing (12) by c, an operation similar to that applied in (4), we obtain

The limits in (12) and (13) are smaller than, respectively, limits in (3) and (4) solely by the factor of; see [24] . This is an important correction because from (12) assumed as a radius of the circular-like trajectory of a spinning electron leads to a correct driving velocity of that electron. The correctness property is examined by the agreement of the driving velocity provided by a spinning particle with the Bohr orbital velocity of the electron; see [25] [26] and Section 3.1. Moreover the magnetic moment produced by a spinning particle is equal to that experimentally observed [25] [26] .

Our aim is now to obtain a minimal with the aid of a more fundamental reasoning than applied in (13). To this purpose the rate of energy produced according to the Joule-Lenz classical law [7] [8] [28]

is examined for the case of the quantum systems. R is the electric resistance

V is a voltage of the electron transition, and

the current intensity. We assume that any considered quantum state is periodic in time, which means that after the time interval the state n is exactly the same as before.

Let the voltage be calculated by assuming that

where

is the energy difference between two neighbouring quantum states. In Section 5.1 the Formula (20) modified into

has been applied―together with (21)-(24) ―to three quantum systems: the hydrogen atom, electron particle in a one-dimensional potential box and the harmonic oscillator. A posteriori several characteristic features concerning R and the Joule-Lenz law have been obtained.

The first of them is that

is a constant for all systems and all quantum states taken into account. The constant number (25) is well known from the experiments on the quantum Hall effect [29] . Another feature is that the product of and calculated in all examined cases is formally similar to that represented by the Formula (1):

In fact the Formula (26) disproves that given in (1) in the sense that now we have

instead of (1).

Another result found in the course of calculations is that

other arguments justifying (26) and (27) are given in [30] .

By assuming that in (26) is equal to entering (6) we obtain―after a substitution of (26) into (6)―the relation

from which

But the Formula (26) can be applied also in the case when

Since in this case, this substitution gives the relation

from which a maximal energy involved in an electron transition is

Let us note that the energy

estimated as valid for transition from the Dirac’s antiparticle sea to the electron particles area [31] [32] satisfies the condition imposed by (32):

Some interesting results seem to be obtained with the aid of the velocity observable

and the intervals of time combined with it. A simple multiplication applied in (58) should give

Our first aim is to check whether result (59) is obtained when entering (59) satisfies the relation

where the last formula is a result of (26).

For the hydrogen atom we have the orbit radius:

and the electron velocity in state n is

In the next step the energy interval concerning the neighbouring levels and n is that given in (41) so, because of (60), we have

see (36). The result for the product of the velocity and time

represents the whole of the circular length associated with the orbit n; see (61).

For a free particle in the potential box having length L the distance travelled within one period of time is the same for all n namely

The velocity term in (65) satisfies the formula for the kinetic energy of a free particle; see (38). The second term in (65) should be evidently

because the energy difference of free electrons is given in (42), so we obtain equal to in (66). This time interval multiplied by entering the Formula (38) gives the product identical with that calculated in (65).

For the low energy excitation of the harmonic oscillator we have

where is the circular frequency. Therefore

All formulae (63), (66) and (68) give

where T is a time period characteristic for a quantum state involved in the energy transition.

Other calculations for the harmonic oscillator are less accurate because the variables applied in them are dependent on time, for that reason only the average quantities are taken into account [34] . The average distance having the same sign occupied by the oscillator is evidently

where a is the oscillator amplitude.

Since the absolute value of the oscilator velocity is [34]

where k is oscillator strength and the oscillator frequency, the average oscillator velocity taken over the distance of the amplitude is

Because of (67) we have

which is a result times larger than in (70).

In general we found that can reproduce the observables of geometrical distance in small quantum systems with the accuracy to a constant coefficients.

An interesting point is the calculation of the distance observables when the interval is replaced by given in (29). For the hydrogen atom in the state of we obtain

which is equal to times the radius of a sphere representing the microstructure of the electron particle [8] [35] .

A similar product calculated for a one-dimensional free-electron case gives

where is taken from (65). Here we require that the equality of (75) with entering should be satisfied, in result an equation for is obtained. Its solution is close to derived in (12).

For the harmonic oscillator a requirement that (72) should hold also in the case of, so

leads to a maximal frequency which can be admitted by the oscillator:

This number is not extremely different from a maximal frequency of the oscillator attained in another way [21] .

If we combine the Formulaes (26) and (69) together with

we obtain

which is the well-known fundamental Planck formula on condition is considered as the frequency of the electromagnetic wave associated with the energy. Consequently T has to be identified with the time period of that wave. From our derivation of (68) given in Section 6 it can be deduced that T is not much different than the time periods associated with quantum states and n entering the difference; see (63), (66) and (68).

A new result in (78) which seems to be neglected by many authors is that

This means that performance of the electron transition between quantum states and n occupies solely one oscillation time period of the electromagnetic wave strictly connected with the period of the quantum level involved in the mentioned transition.

In effect of (26) and (69) the emission rate of energy in a quantum system can take a very simple formula

A maximal time rate of energy which can be attained by a fermion particle of mass m in a single transition is

see (29) and (32).

For the hydrogen atom at large n we have [see (41) and (50)]

This result can be compared with a classical emission rate; see Section 9.

On the other hand for a harmonic oscillator we obtain

A reference of this formula to the classical emission rate of energy is discussed also in Section 9.

The Joule-Lenz dissipation rate of the electron energy in a metal referred to a single electron transition can be represented by the formula [8] :

Here l is the electron free path, is the strength of the electric field acting on the metal, is the average electron velocity which is

where is the Fermi velocity because the electrons located mainly near the Fermi level are submitted to the motion due to the action of, the parameter is the relaxation time. The work done along the length l is connected with by the acceleration formula

because

In effect from (86)

On the other hand, because of (84) and (85)

where the last step is coming from the present formalism; see (81). From (88) and (89) we obtain the relation

or

If we note that relation

is satisfied for small according to the present formalism, we obtain

In consequence the rate

does hold for a single electron transition in the metal. The Formula (94) can be submitted to the experimental verification.

It can be noted that for

which is the case of the electron transport in superconductors, we obtain in result of (94) that

The classical emission rate depends both on the amplitude a of the oscillator and the emitted frequency [36] :

We assume the transition is going on between two neighbouring quantum levels and n.

For the harmonic oscillator being in state n the amplitude can be deduced from a classical relation between the energy and amplitude. Therefore for the energy

this gives (see e.g. [34] )

The frequency is assumed to be that given by the transition energy

For the classical emission rate of the harmonic oscillator having frequency we obtain with the aid of (98) the formula

and an interesting result is the ratio of the classical and quantum emission rates of the oscillator. This is given by the formula [see (83)]

The ratio (102) differs solely by the factor of

from the damping constant

of the classical emission see [36] [37] . The T entering (103) is the oscillation time period of the electromagnetic wave having the frequency. The product

is the number of excitations within the time period T; see [36] .

A similar calculation can be done for the hydrogen atom. In this case the classical emission rate between levels nad n becomes

here (61) and (62) are taken into account. The quantum rate of emission is

on the basis of (80) and (81). Therefore the ratio of (106) to (107) becomes

where

is the fine-structure atomic constant; see e.g. [4] .

The physical consequencies of a quantum aspect of the Joule-Lenz law for the dissipation rate of energy are examined.

The mentioned aspect seems to influence the uncertainty principle for energy and time. In consequence a lower limit of the time interval and an upper limit of the energy interval admissible in a quantum transition process could be calculated.

The next point concerned the time rate of the low-energy transitions was performed in small quantum systems. On the basis of the Joule-Lenz law the transition time between quantum levels could be calculated in a definite, i.e. non-probabilistic, way. This calculation indicates a similarity existent in the size of the seeked transition time and time periods characterizing the examined quantum levels.

In effect a simple formula coupling the transition time with transition energy could be obtained. The formula makes a reference to the Planck constant h and points out that transition time is in fact equal to the time period T of the electromagnetic wave produced in effect of the transition.

As an application of the theory, the classical and quantum emission rate of energy in two systems (harmonic oscillator and the hydrogen atom) taken as examples have been calculated and compared.

StanisławOlszewski, (2016) Quantum Aspects of the Joule-Lenz Law. Journal of Modern Physics,07,162-174. doi: 10.4236/jmp.2016.71018