The experimental setup consists of a laser pointer supported by a tripod and a 5 cm diameter and 2.5 mm thickness PZT4 ceramic disc supported with its circular face in a horizontal position on a light Styrofoam holder. The mentioned disc is also positioned below and immediately near the laser beam output of the pointer. When triggered, the laser beam passes a few millimeters above the circular face of the disc crossing above its center and also its entire diameter.

The circular faces of the disc are covered by metallic finish and they are connected to a high voltage power supply via aluminum stripes. When triggered, the laser beam is projected over a certain distance and achieves almost perpendicularly a whiteboard with 1-centimeter grid. The grids are used as the position reference for analysis of the shape change of the laser beam profile projection.

In some outdoor or external tests, the power cord of the high voltage power supply was plugged in the inverter connected to +12 VDC output of the car in order to supply 110 VAC. In other indoor tests, the power cord was plugged directly in the AC outlet of the laboratory.

Three different distances were tested such as 10.85 m, 47 m and 120 m between the whiteboard and laser pointer in order to project some laser beam profiles with respectively 2 cm, 5 cm and 9 cm in terms of average diameter. In the first and last distances, the experimental setup was performed in the field (outdoor) with cloudy sky, more than 85% air relative humidity and around 21˚C temperature in terms of weather conditions. In the second distance, the setup was performed inside the building (indoor) with the PZT4 ceramic disc covered by two thin layers of polystyrene in order to even more reduce at least 2.3 times the electric field around it.

The laser pointer had a continuous activation in order to project the laser beam. During its activation, it was applied a DC high voltage on the PZT4 ceramic disc with approximately 1 kV by the power supply during approximately 30 seconds per each cycle. In other words, we had approximately 15 seconds “off” with 0 V and 15 seconds “on” with up to 1 kV per cycle in terms of alternating operation.

The PZT4 ceramic disc was tested in the converse piezoelectric mode, that is, when a mechanical stress is generated according to the voltage applied on it. The disc was polarized directly with the positive pole of the power supply connected to the positive side of the disc and the negative pole of the power supply connected to the negative side of the disc. In other tests, the disc was reversely polarized, that is, the positive pole of the power supply was connected in the negative side of the disc and the negative pole of the power supply was connected in the positive side. When the PZT4 ceramic disc is polarized directly, its thickness has a mechanical stretching in the z axis and it has a mechanical contraction in the same direction when polarized reversely.

During the tests, several videos of the laser beam profile projected to the whiteboard were performed and several frames of them were captured accordingly.

The list of devices performed in the experiments is shown in Table 1.

The Figure 1 shows the photo of the experimental setup taken inside the

laboratory building, with a 47 m in terms of distance between output of laser beam pointer and white board.

The Figure 2 and Figure 3 show the photos of the experimental tests performed in the field (outdoor).

It was made a comparison between the video frames obtained in the “on” period (high voltage applied in the PZT4 ceramic disc) and “off” period (power supply turned off) and it was noted a visual subtle difference mainly in some regions of

the laser beam profile projected in the whiteboard as its upper, bottom, left and right corners.

It was also just considered the analysis of the video frames after several seconds from the short period of power supply activation in order to the high voltage be well stabilized and to avoid any possible transitory acoustic propagation in the air during the short period of stretching or contraction of the PZT4 ceramic disc.

Some small variation (blinking, oscillation) of the laser beam profile did not strongly affect the visualization of the differences between the video frames from the “on” and “off” periods.

Considering all of the tests, the shape of the laser beam profile seems to be stretched in the upright direction (z axis) and contracted at the same time in the horizontal direction during the “on” period when the PZT4 ceramic disc was directly polarized, that is, when its thickness was stretched.

It was noted the opposite, that is, the laser beam profile seems to be contracted in the upright direction (z axis) and stretched at the same time in the horizontal direction during the “on” period when the PZT4 ceramic disc was inversely polarized, that is, when its thickness was contracted.

The laser beam profile recovered its original symmetric shape when it was again turned off the voltage (off period).

The possible scenarios are represented in three diagrams drawn at the top of the Figure 4, where we can see from the left to the right, the original symmetric condition of the laser beam profile shape, the condition of contraction in the z axis when the disc is reversely polarized and the condition of stretch in the z axis when the disc is directly polarized. For didactic proposal, the shape variation drawn in the diagrams was exaggerated. The simple diagram of the experimental setup including the laser pointer, laser beam projection, PZT4 ceramic disc, the whiteboard and the laser beam profile is drawn in the bottom of the Figure 4.

The dimension of the shape of the laser beam profile seems to change approximately 0.5 mm in case of the test for a 10.85 m distance.

Considering that the PZT4 ceramic disc affected the laser beam emitted above it during the short “on” time, it is reasonable to obtain probably higher dimension shape changes for long distances. Therefore, it was performed other tests afterwards for long distances, such as 47 m and 120 m, which resulted significant dimension shape changes, that is, respectively 2 mm and 5 mm, with 20% estimated error.

The Figure 5 shows four video frames obtained in the experiments performed with 120 m distance where we can see two laser beam profiles “off” and “on” in case of PZT4 ceramic disc polarized reversely (contraction) and also two profiles “off” and “on” in case of ceramic disc polarized directly. The subtle contraction of the laser beam profile in the z axis is visible for the reverse polarization of the disc and the subtle stretching of the laser beam profile in the z axis is visible for the direct polarization.

Such as in Figure 5, Figure 6 also shows four video frames obtained in the experiments performed with 47 m distance where we can see two laser beam profiles “off” and “on” in case of PZT4 ceramic disc reversely polarized (contraction). Analogously, we also have two profiles “off” and “on” in case of ceramic disc directly polarized. As expected from the earlier experimental result, the subtle contraction of the laser beam profile in the z axis is visible for the reverse polarization of the disc and the subtle stretching of the laser beam profile in the z axis is visible for the direct polarization.

There is no acoustic interaction from the PZT4 disc in its converse mode to the laser beam because it was applied a DC voltage (static electric field) and the visual analysis of the laser beam profiles just consider the video frames after the short time (milliseconds) of the high voltage activation.

Since the low power laser beam is not affected by traveling through static electric field [12] , therefore this cannot explain the change of the profiles shape projection that we analyzed.

Thinking about some other conventional explaining, there is the electro-optical Kerr effect in the atmosphere [13] where a static electric field causes an alignment of the air molecules, and creates birefringence, that is, the optical path length change (Δn) can happen according to the following equation:

Δ n = λ K ε 2 , (1)

in which λ is the vacuum wavelength of the laser beam, K is the Kerr constant of the air (almost 2.3 × 10⁻²⁵ m²∙V⁻²) and ε is the magnitude of the static electric field applied.

It is well noted in the Equation (1) that the optical path length change (Δn) varies according to the square value of the electric field. In our case it is 0.4 × 10⁶ V/m (1 kV DC voltage applied) between the circular surfaces of the PZT4 disc separated by a 2.5 mm thickness.

The electro-optical Kerr effect occurs in some condition in which a static electric field is applied in the direction transverse to the laser beam direction and this condition can theoretically happen in our experiments. After all, the static electric field applied between the circular faces of the PZT4 disc is perpendicular to the laser beam positioned a few millimeters above it.

Some static electric field can emerge from the top of the circular face of the PZT4 disc causing the alignment of the air molecules placed on it where the laser beam propagates. Despite of this, according to [13] , regarding the electro-optical Kerr effect in the atmosphere, for most cases, the laser beam phase shift and its variation are so small as to render its proposed measurements unfeasible. The reference [13] assumed a resolution of 2 × 10⁻⁸ for measured valued of phase shift.

The magnitude of the electric field on the top of the PZT4 disc axis must be reduce around 92% in the laser beam position of propagation (just 2 millimeters above), that is, 0.368 × 10⁶ V/m for a 1 kV DC voltage applied. Remind that the low power laser beam isn’t affected in its propagation through a static electric field [12] . Considering this value of electric field (the electric field magnitude also decays from the center of the disc towards the edge, following the radius direction) and the short path length of the laser beam (PZT4 disc diameter) of 0.05 m, the overestimated phase shift value is calculated as 1.963 × 10⁻⁸ according to Equation (1). Therefore this value is less than the mentioned resolution limit of measurement (2 × 10⁻⁸).

It was also applied some dielectric layers of thin polystyrene foils (dielectric constant equal to 2.3) covering the PZT4 disc in case of experiments performed indoor in order to reduce even more some possible emerging electric field remained in the environment. In this condition, the overestimated phase shift is calculated as 0.371 × 10⁻⁸, that is, much less than the resolution limit of measurement. We need to outstand that the changes in the laser beam profiles shape with the 1 kV DC voltage application in the PZT4 disc remained the same with or without the dielectric layers coverage.

All these arguments strongly suggest that it is not easy to explain the novel visual effects via some conventional theoretical framework, so that local interactions such as acoustic or electromagnetic ones cannot probably be responsible for them.

In our previous works, novel effects detected in experiments performed by ourselves and other authors such as in symmetric capacitors [14] [15] asymmetric capacitors [16] , magnetic cores [11] , laser diodes [17] , piezoelectric devices [9] [10] and superconductor devices [18] [19] seem to be quantitatively and qualitatively explained by an unique theoretical framework. In this framework [11] , the preexisting condition of generalized quantum entanglement (GQE) between all existing particles in a physical system, usually extremely weak because of the huge entropy, rises when a myriad of group of particles are conditioned to have the same quantum state (local entropy reduction) via a strong local field such as electric or magnetic one, for example. In the present work we report that the anomalous forces verified can be microscopically originated from the state of generalized quantum entanglement of their particles, in a manner similar to the anomalous effects analyzed in other physical systems mainly based on dipoles, dielectric materials and superconductors. The difference between the anomalous effect raised from piezoelectric materials and each previous physical system analyzed is in the type of the source device and the nature of the effect. For instance, in case of capacitors under high voltage, it appears on them an upward anomalous force decreasing their apparent weight and in case of superconductors and diode laser beams it is produced a field of forces at distance in the surroundings.

There is also a favorable condition for GQE effects rising in case of the molecular electric dipoles inside the piezoelectric ceramic disc (over high voltage) inducting its dipolar momentum variations to the group of the laser beam photons positioned at distance in the experiments described in this work.

The data information of PZT4 ceramic disc (according to our previous article [9] ) allows us to calculate the intensity of the attractive or repulsive on local force inducted to the laser beam. The modulus of the force for the 1000 V voltage applied in the piezo electric ceramic disc can be calculated using F = V ⋅ T / g 33 as follows:

F = V ⋅ T / g 33 = 1000 × 2.5 × 10 − 3 / 0.02292 = 109.1   N . (2)

The second step is to calculate the strain S, using:

S = F / A = 109.1 / ( 1.964 × 10 − 3 ) = 55564.17   N / m 2 , (3)

in which A is the circular area of the disc. The next step is to calculate the physical deformation D using the equation

D = S / Y 33 = 55564.17 / ( 6.2 × 10 10 ) = 8.962 × 10 − 7 . (4)

Finally, then on local force induction can be calculated as shown:

f = F ⋅ D = 109.1 × 8.962 × 10 − 7 = 9.78 × 10 − 5   N . (5)

In our next work, this value of non local force will be used for predicting the displacement of the laser beam profile in term sofa quantitative analysis.

When the PZT4 ceramic disc in piezoelectric converse mode condition is directly polarized via DC voltage application, the internal (lead zirconate titanate) electric molecular dipoles change its collective dipolar momentum in order to stretch the thickness dimension of the disc both upwards and downwards (z axis). Theoretically, the group of photons of the laser beam crossing above the disc projection area also presents a change in its transversal momentum component (z axis) because of the nonlocal induction generated by the molecular dipoles of the disc. The stretching of the laser beam profile projected in the whiteboard is visually observed accordingly.

In the opposite case, that is, when the PZT4 ceramic disc in piezoelectric converse mode condition is inversely polarized via DC voltage application, the electric molecular dipoles change its collective dipolar momentum in order to contract the thickness dimension of the disc. The group of photons of the laser beam has also change in its transversal momentum component (z axis) because of the nonlocal induction of molecular dipoles of the disc and the contraction of the laser beam profile projected in the whiteboard is also visually observed accordingly.

In case of the non-energized condition of the PZT4 ceramic disc, that is, when we have no voltage applied, the internal electric molecular dipoles are not subjected to any electric field and it cannot change the transversal momentum component of the group of laser beam photons. In this condition, there is no visual change in the laser beam profile and it can remain with its original symmetric shape.

In terms of quantum framework, the system electric dipole-photon presented in our experiments has some similarity with other experiment [20] where a single photon interacted with a single atom (ion, electric dipole) and its state was measured to be analyzed afterwards. In other similar experiment [21] we had the opposite, a single atom (ion, electric dipole) interacted with a single photon and its state was measured to be also analyzed. In both experiment, the coherence of the quantum states of both the photon and the atom (ion, electric dipole) was well controlled for the detection of quantum entanglement between both where the state variation of one of the two entailed the variation of the state of the other.

In our experiments, it is supposed that a myriad of internal electric dipoles of the PZT4 ceramic disc submitted to the same local electric field can change its quantum state and also the quantum state of a myriad of coherent photons emitted from the laser pointer considering the preexisting condition of generalized quantum entanglement (GQE) between them. The change in the macroscopic observable, that is, in the shape dimensions of the laser beam profile follows the change in the other macroscopic observable (thickness of PZT4 ceramic disc).

For the next step, the authors intend to perform more experiments in order to better characterize the magnitude of the changes of the laser profile shape according to the magnitude of the induction generated by the PZT4 ceramic disc already characterized by accelerometer measurements. More experiments related to the measure of the geometry of the induction will be also performed.