This paper presents new experimental results concerning the PeTa effect—infrared characteristic radiation under first order phase transitions, especially during deposition and condensation of vapours/gases and the crystallisation of melts. The abbreviation “PeTa effect” means Perel’man-Tatartchenko’s effect. The nature of the PeTa effect is transient radiation that a particle (i.e., atom, molecule or/and cluster) emits during a transition from a meta-stable higher energetic level (in a super-cooled melt or super-saturated vapour) to the stable condensed lower level (in a crystal or liquid). The radiation removes latent heat with photons of characteristic frequencies that are generated under this transition. This paper is the second in a set describing the appearance of PeTa radiation under air cooling with deposition and condensation of air components. The radiation was recorded using an IR Fourier Spectrometer with a highly sensitive MCT detector. Certain peculiarities of the recorded radiation as well as its applications in the physics of the atmospheres of Earth and Jupiter are analysed.
This paper presents new experimental results for the PeTa effect—a physical phenomenon of infrared characteristic radiation (IRCR) under first order phase transitions, especially during deposition and condensation of vapours/ gases and crystallisation of melts. The effect was theoretically predicted by M. Perel’man [
sure that Planck’s radiation does not influence our results. Deep air cooling allowed these conditions. If we decrease the temperature from 298 K to 77 K, the maximum amplitude of Planck’s radiation will move from 9.9 µm to 37.6 µm, and the integral intensity of equilibrium radiation in the range of our measurement, 1 to 25 µm, has to be decreased by a factor of 3500. In our experiments [
For the recording of IR radiation, the same Fourier spectrometer utilised in previous experiments [
An objective of the first experiment was to analyse the peculiarities of PeTa spectra under gradual changes of conditions during condensation and/or deposition of different air components, by increasing the temperature of the target, from the temperature of liquid nitrogen (77 K) to room temperature (298 K). The integral radiation intensity within the range of 1 - 25 µm was continuously recorded from the irradiative cup wall. In this instance, a glass cup was used. For radiation spectra, a time of 1.09 s was chosen for the accumulation of data for one spectrum, and an average of 5 spectra was used. Thus, we had a new spectrum every 5.44 s, with a resolution of 2 cm-1. The temperature of the laboratory was 25˚C (298 K) and the relative humidity was 47% (corresponding to 286 K for the water vapour dew point).On the integral radiation curve (
PeTa radiation and increasing Planck’s radiation. At point 9, the speed of radiation change is equal to zero. At this point, the speed of decreasing PeTa radiation is equal to the speed of increasing Planck’s radiation. Approximately 150 s later (
Here are the critical temperature ranges of our experiment for normal atmospheric pressure, and possible physical processes for equilibrium conditions (without supercooling, besides a well-known super-cooling of water up to 40 K):
77 K - 88 K: deposition of H2O and CO2, condensation of Ar and O2.
88 K - 90 K: deposition of H2O and CO2, condensation of O2.
90 K - 195 K: deposition of H2O and CO2.
195 K - 233 K: deposition of H2O.
233 K - 273 K: deposition and condensation of H2O.
273 K - 286 K (dew point): condensation of H2O.
286 K - 298 K: evaporation of H2O.
Thus, on the
Let us compare consequent spectra.
Increasing the temperature moves the main peak from 13.5 µm to the shorter wavelength of 11.5 µm (spectra 1 - 9). However, for spectrum 10, the peak moves back to 13.5 µm. This effect can be connected with the condensation of water, as well as with augmentation of Planck’s radiation.
The spectra obtained during very fast cooling have more intensive peaks near 8 µm in comparison with spectra of the same integral intensity obtained during slow heating. It is especially clear for spectra −5 and 5 of
An objective of the second experiment was to obtain PeTa radiation during deposition and condensation of water vapour on a cooled cup wall at a temperature range of 253 K to 286 K with synchronised recording of hoarfrost grains, or the dew droplets on the surface, with an optical microscope (magnification X10 - X500).
The temperature of the laboratory was 25˚C (298 K) and the relative humidity was 47% (corresponding to 286 K for the water vapour dew point). An irradiative object, a 200 ml plastic cup containing alcohol-water solution cooled in a refrigerator, was placed approximately 4 cm from the input window of the spectrometer (
We divided the interval of time of cup heating from this temperature to room temperature over twelve ranges (
First, we explain the notifications that we use for all: 1. Ranges: d1, d2; 2. Time interval: 100 - 1200 s; 3. Physical process: the water vapour deposition; 4. The averaged spectra of radiation for each range:
1. cdC; 2. 1486 - 1986 s; 3. Water vapour condensation, deposition, and crystallisation of formed droplets; 4.
1. mc; 2. 2200 - 2400 s; 3. Ice melting and water vapour condensation; 4. Figures 4(a) and 5(a), mc; 5. Relative augmentation of the peak at 9.7 µm; 6. Figures 4(f) and (g); 7. As in the previous point, the peak at 9.7 µm is most likely connected with water vapour condensation.
1. c1 - sc; 2. 2700 - 5244 s; 3. Water vapour condensation up to stop condensation; 4.
1. e1 - e3; 2. 5444 - 7044 s; 3. Water vapour droplet evaporation; 4.
1. bg; 2. 7100 s; 3. Planck’s radiation at room temperature; 4.
The objective of the third experiment was to compare the sources of PeTa and Planck’s radiations. All conditions of the experiment were the same as in the previous two experiments.
1) We filled the Al cup with liquid nitrogen (77 K). The wall of the cup was covered with an ice film. We measured the integral intensity of radiation, U1, in the range of 1 to 25 µm from the cup wall. We filled the plastic cup with water heated to a temperature higher than the dew point. We measured the integral intensity of radiation, U2, in the range of 1 to 25 µm from the cup wall. We increased the temperature of the water up to the equalisation point of both (U1 and U2) intensities. We repeat once more, if we decrease the temperature from 298 K to 77 K, the maximum amplitude of Planck’s radiation will move from 9.9 µm to 37.6 µm, and the integral intensity of equilibrium radiation in the range of our measurement has to be decreased by a factor of 3500. This means that Planck’s radiation from the cup with liquid nitrogen is a negligible quantity, and the cup will emit only PeTa radiation. Thus, we found that at the temperature of the laboratory 298 K and relative humidity 47% (corresponding to 286 K for water vapour dew point), the integral PeTa radiation at 77 K corresponds to Planck’s radiation at 329 ± 2 K. The spectra of both radiations are shown in
We did not protect the spectrometer from the parasitic surrounding sources of Planck’s radiation.
We used a plastic cup so the emissions of the ice and plastic do not significantly differ.
2) We performed the same experiment with two plastic cups filled with a cooled alcohol solution and water heated to a temperature higher than the dew point. We found that the integral intensity of the radiation at 253 ± 2 K corresponds to the intensity of Planck’s radiation at 298 ± 2 K. However, at 253 K, we cannot neglect Planck’s radiation. Thus, we found that at the temperature of the laboratory (298 K) and a relative humidity of 47% (corresponding to 286 K for the water vapour dew point), the integral at the range of 1 - 25 µm for the totality of PeTa and Planck’s radiations at 253 ± 2 K, corresponds to Planck’s radiation at 298 ± 2 K. The spectra of both radiations are shown in
In the paper [
An igloo, or snow-house, is a type of shelter built from snow. On the outside, temperatures may be as low as −45˚C, but on the inside the temperature may range from −7˚C to 16˚C. A widely spread opinion is that snow is a good insulator [
emitted by the sheet, heated to approximately 30˚C. Certainly, inside the house, the metallic sheet has to be protected against thermo-conductive heat loss.
Evidently, the same effect has to exist for an ice-cream.
The stuffiness is a well-known effect that ceases with the first droplets of rain [
Detected by satellites, IR radiation would allow very important information concerning the atmospheric and earth’s surface processes to be accumulated if interpretation of IR images is definite. Let us analyse an anomalous distribution of IR radiation mainly obtained from the Advanced Very High Resolution Radiometer data in the channels of 10.3 - 11.3 µm, and 11.5 - 12.5 µm [26-36]. The zones of permanent or periodical increased intensity of radiation were detected on the images of tectonic breaks located in the west part of the North American continent, in the south part of East Siberia, in the Tarim Valley in China, in the Rhine Graben in Germany, and in zones of rift-genesis of the Afar Depression in northeastern Africa. As a result, the authors conclude that the anomalies in earth’s infrared radiation at regions of tectonic breaks have a global character. Four types of anomalies were detected: 1. Linear; 2. Contour; 3. Striped; 4. Isolated. Respectively, they had the lengths: 1. 200 - 600 km; 2. 100 - 200 km; 3. 40 - 60 km; 4. 1.0 - 1.5 km; and the widths: 1. 5 - 15 km; 2. 1 - 6 km; 3. 10 - 20 km; 4. 1.0
- 1.5 km. Emission of 1st, 2nd, 4th types had a permanent character, and the 3rd type was most noticeable at the rain seasons and became weak during winters. Some of the anomalies were located in ocean or lake coast strips, but the most were situated on the middles of slopes in mountain ranges. The last anomalies were narrower for the steeper slopes, and the intensity of their radiation was distributed with the most contrast on alternate mountain ranges and valleys. Typical values of measured infrared flows were arranged as 50 - 90 mW/(m2∙str∙μm). The authors have mainly explained these anomalies as the sources of endogen heat flow exiting through tectonic breaks.
We think this explanation is false. Given that the anomalies are located in places with ideal conditions for fog and cloud formation, it would seem to follow as a natural consequence that the recorded IR radiation is PeTa radiation of water vapour condensation and/or deposition during fog and cloud formation. First of all, it is not surprising that anomalies were detected in the zones of tectonic breaks, because only these zones had been considered in [26-36]. Indeed, in [
the process of vapour condensation.
With respect to Morozova [
It has to be mentioned that, sometimes, together with endogen heat, authors of [26-36] discuss a water vapour condensation as a possible infrared source: “Water vapour is transformed in a fog. The heat of the phase transition is liberated, the radiometers of satellites ‘see’ this heat” [
In this part of the paper, a qualitative model of Juvenal increased infrared emission is proposed. The model explains the nature of Juvenal unusual colour, and, especially, its red spots, which are a subject of numerous scientific discussions. The famous images of Jupiter captured by NASA’s Voyager spacecraft and the Hubble Space Telescope, show that Jupiter has many shades of white, orange, brown, yellow and even red. Only the following explanation of this phenomenon has been seriously discussed [40,41]. The coloration in the clouds of Jupiter is caused by upwelling compounds, known as chromophores, which change colour when they are exposed to ultraviolet light from the Sun. The substances are believed to be phosphorus, sulphur, or possibly hydrocarbons. These chromophores mix with the warmer, lower deck of clouds. The zones of different colours are formed when rising convection cells form crystallising ammonia that masks out these lower clouds from view. A criticism of the model is not the aim of this paper, but the main weak points of this model will be mentioned. First of all, only quantities of chromophores less than 1 ppm have been detected in the Juvenal atmosphere. In addition, the statement from the paper [
It is well-known that the Jupiter emits approximately three times the energy that it receives from the Sun. The additional energy comes from the hot surface of the planet with circulation of its atmosphere. Our model may be briefly presented as follows: The intensive circulation in the Juvenal atmosphere lifts heated vapours, particularly of ammonium and water, which are condensed and solidified in the upper layers of the atmosphere. PeTa emission taking place during condensation and crystallisation seems to be the reason for the emission of infrared radiation, complementary to the equilibrium Planck’s radiation in Jupiter. Under high pressure, emission of red characteristic radiation (RCR) seems to be a possible part of PeTa radiation. Next, it would follow as a natural consequence, that PeTa emission displaces the visual colour of the planet into the red range. The red spots are the stable atmospheric vortexes. The processes of condensation and solidification, and hence coloration due to PeTa radiation, must be more intensive there. In [11-15], we have mentioned a possibility of these processes in the Juvenal atmosphere.
The Juvenal cloud structure and atmospheric pressure is notably important for our model. The only spacecraft to have descended into Jupiter’s atmosphere and to have taken scientific measurements is Galileo. This spacecraft sent an atmospheric probe into Jupiter upon arrival in 1995: next, it entered Jupiter’s atmosphere, where it burned up in 2003. Ice clouds of ammonia (NН3), ammonium hydrosulphide (NH4SH), and water were recorded. The average content of water and ammonia in the Juvenal atmosphere is 0.1% and, 0.02% [
We are aware of the weak points of our brief model. This model is a first step of applying the PeTa effect to Juvenal atmospheric processes. There are many further analyses to perform. First, spectra of PeTa emission have to be determined for the atmospheric components. Secondly, the windows of transparency, absorption and reemission, have to be taken into account. However, in any case, the PeTa effect exists, and it has to be accounted for in all atmospheric models.
In our experiments, radiation occurs during condensation or/and the deposition of air components. Only the PeTa effect can explain this radiation.
According to the principles of quantum electro dynamics, the presence of the described spontaneous transitions, and as a result, PeTa radiation, should lead to an opportunity to stimulate such transitions. For example, crystallization by irradiation of the substance close to the temperature of crystallisation at a resonant frequency corresponding to the particular transition, can be stimulated. Such opportunities, which have not been investigated experimentally to date, should uncover new effects. For instance, fog or ice cloud formation may occur as a result of atmosphere irradiation by characteristic radiation. At the same time, the primary laser beam will be amplified. In this way, the PeTa energy of water condensation or freezing in the atmosphere can be accumulated.
The second method of atmospheric PeTa energy accumulation could use an infra-red laser and be based on water vapour condensation or freezing in atmosphere. Let us imagine a system of two parallel mirrors (one of them is semi-transparent) of area of 1 m2 and at the distance of 1 m each from each other. Let us locate this system in the atmosphere where water vapour is saturated but is not yet condensed, for instance, on the slope of the mountain Primorski (approximately lower 1000 m), or on the slope of Taibei (approximately lower 2800 m) (Figures 8(a) and (b)). Let us provoke condensing of vapour with a special salt spray, radioactive source radiation, characteristic PeTa radiation, etc. In this case approximately 5 g (the temperatures are 271 K and 284 K, respectively) of water vapour will be condensed in our system. This means that 12.4 kJ of energy will be liberated and the system would work as a laser. For 8% laser efficiency, the energy of 1kJ would be radiated. The movement of air inside the system with a speed of 1 m/s (a result of a natural convection) would provide a generator with 1 kW power. This could be a pulse generator with a frequency of 1 Hz. For comparison, a silicon solar cell of area 1 m2, with an efficiency of 14%, provides 100 W of power. Thus, PeTa radiation would be used for atmospheric energy accumulation, and together with the solar, wind, geothermal and falling water energies, provides the fifth source of ecologically pure energy.
Our experiments allow estimation of both range and order of intensity of PeTa radiation. We demonstrate that the PeTa effect not only exists, but the power of PeTa radiation is significant and must be considered in all calculations of energetic balance for the atmospheres of Earth and other planets [
Our experiments explain why 6.7 µm wave-length IR radiation is used for water vapour registration in the Earth’s atmosphere.
Although theory [6,8] seemed to give a satisfactory, and, to a certain extent, quantitative explanation of the phenomenon under investigation, this explanation lacked full quantitative basis.
There are two facets of the experiment that could improve the recording of the energetic balance of the atmosphere. The first result is the exact PeTa spectrum of the phase transitions of water at the actual temperature and pressure values. The second is the value of PeTa radiation yield at the same conditions. We hope to be able to present these results in the near future.
We could also use these radiation measurements to find if there is water in the atmospheres of other planets, for instance, Mars.
This radiation may explain Jupiter’s red colour and its infrared emission. It is well-known that Jupiter emits more energy than it receives from the sun. Circulation in Jupiter’s atmosphere lifts the heated ammonium and water vapours, which are condensed and solidified in the upper part of the atmosphere. The PeTa radiation of these processes seems to be the reason for the emission of infrared radiation which displaces the planet’s colour in the red range.
A similar process could be applied for artificial cooling of Earth: creating upper cirrus clouds using characteristic PeTa radiation and, as a result, leading to heat emission into space.