Experimental research on the mechanism of chemical energy conversion to light energy under thermal induction

Since the discovery of glare illuminators, considerable eff orts have been devoted to achieving a breakthrough of high light intensity on the order of magnitude. In this paper, we prepared strong fl ash blinding agents for the fi rst time by using aluminum powder, oxidant, and adhesive as the main materials, and tris-(8-hydroxyquinolinato) aluminum (Al2q3), triazoindolizine, or nano zinc oxide, etc. as electronic output brightener after mixing and granulation according to the developed formulation. It was discovered that the luminescence intensity was related to the thermal eff ect of the substance while the brightener only served as an auxiliary brightening eff ect to achieve energy non-destructive conversion. With the same formula, the luminescence intensities of glaze agents with ADN and potassium perchlorate as oxidants were slightly higher than that of ammonium perchlorate oxidant; the brightening eff ect of nano-zinc oxide was slightly higher than those of tris-(8-hydroxyquinolinato) aluminum (Al2q3) and triazoindolizine. The luminescence intensity of the substance with a high thermal eff ect value was high, but the luminescence time was slightly short. Under identical conditions, the luminescence eff ect of nano-aluminum powder was obviously better than that of micro-aluminum powder with the highest luminescence intensity of 3.9 × 1010 ~ 1.9 × 1011 cd and the luminescence time of 39 48 ms. The eff ects of shell material and structure and the eff ect of heat-induced mode on the luminescence intensity were also investigated. The luminescence intensity of the glare agent with a high shell strength was high, but the luminescence time was slightly short. Moreover, the energy level of the brightener is excited under the induction of high temperatures, which leads to a blue shift to promote the chemical reaction of the material in a favorable direction. Finally, the optical radiation of the thermally induced high-temperature combustion system was analyzed from the aspects of thermal eff ect, combustion temperature, and chemiluminescence eff ect. A way to improve the optical radiation intensity of a high-temperature combustion system was proposed.


Introduction
The production of light includes natural light, thermal radiation light, electroluminescence, photoluminescence, chemiluminescence and bioluminescence [1][2][3][4]. The luminescent system is a reaction system that includes the conversion of chemical energy and light energy, that is, the chemical substance itself contains high chemical energy, which is mostly converted into light energy through the combustion reaction, and then released in the form of strong radiant light [5,6]. Later, people discovered that the illuminating light was controllable in electroluminescence, and the illuminance could be enhanced by chemical substances [7,8]. After exploring the materials in the d track [5], we obtained high-quality organic electroluminescent diodes (OLED), which provided humans with high-quality, durable, and low-cost lighting [9][10][11].
Inert gas can produce plasma effect under the conditions of explosive shock compression [12], high temperature and high-pressure plasma effect will produce tens of thousands of degrees or even hundreds of thousands of degrees of high temperature, extremely strong optical radiation (such as explosive electromagnetic wave plasma laser ammunition) [13]. Explosion excitation can emit plasma light and ultraviolet light at the same time [14], while the working luid of the condensed phase high-temperature combustion system burns under normal pressure and emits infrared light [15].
In this paper, high-activity nano-aluminum powder, oxidizing agent, and adhesive are used as raw materials to cooperate with brighteners, using thermal radiation to induce electron excitation luminescence, and the wavelength is 420 nm ~ 760 nm, the highest luminous intensity is 3.9 × 10 10 ~ 1.9 × 10 11 cd, and the luminescence time 39 ~ 48 ms, the luminous working medium realizes the electronic output control and brightness enhancement. The discovery in this study is of great signi icance for improving the lighting effect of existing illuminating lare and for developing nonlethal new ammunition for special purposes.

Experimental equipment, devices and processes
The experimental materials include nano-scale aluminum, potassium perchlorate, brightener, glue, etc. The preparation process is as follows. Spherical aluminum powder 40 -80 nm and oxidant were mixed according to the formula ratio. After a 2% ~ 5% brightener was added to the resulting mixture, the mixture was mixed homogeneously according to the dry mixing method. The homogeneous mixture was transferred to a container, in which the mixture was mixed with 0.6% -0.85% of glue (as a percentage by weight of solids). Through the processes of kneading, granulating, and vacuum drying, strong light blinding agent dry granular was obtained with total volatiles less than 1.0%. The dry granular was illed in a constrainable shell consisting of a deferred ignition tube and a high-energy pyrotechnic charge, which was placed in a mace-shaped ire-transfer mechanism made of celluloid. When the ignition tube is applied, the lame is sprayed to heat and ignite the high-energy pyrotechnics. The lame generated by the high-energy pyrotechnics rapidly radiates heat to the strong light-blinding agent and propagates to the depth through the mace-shaped ire transfer system. As a result, explosive luminescence occurs under thermal and pressure excitation conditions. The luminescence intensities of the 100 g and 200 g glare blinding agents were examined experimentally, and the light intensities at 10 m to 100 m were recorded by a photometer and a Kistler transient recorder. The test device for exciting the strong light by thermal radiation is shown in igure 1. Table 1 records the process of thermal radiation excitation and the luminous intensity. The light intensity test results show that the luminous intensity of nano-aluminum powder, KClO 4 , ADN, etc. are used as oxidants, and triazoindolizine and nano-zinc oxide are used as brighteners to form a strong light system. The luminous intensity reaches 10 8 cd ~ 10 11 cd, followed by other materials. As the luminous intensity increases, the luminous time decreases.

Discussion
Combining the experimental results, we will discuss the optical radiation of the high-temperature combustion system from the perspectives of thermal effect, combustion temperature, and chemiluminescence effect, and theoretically analyze the way to improve the luminous intensity of the hightemperature thermal radiation system through the lossless conversion of energy under thermal radiation excitation conditions.

1) The relationship between material composition and luminous effect
In addition to the temperature radiation of hot solids and liquids, the optical radiation of high-temperature combustion systems also has chemiluminescence effects. Because the combustion system is a chemical reaction system, nonequilibrium radiation output can be observed. During the chemical reaction process, some atoms or molecules may be in a higher energy state and may radiate light energy before reaching thermal equilibrium (usually through collision) [16]. The system has the potential to surpass the black body radiation, and the thermal radiation is restricted by the black body radiation, and the luminous intensity has an upper limit.
The laser is a well-known strong light source. Certain chemical reaction systems can directly exhibit laser behavior [17]. The necessary and suf icient conditions are the lipped  distribution of the particle vibration state, that is, the number of particles in the excited state increases; the concentration of luminescent particles reaches a certain threshold, low at this value, no effective luminescence can be produced [18]. The excitation of the high-temperature combustion system may also produce the above behavior, which may provide energy beyond the thermal equilibrium or black body radiation. Due to the quantum effect and surface effect of nano-aluminum powder, the luminous intensity increases up to 10 11 cd, and the different types of oxidants have little effect on the luminous intensity.

2) Thermal effect and luminous intensity
The light radiation of the high-temperature combustion system is related to the heat released when the reactant burns. High thermal effect value and strong light radiation. The thermal effect of the combustion system can be calculated by Guess's law. The thermal effect of a typical binary high-energy combustion system under the conditions of zero oxygen balance (oxygen difference n = 0) and negative oxygen balance (n = -20), as the value of oxygen difference n decreases, the thermal effect of the system increases.
Combustion temperature is an important factor affecting the light output of the system. Because the optical radiation of most high-temperature combustion systems is mainly the thermal radiation of hot solids and liquids in the lame, which is governed by the absolute black body radiation law.
The higher the temperature, the greater the total radiant energy. Therefore, the best light radiation system for thermal radiation effect is a system with a high combustion temperature similar to a black body.
In the formula: T -Combustion temperature, ℃; Q -Combustion heat, kJ; Σ(Q s +Q k ) -The sum of melting heat and vaporization heat of combustion products, kJ; ΣC p -Total heat capacity of combustion products, kJ/℃ o Some combustion reactions lack thermodynamic data, so it is more dif icult to use the above formula to calculate. However, the molar atomic heat Q 3 (kJ/mol) of the oxides produced by the combustible agent can be used to estimate the combustion temperature, because the temperature is proportional to Q 3 in the approximate irst combustion reaction. The Q 3 values of Mg, Al, and Zr are 305, 331, and 364 kJ/mol, respectively. In addition, the combustion temperature can also be compared based on the melting point and boiling point of the formed oxide. The higher the melting point and boiling point of the formed oxide, the higher the combustion temperature of the system.
Judging from the Q 3 value and the melting point and boiling point of the oxide, the Zr-containing system can obtain a higher combustion temperature, and the theoretically calculated value is up to 6200 ℃, which is higher than that of the Mgcontaining and Al-containing systems. It has been reported in the literature that the combustion temperature of the Zr-O system has been measured to reach 4950K, and is generally around 4000K [19], while the combustion temperature of the Mg/Al-containing combustion system is generally around 3500K [20]. According to Wien's displacement law, the maximum radiation wavelength is inversely proportional to the temperature T.
From the equation (4), it can be calculated that the maximum radiation wavelength of the combustion system containing Mg and Al should be about 960nm, which is in the infrared region; While the maximum radiation wavelength of the Zr-containing system is about 580 ~ 725 nm, which is just in the visible light region, which is the optical ef iciency. Large area, which can produce stronger light radiation. Increase the calori ic value of the material and increase the luminous ef iciency. The radiation wavelength is close to the UV direction from infrared light, and the luminous intensity is the highest.
Using Planck's law, the difference in radiant energy of different systems can be seen more clearly. M λ -the radiation emission of light with a wavelength of λ at temperature T, W/(m 2 .μm); C 1 -the irst radiation constant; C 2 -the second radiation constant. Figure 2 is the use of the above formula to make the radiant energy curve with wavelength when the temperature is 4950K, 4000K and 3000K.
It can be clearly seen from igure 2 that the total radiant energy has a maximum value when the radiation temperature is 3400K ~ 4950K, most of the wavelengths fall within the range of 420 ~ 760 nm, and when the temperature is below 3400K, it is more concentrated in the wavelength of the infrared and visible light range.
from the aspects of thermal effect, combustion temperature, luminescent composition and photochemical effect, excitation mode and shell material.
It was discovered for the irst time that the luminous intensity is related to the thermal effect of the substance. The luminous intensity with a high thermal effect value is higher, but the luminous time is slightly shorter, and the brightener only plays a role in regulating and increasing the brightness to realize energy lossless conversion. When the conditions are the same, the luminous effect of nano-aluminum powder is obviously better than that of micron-level aluminum powder, with the highest luminous intensity reaching 3.9 × 10 10 ~ 1.9 × 10 11 cd, and the luminous time is 39 ~ 48 ms. The reason for the increase in luminous intensity is the quantum effect and Due to surface effects; different types of oxidants have little effect on the luminous intensity, and when the oxidant is ADN and potassium perchlorate in the same formula, the luminous intensity is slightly higher than that of ammonium perchlorate; it is found and veri ied that the lightenhancing effect of nano-zinc oxide is slightly higher than tris (8-hydroxyquinoline) aluminum (Al2q3) and triazoindolizine, the brightener undergoes an energy level jump induced by high temperature, resulting in the release of electronic excitation energy, and a blue shift to promote the chemical reaction of the material toward the light intensity Increase the direction of development, which is basically consistent with the results of the blue shift of the LED. The excitation time can be adjusted by improving the structure, which is conducive to generating a suf iciently high temperature and maintaining it for a long enough time to achieve the maximum luminous ef iciency.

Conclusion
In our research, we prepared strong lash blinding agents for the irst time by using aluminum powder, oxidant, and adhesive as the main materials, as well as electronic output brightener selected from tris-(8-hydroxyquinolinato) aluminum (Al2q3), triazoindolizine, or nano zinc oxide. The luminous characteristics of different media under different excitation modes are systematically studied. The factors affecting the luminous intensity are discussed separately