Experimental phase

High-purity (99.9%), “Skyspring Nanomaterials, Inc.,” US-made amorphous nano-SiO₂ was used to study the amount, formation rate, and radiation-chemical yield of molecular hydrogen obtained from water radiolysis processes in the created nano-SiO₂/H₂O systems with a particle size of d = 20 nm under the influence of γ-quanta. Nano-SiO₂ was cooled after heat treatment in the open air at a temperature T = 773 K for t = 72 hr, then the necessary mass (m = 0.2 g) was added to the ampoule (V = 9 ml), cleaned, and thermally treated (T = 773 K) under special conditions. Nano-SiO₂ inside the ampoule was thermally treated (T = 673 K) for 4 hr under vacuum conditions (P = 10⁻³ mmc.st.) and then cooled and sealed by expelling the required amount of bidistilled water purified from air under special conditions (Pikaev, Reference Pikaev1975).

The ampoule was irradiated in a ⁶⁰Co source with a dose rate of P = 9.276 rad/s at room temperature. Absorbed dose strength was determined using ferrous sulfate and methane methods. In a specific research object, the strength of the absorption dose was calculated using electron density comparison methods (Jafarov et al., Reference Jafarov, Garibov and Aliev1987; Pikaev, Reference Pikaev1975).

It was analyzed that H₂, O₂, and H₂O₂ are the final molecular products obtained from the radiation-heterogeneous decomposition of water in the nano-SiO₂/H₂O created system. Since part of O₂ of these products is trapped on the catalyst surface and H₂O₂ is in solution, it creates great difficulties in determining their amounts. Therefore, more accurate information about the kinetic regularity of the products obtained from the radiation-heterogeneous decomposition processes of water was made based on the amount of molecular hydrogen.

The amount of obtained molecular hydrogen was analyzed in an “Agilent-7890” chromatograph. To confirm the results, a modernized “Tsvet-102” chromatograph (accuracy 8–10%) was also used in parallel. A column with a length of 1 m and an inner diameter of 3 mm was used in the “Tsvet-102” chromatograph. Activated carbon with particle size d = 0.25 ÷ 0.6 mm was used inside the column, and argon gas with a purity of 99.99% was used as a gas carrier in both chromatographs.

Results and discussion

The reliance chart of the sum of atomic hydrogen obtained from the radiation-heterogeneous decay of water within the frameworks made by changing the mass of water (m = 0.01 (1), 0.02 (2), 0.04 (3), 0.08 (4), 0.2 (5), 0.4 (6), and 0.8 g (7)) included to nano-SiO₂ with the mass m = 0.2 g and molecule estimate d = 20 nm under the impact of γ-quanta (⁶⁰Co, P = 9.276 rad/s, T = 300 K) on the radiation time (dosage) is given in Figure 1.

Figure 1.

The dependence of the amount of molecular hydrogen obtained from the radiation-catalytic decomposition of water in the systems created by addition of water with the mass of m = 0.01 (1), 0.02 (2), 0.04 (3), 0.08 (4), 0.2 (5), 0.4 (6), and 0.8 g (7) to nano-SiO₂ with the mass m = 0.2 g and particle size d = 20 nm under the influence of γ-quanta (⁶⁰Co, P = 9.276 rad/s, T = 300 K) on the radiation time.

From the linear parts of the kinetic curves (Curves 1–7 in Figure 1) obtained from the studied systems (nano-SiO₂/H₂O), the formation rates of molecular hydrogen (Jafarov, Reference Jafarov2022) were determined for water, nano-silica, and the total system. The formation rate of molecular hydrogen obtained from the radiolysis of pure water was determined based on the following expression:

(1) $$ {w}_0\left({\mathrm{H}}_2\right)\hskip0.35em =\hskip0.35em 0,01{G}_0\left({\mathrm{H}}_2\right)P $$

where G ₀(H₂) = 0.45 molecule/(100 eV) is the radiation-chemical yield of molecular hydrogen obtained from the radiolysis of pure water, and P is the strength of the absorbed dose of the radiation source. From the kinetic part of the curves in Figure 1, the formation rate of molecular hydrogen was determined for water in the nano-SiO₂/H₂O system as

(2) $$ {w}_{{\mathrm{H}}_2\mathrm{O}}\left({\mathrm{H}}_2\right)\hskip0.35em =\hskip0.35em \frac{N\left({\mathrm{H}}_2\right)}{m_{{\mathrm{H}}_2\mathrm{O}}t} $$

for the total nano-SiO₂/H₂O system as

(3) $$ {w}_{tot}\left({\mathrm{H}}_2\right)\hskip0.35em =\hskip0.35em \frac{m_{{\mathrm{H}}_2\mathrm{O}}}{m_{{\mathrm{H}}_2\mathrm{O}}+{m}_{{\mathrm{SiO}}_2}}{w}_{{\mathrm{H}}_2\mathrm{O}}\left({\mathrm{H}}_2\right) $$

and for nano-SiO₂ as

(4) $$ {w}_{{\mathrm{SiO}}_2}\left({\mathrm{H}}_2\right)\hskip0.35em =\hskip0.35em \frac{m_{{\mathrm{H}}_2\mathrm{O}}}{m_{{\mathrm{SiO}}_2}}\left[{w}_{{\mathrm{H}}_2\mathrm{O}}\left({\mathrm{H}}_2\right)-{w}_0\left({\mathrm{H}}_2\right)\right] $$

where the amount of molecular hydrogen obtained from the water radiolysis in the N(H₂)-nano-SiO₂/H₂O system is the mass of $ {m}_{{\mathrm{H}}_2\mathrm{O}}- $ water, $ {m}_{{\mathrm{SiO}}_2}- $ nano-SiO₂, and $ {m}_{tot}\hskip0.35em =\hskip0.35em {m}_{{\mathrm{SiO}}_2}+{m}_{{\mathrm{H}}_2\mathrm{O}}- $ the total system. In those systems, the formation rates of molecular hydrogen obtained from the water radiation-catalytic decomposition determined for the water (2), total system (3), and nano-SiO₂ (4) are given in Table 1.

Table 1.

The formation rates of molecular hydrogen obtained from the radiation-catalytic decomposition of water in the systems created by the addition of water with the mass of m = 0.001, 0.003, 0.01, 0.02, 0.04, 0.08, 0.2, 0.4, and 0.8 g to the nano-SiO₂ with the mass of m = 0.2 g and the particle size of d = 20 nm under the influence of γ-quanta (⁶⁰Co, P = 9.276 rad/s, T = 300 K)

Table 2 shows the dependence of the radiation-chemical yield of molecular hydrogen determined for the total system, water, and nano-SiO₂ on the water mass on the basis of those rates ( $ {w}_{tot}\left({\mathrm{H}}_2\right) $ , $ {w}_{{\mathrm{H}}_2\mathrm{O}}\left({\mathrm{H}}_2\right) $ , and $ {w}_{{\mathrm{SiO}}_2}\left({\mathrm{H}}_2\right) $ ).

Table 2.

The radiation-chemical yield of molecular hydrogen obtained from the radiation-catalytic decomposition of water in the systems created by the addition of water with the mass of m = 0.001, 0.003, 0.01, 0.02, 0.04, 0.08, 0.2, 0.4, and 0.8 g to the nano-SiO₂ with the mass of m = 0.2 g and the particle size of d = 20 nm under the influence of γ-quanta (⁶⁰Co, P = 9.276 rad/s, T = 300 K)

Figure 2 shows the graphs of the dependence of the radiation-chemical yield of molecular hydrogen on the water mass determined for the total system (curve 1), water (curve 2), and nano-SiO₂ (curve 3) based on those rates ( $ {w}_{tot}\left({\mathrm{H}}_2\right) $ , $ {w}_{{\mathrm{H}}_2\mathrm{O}}\left({\mathrm{H}}_2\right) $ , and $ {w}_{{\mathrm{SiO}}_2}\left({\mathrm{H}}_2\right) $ ).

Figure 2.

Dependence of the radiation-chemical yield of molecular hydrogen determined for the total system (curve 1), water (curve 2), and nano-SiO₂ (curve 3) obtained from radiation-catalytic decomposition of water in the created systems nano-SiO₂/H₂O with a mass of $ {m}_{{\mathrm{SiO}}_2} $ = 0.2 g and a particle size of d = 20 nm under the influence of γ-quanta (⁶⁰Co, P = 9.276 rad/s, T = 300 K) on the water mass.

To explain the obtained results, let us establish a model. If we consider a nanoparticle as a sphere with radius R, then its volume can be determined based on the following expression:

(5) $$ {V}_{\mathrm{sph}..}\hskip0.35em =\hskip0.35em \frac{4}{3}\pi {R}^3 $$

If the space between the nanoparticles is completely filled with water, then, if each particle is described as a cube with the edge 2R together with the corresponding water, the volume of water around the particle can be determined as follows:

(6) $$ {V}_{wat.}\hskip0.35em =\hskip0.35em {V}_{cub.}-{V}_{sph..}\hskip0.35em =\hskip0.35em {(2R)}^3-\frac{4}{3}\pi {R}^3\hskip0.70em =\hskip0.70em \left(8-\frac{4}{3}\pi \right){R}^3 $$

The mass of water can be defined as m_wat = ρ_wat.⋅V_wat, and the mass of nanoparticle can be defined as m_sph. = ρ_sph.⋅V_sph. Taking into account the data, the ratio of the mass of water to the mass of the catalyst can be calculated as follows:

(7) $$ \frac{m_{wat}}{m_{cat}}\hskip0.35em =\hskip0.35em \frac{\rho_{wat}\cdot {V}_{wat}}{\rho_{cat}\cdot {V}_{cat}}\hskip0.35em =\hskip0.35em \frac{\rho_{wat}}{\rho_{cat}}\frac{\left(8-\frac{4}{3}\pi \right){R}^3}{\frac{4}{3}\pi {R}^3}\hskip0.35em =\hskip0.35em \left(\frac{6}{\pi }-1\right).\frac{\rho_{wat}}{\rho_{cat}} $$

Apparently, this ratio does not depend on the size of the nanoparticle. Considering the data $ {\rho}_{{\mathrm{SiO}}_2}\hskip0.35em =\hskip0.35em $ 2.33 g/cm³ and $ {\rho}_{{\mathrm{H}}_2\mathrm{O}}\hskip0.35em =\hskip0.35em $ 1 g/cm³, this ratio is approximately 40%. That is, water added in excess creates a liquid phase on the surface. Therefore, the yield of molecular hydrogen gradually decreases (determined by the total system).

The obtained results can be explained on the basis of known mechanisms of radiation physics and chemistry. Due to the effect of γ-quanta, non-equilibrium energy carriers—electrons $ \left({e}^{-}\right) $ , holes $ \left({\mathrm{SiO}}_2^{+}\left({h}^{+}\right)\right) $ , and electron-excitation states ( $ {\mathrm{SiO}}_2^{\ast } $ –excitons)—are formed inside the nanoparticle. This process can be symbolically described as follows:

(8) $$ {\mathrm{SiO}}_2\overset{\gamma }{\to }{\mathrm{SiO}}_2^{+}\left({h}^{+}\right),{\mathrm{SiO}}_2^{\ast },{e}^{-} $$

If the energy spent on the formation of an electron–hole pair in SiO₂ under the influence of ionizing rays (γ-quanta, electrons) is 19.1 eV (Aussman & McLean, Reference Aussman and McLean1975), then the radiation-chemical yield of the electron–hole pair is equal to G(h⁺–e⁻) = 5.2 pair/(100 eV). A part of the formed electron–hole pair can be recombined within the particle due to the Coulomb interaction (the Onsager effect). The other part of the holes migrates according to the drift mechanism (Levin et al., Reference Levin2008): one part is captured by structural defects in the volume, and the other part is transported to the surface of the nanoparticle and captured by the adsorbed complex $ \left[{\mathrm{SiO}}_2-{\mathrm{H}}_2{\mathrm{O}}_2\right] $ of water on the surface, forming the ion complex:

(9) $$ \left[{\mathrm{SiO}}_2-{\mathrm{H}}_2{\mathrm{O}}_s\right]+{h}^{+}\to {\left[{\mathrm{SiO}}_2-{\mathrm{H}}_2{\mathrm{O}}_s\right]}^{+} $$

By recombining that ion complex with thermal or tunneling electrons, they cause electron excitation of the complex:

(10) $$ {\left[{\mathrm{SiO}}_2-{\mathrm{H}}_2{\mathrm{O}}_s\right]}^{+}+{e}^{-}\to {\left[{\mathrm{SiO}}_2-{\mathrm{H}}_2\mathrm{O}\right]}^{\ast } $$

On the other hand, the excitons generated by ionizing radiation can be absorbed inside the nanoparticle and transfer their energy to the water complex adsorbed on the surface. At this time, the electron excitation of the complex takes place:

(11) $$ exc+\left[{\mathrm{SiO}}_2-{\mathrm{H}}_2{\mathrm{O}}_s\right]\to {\left[{\mathrm{SiO}}_2-{\mathrm{H}}_2\mathrm{O}\right]}^{\ast } $$

The energy of the short-lived electron-excitation complex $ {\left({\mathrm{SiO}}_2\hbox{-} {\mathrm{H}}_2{\mathrm{O}}_s\right)}^{\ast } $ (Alba-Simionesco, Reference Alba-Simionesco2010) is transferred to the adsorbed water molecule, causing its decomposition, and as a result, H and OH intermediates are formed:

(12) $$ {\left[{\mathrm{SiO}}_2-{\mathrm{H}}_2\mathrm{O}\right]}^{\ast}\to {\mathrm{SiO}}_2-\mathrm{OH}+\mathrm{H} $$

In order to obtain intermediate products H and OH from the decomposition of a water molecule, it is necessary to break the bond between them (E _bond = 5.1 eV). Therefore, the energy of the transferred exciton (E _exc) and the bonding energy must satisfy the condition E _exc ≥ E _bond.

On the other hand, the electrons molded inside the nanoparticle under the effect of radiation and each unused time of δ-electrons they make consistently lose their energetic imperativeness in adaptable and inelastic collisions inside the atom and, while some of them are captured by auxiliary forsakes inside the particle, some are transported to the surface of the atom. Among the electrons transported to the surface, a parcel of which engine essentialness is more diminutive than the surface potential is localized on the surface, and a parcel returns into the particle, while the greater ones are emanated into the water after crossing the surface of the particle. Electrons transmitted from the surface of a strong into water steadily lose their motor vitality in dipole unwinding, flexible and inelastic collisions, initially turn into warm electrons, and after that, they can be solvated (Liu et al., Reference Liu, Zhang and Thomas1997):

(13) $$ {e}^{-}+n{\mathrm{H}}_2\mathrm{O}\to {e}_{aq}^{-} $$

It has been proved both experimentally (Dimitrijevic et al., Reference Dimitrijevic, Henglein and Meisel1999) and theoretically (Ouerdane et al., Reference Ouerdane, Gervais, Zhou, Beuve and Renault2010) that the radiation-chemical yield of electrons solvated in the liquid phase (12) is higher in comparison with pure water in the created nano-SiO₂ systems suspended in water, and this value changes depending on the size of the nanoparticle.

We can describe the obtaining of molecular hydrogen from the radiolytic decomposition occurring between electrons solvated $ \left({e}_{aq}^{-}\right) $ in the interparticle liquid phase and water molecules as

(14) $$ 2{e}_{aq}^{-}+2{\mathrm{H}}_2\mathrm{O}\to {\mathrm{H}}_2+2{\mathrm{OH}}^{-} $$

atomic hydrogen:

(15) $$ {e}_{aq}^{-}+\mathrm{H}+{\mathrm{H}}_2\mathrm{O}\to {\mathrm{H}}_2+{\mathrm{OH}}^{-} $$

and protonated water molecules $ \left({\mathrm{H}}_3{\mathrm{O}}^{+}\right) $ :

(16) $$ {e}_{aq}^{-}+{\mathrm{H}}_3{\mathrm{O}}^{+}\to \mathrm{H}+{\mathrm{H}}_2\mathrm{O} $$

Finally, molecular hydrogen can also be obtained in the following form:

(17) $$ \mathrm{H}+\mathrm{H}\to {\mathrm{H}}_2 $$

From here, it is known that two electron–hole sets or two excitons are utilized to get one atomic hydrogen. Responses (8–12 and 17) basically play a part in getting atomic hydrogen from the radiation-heterogeneous deterioration of water adsorbed on the nano-SiO₂ surface under the impact of γ-quanta. Be that as it may, within the frameworks made by water adsorption on the nano-SiO₂ surface under the impact of γ-quanta, the radiation-chemical surrender of atomic hydrogen from water decay was less than 0.36 molecule/(100 eV). This implies that the surface vitality exchange centered on the nano-SiO₂ surface is exceptionally thin. When the interparticle space is filled with water, the radiation-chemical surrender of the electrons radiated from the strong surface to the fluid stage increases, and as a result, the radiation-chemical surrender of the atomic hydrogen obtained by responses (13–16) also increases.