Abstract
ZnO–SnO2–Ag(AgCl) nanocomposites consisting of hexagonal ZnO, tetragonal SnO2, metallic Ag and AgCl nanocrystals were prepared by wet polymer-salt synthesis. The materials were studied using optical and luminescent spectroscopy, SEM, EDS and XRD analysis. The ability to generate chemically active singlet oxygen and antibacterial activity of prepared materials against both gram-positive and gram-negative bacteria were tested. It was showed that Ag structural transformation starts in initial composite solutions and proceeds at all stages including drying and thermal treatment of ZnO–SnO2–Ag(AgCl) synthesis. During this transformation, Ag exists in different forms (ions, molecular clusters, metallic and salt (AgCl) nanoparticles) and structural states (free Ag+ ions and Ag-PVP complexes in the solutions; Ag+ ions embedded into oxides crystal matrices; molecular clusters in the solutions and in PVP-salt composites; nanoparticles). Synthesized ZnO–SnO2–Ag(AgCl) powders consist of small (about 50 nm) nanoparticles—“nanogenerators” of chemically active singlet oxygen. This provides high antibacterial activity of these materials against both gram-positive and gram-negative bacteria.
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1 Introduction
The development of new effective photocatalytic and bactericidal materials for medical and environmental applications is actual problem. Oxide photocatalytic and bactericidal materials are chemically durable, ecological, cheap and promising for wide practical applications [1,2,3,4,5,6,7].
It is known that the photogeneration of the chemically active oxygen is one of the main mechanisms in determining photocatalytic and bactericidal properties of oxide materials. The mechanisms of this phenomenon was studied and discussed in many works [4,5,6,7,8,9]. The effectiveness of this photogeneration depends on the characteristics of excited radiation and on the electronic structure and the morphology of oxide materials [6,7,8,9,10,11].
The formation of chemically active oxygen species occurs on the materials surface. So, the application of nanomaterials having high specific surface area provides significant enhancement of photocatalytic and bactericidal properties compared with macroscopic materials [12]. The values of specific area of material surfaces grow with a decrease in their particles sizes. It determines significant increase in the photocatalytic properties and antibacterial activity of highly disperse materials. The nanoparticles (NPs) forming chemically active oxygen under light irradiation are called “nanogenerators” which play a key role in the photocatalytic and bactericidal properties of oxide materials. Thus, the strategy of the new photoactive materials development should be focused on the study and optimization of these nanoparticles.
The hetero-structure consisting of two different closely packed oxide semiconductor NPs demonstrate significantly higher photocatalytic and bactericidal properties compare with single-component [13, 14]. This phenomenon is related to the spatial separation of photo-generated electrons and holes and the prevention of their recombination. Recombination processes strongly decrease the effectiveness of photo excitation of materials and reduce their photocatalytic and bactericidal properties.
ZnO and ZnO-based nanocomposites containing SnO2 or Ag additions have high photocatalytic and bactericidal properties and can be used in oncology [11,12,13,14,15,16,17,18,19,20,21,22,23]. Different nanomaterials containing ZnO NPs doped with silver compounds demonstrate high luminescent, photocatalytic and antibacterial properties and are very promising for different optical, environmental and medical applications [10, 23,24,25,26,27,28,29,30]. The plasmon-exciton interaction in these composites determines significant enhancement of their luminescence properties in near UV spectral range comparing with pure ZnO [24, 29,30,31]. It is worth noting that the structure, morphology and luminescence properties of ZnO-based nanocomposites doped with Ag significantly depend on the method of their preparation [24, 29,30,31,32,33].
Many different technological methods (electrospinning and subsequent calcination [25], liquid polymer-salt methods [30,31,32,33], sol–gel [34], hydrothermal synthesis [28], MOCVD [27], co-precipitation [35], ultrasonification [36]) have been applied for the synthesis of Ag-doped ZnO crystals.
Ag can be presents in different structural forms in ZnO-based nanocomposites depending on the method and technological conditions on their preparation. In [29] preliminary synthesis, Ag NPs were deposited on the surface of ZnO NPs for the formation of ZnO/Ag nanocomposites. Ag formed Ag2O NPs on the surface of ZnO micro-flowers [37] or nanofibers [25] which were formed earlier in the solution. In ZnO/Ag nanocomposites synthesized in [38] by spray pyrolysis or solvothermal methods all Ag also present in the form of NPs. Contrary, in ZnO/Ag nanocomposites prepared by sol–gel synthesis some part of silver was embedded into ZnO crystal matrix [39]. Diffusion of Ag+ ions into ZnO crystal matrix was discussed also in [40, 41]. Thus, the structural form of silver in ZnO/Ag nanocomposites depends on technological method used for their preparation and was discussed in many works.
The polymer-salt technique which involves the application of liquid film-forming solutions is simple, non-expensive and can be used for the preparation of different oxides [11, 18, 33, 42]. In this method, homogeneous and transparent solutions containing soluble polymer and thermally decomposable metal salts are used as oxide NPs precursors. The coated materials are subjected to drying followed by thermal treatment.
The aim of this work is focused on the polymer-salt synthesis of Ag-containing ZnO–SnO2 nanocomposites, the study of Ag influence on their structure, spectral and luminescence properties, the ability to generate singlet oxygen under light irradiation and their antibacterial activity against gram-positive and gram-negative bacteria. New high effective photoactive and bactericidal materials with the defects-engineered structure and the simple and cheap method of its fabrication were the targets of this study.
2 Materials and Methods
Aqueous solutions of Zn(NO3)2, SnCl2, AgNO3 and high-molecular polyvinylpyrrolidone (Sigma Aldrich, Mw = 1,300,000 g/mol) were used for powders synthesis. These solutions were mixed together at room temperature with vigorous stirring for 1 h. Small particles of AgCl were formed in the solutions during their mixing. Drying of the resultant homogeneous liquid mixtures was performed by air at 20 °C. Thermal treatment of dried samples was carried out at atmospheric pressure at 550 °C for 2 h. Such thermal treatment provides full decomposition of metal nitrates and PVP [18]. Nominal chemical compositions of prepared solutions and calculated chemical compositions of the obtained powders are given in Table 1.
XRD and SEM analysis was carried out for the study of the structure and morphology of prepared materials. Chemical composition and materials morphology were studied using microscope VEGA3 TESCAN with energo-dispersive analysis attachment Essence™ EDS.
The difference between nominal and analytical chemical compositions of prepared materials was < 5 wt%. The diffractometer Rigaku Ultima IV was used for XRD analysis of prepared materials. The diffraction patterns were scanned from 20° to 65° (2θ). UnitCell software was used to refine the unit cell parameters of prepared powders [43].
The measurements of materials luminescence spectra (λex = 370 nm) in visible spectral range (400–700 nm) were carried out using fluorescence spectrometer Perkin Elmer LS-50B. Double beam UV–Vis spectrophotometer Perkin-Elmer Lambda 650 was used for the measurements of absorption spectra.
It is known [6, 7] that chemically active singlet oxygen has characteristic luminescence band in NIR spectral diapason (λmax = 1270 nm). Photoluminescence spectra in NIR spectral range was obtained upon the excitation with two different HPR40E LEDs (emission band maximum at λmax = 370 nm; power density 0.35 W/cm2) and (λmax = 405 nm; power density 0.90 W/cm2).
The method described in [44] was used for the estimation of bactericidal properties of prepared coatings. The experiments were carried out at natural lighting conditions. The representatives of gram-positive bacteria Staphylococcus aureus ATCC 209P and gram-negative bacteria Escherichia coli ATCC 25922 were used as test bacteria. Bactericidal activity at room temperature was estimated by the measurement of the size of inhibited area, which is formed on surface containing bacteria. In the experiments, three samples of each powder were used and the test results were subsequently averaged.
3 Experimental Results and Discussion
Figure 1a presents absorption spectra of fresh solutions 1–4. Some bend at λ = 300–305 nm related to the absorption band of nitrate anions [45] is observed in absorption spectrum of solution 1. It is worth to notice that small AgNO3 additions into the solutions significantly increase absorption in UV spectral diapason and shift absorption edge into the longer wavelengths. It is worth to notice that the addition of even small amounts of AgNO3 into the solution leads to a significant increase of light absorption in UV spectral range (curves 2–4, Fig. 1a). The slight difference in chemical compositions between solutions 1 (curve 1) and solutions 2–4 (curves 2–4) cannot explained the observed difference in absorption spectra. It is possible to suggest that this phenomenon related to the fast formation of small molecular clusters Agn in these solutions. It is known [32, 33, 46,47,48,49,50] that such clusters have intensive absorption bands in UV spectral range. The comparison of absorption spectra of the solutions 2–4 (curves 2–4) shows that the increase of AgNO3 content (Table 1) leads to the growth of the amount of these silver clusters and shifts absorption edge into the longer wavelength diapason.
Characteristic plasmonic absorption band of silver NPs is absent in the solutions absorption spectra presented in Fig. 1a. This is related to the small AgNO3 content in solutions 1–4 (Table 1). Usually, the presence of this Ag plasmonic band in absorption spectra is the result of intensive reduction of silver ions and this band is shown often in the spectra of the solutions with high Ag content or subjected light irradiation [32, 33]. Spectral position of this band depends on the concentration of Ag NPs.
The transformation of Ag structural forms is significantly accelerated under light irradiation even at the presence of stabilizing additives [33]. However, some changes in the absorption spectra of our solutions are observed also after the storage in the darkness (Fig. 1b). This phenomenon is explained by the presence of PVP in solutions compositions (Table 1). Besides stabilization effect [51, 52], PVP in the solution can reduce Ag+ ions [53]. This reduction of Ag+ ions leads to the formation of an additional amount of silver clusters having absorption bands in UV spectral range. This phenomenon is responsible for the spectral changes in prepared solutions during their storage in the darkness.
The study of photoluminescence spectra in visible spectral range of prepared solutions confirms the formation of small silver molecular clusters. The intensity and spectral positions of luminescence bands of these clusters depend on their electrical charge + 1 or neutral clusters and the amounts of Ag atoms in the materials structure [48, 50, 54]. The photoluminescence spectra of solution 4 (Table 1) at different excitation wavelengths are shown in Fig. 2a. The luminescence bands with λmax ~ 490 nm and ~ 605 nm, described previously in [32, 33, 46, 48, 50] are seen in these spectra. According to [32, 33, 48, 50] the main input in the luminescence at 605 nm can be related to the presence of Ag2, Ag4, Ag+4 and Ag5 clusters.
Figure 3 shows SEM images at different magnification of the samples 4 (a,b) and 5 (c,d). It is seen that the samples contain grains with different shape and size which varies from 5 up to 20 μm. The application of high magnification (Fig. 3b, d) shows that these grains are not monolithic and have the structure consisting of small nanoparticles having size 50–60 nm. Such morphology provides high specific surface area that promotes high photocatalytic and bactericidal properties of the materials. The similar photos were observed for all prepared samples and the significant influence of Ag content on materials morphology was absent.
The data of energy-dispersive analysis of powder 5 are presented in Fig. 4. The peaks of main components (Zn, Sn, Ag, O) of prepared materials (Table 1) are observed in this diagram. The experimental data obtained by the EDS method showed consistency with the experimental and calculated chemical compositions of the synthesized powders.
XRD patterns of prepared powders with different Ag content (powders 4 and 8) are given in Fig. 5. Numerous peaks attributed to hexagonal ZnO crystals (JCPDS card No. 36-1451) and tetragonal SnO2 crystals (JCPDS card No. 41-1445), metallic Ag (JCPDS card No. 04-0783) and face-centered cubic (chlorargyrite) phase (reference JCPDS Card No. 31-1238) of the AgCl are observed in these patterns. The peaks of ZnO crystals are the most intense and the ratio between the intensities of these peaks is close to the standard data (JCPDS card No. 36-1451).
Significant growth of the intensities of AgCl and Ag peaks is observed with the increase in Ag content. The simultaneous presence of various forms of silver in powders can be associated with a complex transformation of its structural state during heat treatment in air atmosphere.
The influence of Ag doping on the crystallization mechanism of ZnO crystals and their structures was studied earlier in [25, 27, 34, 39, 40]. So, authors [34] reported that doping ZnO with Ag during sol–gel synthesis reduces the average ZnO crystal size.
Based on obtained XRD data it is possible to suggest that Ag ions penetrate inside the growing ZnO and SnO2 crystals and modified their structure increasing lattice parameters (Tables 2, 3). Similar results were observed previously in [39] for Ag-doped ZnO nanoparticles prepared by sol–gel method. The possibility of Ag+ diffusion from Ag2O powder into ZnO crystal matrix during thermal treatment at 200–250 °C was discussed also in [40]. The incorporation of Ag+ ions into the ZnO lattice through substitution of Zn2+ ions is difficult due to their higher ionic radius 1.22 Å in comparison with the radius of Zn2+ ions 0.74 Å [41].
Figure 6 demonstrates the dependence of the cell volumes of ZnO (a) and SnO2 (b) crystals from Ag content in prepared ZnO–SnO2–Ag(AgCl) materials. It is seen that the growth of Ag content leads to a significant cell expansion of both crystal oxides. The change of the parameters of the crystal cell at the incorporation of the doping component is well-known phenomenon. Such variations of ZnO crystal cell parameters at Gd doping were described previously in [55].
Observable ZnO and SnO2 crystal cells expansion in our samples can be related to the some features of polymer-salt synthesis. Our initial compositions included the mixtures of PVP and metal nitrates which were decomposed simultaneously with heat realization at 300–500 °C and formed oxides crystals [18] and Ag during the thermal treatment. So, the incorporation of Ag into ZnO and SnO2 matrices can be attributed to initial stages of their crystals formation and growth.
Besides the crystal cells distortion, Ag diffusion into ZnO and SnO2 crystals leads to the formation of structural defects in the crystals structures. Figure 7 demonstrates photoluminescence spectra of prepared powders in visible spectral range. The most intense peaks attributed to ZnO crystals [39, 41] defects are observed at 450 nm and 485 nm. Similar peaks of photoluminescence spectra of ZnO:Ag materials in this spectral region was observed previously in [31, 39, 41]. The observed intensive luminescence in visible spectral range indicates the high concentrations of structural defects in obtained nanocomposites. Taking in account the significant role of such defects in the enhancement of photocatalytic properties and antibacterial activity of oxide semiconductors [56,57,58], these results are important.
It is worth noting that even small Ag additions change significantly the luminescence intensity in visible spectral range and spectra shape. This agrees with the data reported in [41]. The addition of the big amount of Ag to the materials composition leads to the remarkable (more than 20 times) decrease of luminescence intensity (curve 4, Fig. 7). This phenomenon is related to the formation and growth of metallic silver nanoparticles in the materials with high silver contents. Metallic silver nanoparticles have strong absorption band in visible spectral range [23, 33] that determines the drastic reduction in the materials luminescence intensity with addition of Ag content.
The measurements of the photoluminescence in NIR spectral region showed that prepared powders generated the singlet oxygen under UV (370 nm) and blue (405 nm) light irradiation. Figure 8 shows photoluminescence spectra of the powders 5 (Fig. 8a, c) and 1 (Fig. 8b). The luminescence band of singlet oxygen with a maximum λmax = 1270 nm, which is characteristic of the 1Δg − 3Σg electronic transition [6, 7] are observed in these spectra. A slightly lower intensity of the singlet oxygen luminescence band is observed upon excitation by UV radiation (λex = 370 nm), compared with the use of blue light (λex = 405 nm), which is associated with the lower power of the UV LED used (see above).
The experiments showed high antibacterial activity of prepared powders against both gram-positive and gram-negative bacteria. Figure 9 demonstrates the photo of ZnO–SnO2-Ag(AgCl) powders 3 (samples 1) and 4 (samples 2) in Petri dish with the inoculums containing bacteria Staphylococcus aureus ATCC 209P. Bacteria-free zones around all samples are seen in this photo. The comparison of size of these zones around powder 4 (samples 2, Fig. 9) with higher Ag content is somewhat bigger.
Figure 10 shows diagrams illustrating the influence of Ag content in prepared powders on their antibacterial activities against Staphylococcus aureus ATCC 209P (a) and Escherichia coli ATCC 25922 (b). The increase of Ag content enhances the antibacterial activity of prepared powders against both gram-positive and gram-negative bacteria. Although the high bactericidal properties of silver are well known, in our materials some part of Ag is inside oxide crystals and observed their high antibacterial activity was not obvious.
4 Conclusion
ZnO–SnO2–Ag(AgCl) powders consisting of hexagonal ZnO, tetragonal SnO2 nanocrystals, metallic Ag and AgCl crystals were prepared by wet polymer-salt synthesis. Ag additions into ZnO–SnO2 materials significantly change their crystal structure, spectral, and luminescence properties.
Our experiments showed that Ag structural evolution starts in initial composite solutions and proceeds at all stages (drying, thermal treatment) of ZnO–SnO2–Ag(AgCl) material synthesis. During this transformation, Ag exists in different forms (ions, molecular clusters, metallic and salt (AgCl) nanoparticles) and structural forms (free Ag+ ions and Ag-PVP complexes in the solutions; Ag+ ions embedded into oxides crystal matrices; molecular clusters in the solutions and in PVP-salt composites; nanoparticles).
Silver content has a significant impact on these Ag structural forms and also on the oxides (ZnO; SnO2) crystal structure and luminescence properties of ZnO–SnO2–Ag(AgCl) nanocomposites. These nanocomposites demonstrate that the photoluminescence in a visible spectral range is related to different defects of ZnO crystal structure. The addition of even a small amount of Ag significantly changes the luminescence intensity and spectra shape.
Obtained ZnO–SnO2–Ag(AgCl) powders consist of small (about 50 nm) nanoparticles – “nanogenerators” of chemically active singlet oxygen. This is provides high antibacterial activity against both gram-positive and gram-negative bacteria.
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The work was funded by Russian Scientific Foundation (Grant No. 20-19-00559).
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Funding was provided by Russian Scientific Fund (20-19-00559).
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Evstropiev, S.K., Karavaeva, A.V., Nikonorov, N.V. et al. Structural Engineering of ZnO–SnO2–Ag(AgCl) Nanocomposites for the Medical Applications. J Inorg Organomet Polym 32, 4373–4383 (2022). https://doi.org/10.1007/s10904-022-02424-8
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DOI: https://doi.org/10.1007/s10904-022-02424-8