INTRODUCTION

Titanium dioxide (TiO2) is a very well-known and well-researched material due to the stability of its chemical structure, biocompatibility, and physical, optical, and electrical properties like white noncombustible and odorless powder with a molecular weight of 79.9 g/mol, boiling point of 2972°C, melting point of 1843°C, and relative density of 4.26 g/cm3 at 25°C. TiO2 is a poorly soluble particulate that has been widely used as a white pigment [1]. It has an optical and electrical properties like a highly refractive index, optical band gap of around 3.69 ± 0.10 eV, and exhibits blue shift with respect to the bulk anatase. TiO2 exists in three mineral forms: anatase, Rutile, and Brookite [2]. The Rutile type has a tetragonal crystal structure (with prismatic habit) and exhibits a sufficient light scattering effect without absorption virtually. With a dipyramidal habit and a crystalline structure that corresponds to the tetragonal system, the anatase type is typically employed as a photocatalyst when exposed to UV light [3, 4]. As a semiconductor, it has a somewhat smaller energy band gap (3.06eV) than anatase (3.23eV). The energy band gap (~3.06eV), as a semiconductor, is slightly lower than anatase (~3.23eV) [5]. This particular TiO2 is mostly utilized as a white paint pigment. Brookite type has an orthorhombic crystalline structure [6]. TiO2 is often favored in the anatase form because of its high photocatalytic activity, higher specific area, non-toxicity, photochemical stability, and relative affordability. It also has a stronger negative conduction band edge potential (higher potential energy of photogenerated electrons) [7].  Today, more than four million tons of TiO2 are manufactured annually, and this chemical is used in a variety of common products [8]. Fig. 1 illustrates an excipient used in the pharmaceutical business for the creation of sunscreen in the cosmetics sector as a colorant in white plastics and as a reasonably priced and nontoxic food pigment authorized by the appropriate European Union authorities for food additive safety [9]. In the past 10 years, researchers in the fields of physics, chemistry, and engineering have been more interested in the development of self-organized nanostructures and nanopatterns, which have a wide range of potential uses. The fundamental benefit of these procedures is that they can serve as examples of “smart” nanotechnology. It follows that it is not unexpected that a significant portion of modern materials research is focused on these nano-scale manufacturing methods. [10]. Given the significance of these two techniques for producing NPs, a comparison of their structural, morphological, and optical characteristics has been conducted. Nanostructures material has been created in recent years using a range of synthesis techniques, including hydrothermal and solvothermal [3, 11], direct oxidation method [12], chemical vapor deposition (CVD), and chemical precipitation [13], green synthesize [14],  electrodeposition [15], microwave [16], drop-casting [17],and spin-coating method [18]. Utilizing drop-casting and spin-coating, two supposedly “wet” techniques that are extremely comparable. In the first process, a spin-coater is required; in the second, it is not. Both techniques are well-known and straightforward and both instances employed the same solvent. The morphological and structural characteristics of the resultant thin films, however, unambiguously define them. Thin films are produced via the widely used, simple, and affordable drop-casting technique. Additionally, the films have simply adhered to corning glass substrates without the need for a binder. The easy drop-casting method is also a potential choice for large-area thin film deposition for technological applications [19]. The versatile sol-gel technology is used to create a range of ceramic materials. In a typical sol-gel process, the precursors, which are frequently inorganic metal salts or metal organic compounds like metal alkoxides, are hydrolyzed and polymerized to produce a colloidal suspension or solution [20]. The phase change from liquid sol to solid gel is caused by complete polymerization and solvent loss. Spin coating or dip coating are two methods that may be used to create thin coatings on a substrate. When the solution is poured into a mold, a wet gel will develop, and after additional drying and heating, the wet gel will harden into a thick ceramic. If the solvent in a wet gel is extracted under a supercritical state, a very porous and low-density substance known as an aerogel is created [21]. The spin coating process is one of the main methods for depositing material layers onto the flat surface of the substrate. This method’s foundation is the dispersion of a solution onto the substrates and anchoring it to them, which accounts for how simple it is. The turntable of this contraption was rotating at thousands of revolutions per minute under the control of the central force. The substrate is dried using this instrument [22].This study focuses on preparation TiO2 NPs using different concentrations and two different techniques (spin coating and drop-casting). In addition, study the influence of the concentration and preparing methods on the TiO2NPs properties and examined the performance structure as antibacterial activity.  

MATERIALS AND METHODS

Materials 

The materials used in this study include chemical materials like P-25 TiO2 powder (DIREVO Industrial Biotech, Germany).  Ethanol (Eth) (99% of purity, Brazil), Deionized distilled water (University of Baghdad, Conductivity 10 µs/cm), Glass substrate (Alfa Aesar A Johnson Matthey company.

Sample preparation

Cleaning the substrate is the first crucial step in creating an effective thin film. Before the deposition process, the soda Lima glass (20 mm× 20 mm ×2 mm) was ultrasonically cleaned in acetone and subsequently with 2-propanol for 20 min, and then rinsed with deionized water. The appropriate TiO2 concentration required to produce a homogenous coating on the substrate was determined depending on the literature review and used two different concentrations (60 and 120 g/L).  TiO2 solutions with different concentrations were created by mixing P-25 TiO2 powder with 200 mL of ethanol.  The mixtures were aggressively churned until uniform and white in color. 

Drop-Casting

The cleaned soda lime glass was carefully coated with each produced TiO2 nanoparticle (TiO2NPs) solution for 30 seconds (Fig. 2). The residual solvent was removed by heated the substrates at 100℃ for 10 min using the hot-plate device to evaporate all residual solvent and repeated this process three times. At this stage, TiO2NPs was obtained by annealed these substrates inside the furnace for one hour at 300℃. TiO2NPs may be made easily and affordably by drop casting, the dispersion volume and concentration have an impact on the film’s thickness and other characteristics as well. The film structure is influenced by the substrate’s wetness, the velocity of evaporation, and the drying procedure. This method has a number of drawbacks, including difficulty controlling film thickness and non-uniform film formation on large wafers [23].

Spin-Coating

P-25 TiO2 powder was combined with 200 mL of ethanol to create TiO2 solutions with concentrations of 60 and 120 g/L, respectively. The mixtures were aggressively churned until uniform and white in color. Each prepared TiO2 nanoparticle solution was carefully deposited onto the cleaned soda lime glass (20 mm × 20 mm × 2 mm) for the ideal coating time (30 seconds at 3000 rpm). After each coating process a heating process at 100 ºC for 15 min. Then, the coated glass substrates were annealed. These processes have a number of benefits, including large scale, low temperature production processing, and the use of a wide range of substrates, a wide range of structural dimensions, minimal material waste, and cheap cost [24].

Activation and preparation of the Bacterial isolates 

The bacterial isolates used in this study were obtained from the Central Environmental Laboratory/College of Science/ University of Mustansiriya; it was gram-positive Bacteria (Staphylococcus. Aureus, Staphylococcus epidermidis) and Gram-negative bacteria (Pseudomonas.  Klebsiella, Streptococcus sp.). To assess the infection antibacterial activity and fungal type (Candida) to assess the infection antifungal activity of these as-prepared NPs. Lines of bacterial isolates were placed on brain heart infusion agar and incubated for 18 hours at 37℃. One colony was then picked from the media plate and inoculated in 5 ml of brain heart infusion broth and then incubated overnight at 37℃. Fig 5 shows the antibacterial samples at these conditions.

Characterization 

The prepared samples were analyzed using a variety of methods. The first technique employed an X-ray diffraction system with a Cu-Ka x-ray tube as the target and a power diffraction system with a wavelength of 1.5406 A to observe the crystal structure and identify the phase of the samples produced. The scan mode is continuous with a speed of 5.0000 degrees per minute, the voltage and current are 40 KV, 30 mA respectively. Atomic force microscopy type (AA3000) was used to examine the sample surface topography, to determine the grain size of agglomerations on the surface and roughness for TiO2 NPs prepared on glass substrates by two different method (drop-casting and spin-coating). This technique provides information regarding sample surface roughness at the nanoscale scale. UV-Visible region were recorded using spectrophotometer (SHIMADZU UV- 1650 PC). 

RESULTS AND DISCUSSION

Surface coating uniformity is an important criterion in the present study. The optimal TiO2 concentration required to produce a uniform coating on the substrate was identified by depositing two different concentrations using two different methods of TiO2NPs on glass substrates and by analyzing the properties of the TiO2-coated substrates. Analytical results indicated that the optimal TiO2NPsconcentration is 120.0 g/L for two methods. Fig. 4 shows glass substrates coated with different TiO2NPs concentrations images of these samples. As shown in these images, the surfaces of the substrates coated with 60.0 g/L TiO2 appear rough and uneven and the roughness of the coating surface decreases as TiO2 concentration increases.  

Fig. 5 shows the XRD patterns of TiO2NPs which prepared by drop-casting technique and the solution prepared with concentrations of (60 and 120 g/L). The anatase phase of TiO2 is represented by all sharp peaks observed in the XRD patterns. There are noticeable diffraction peaks located at 2θ= 25.35°, 37.90°, 48.10° , 54.49° and 62.92º which is observed on the spectra of drop-casting process attribute to (101), (004), (200), (105) and (204) orientation plane of anatase-TiO2. These results indicate that the synthesized powders in monoclinic phase of TiO2 nanoparticle can be obtained by double-step drop-casting process and agreed well with (JCPDS card number 01-084-1285). These results are nearly in agreement with research  [25]. The well-known Scherrer’s formula, expressed in Eq.1, can be used to calculate the average crystallite size of TiO2 from the full-width at half maximum (FWHM).

where D is the crystallite size, K is the form factor, λ is the X-ray wavelength of Cu Ka (0.154 nm), β is the full-width at half maximum (FWHM), and θ is the Bragg angle. Fig. 5 illustrates the results of calculating the crystallite size of TiO2 produced by the drop-casting procedure using the (101) plane diffraction peak. The average crystallite size were increased from 6.31nm to 8.01nm for 60g/L and 120g/L, respectively. It  noticed  that the crystallite size of the prepared samples are increased by increasing the TiO2 concentration and a good agreement with research [26]. 

Fig. 6 explains the phase composition and the crystalline size of the two samples that prepared by spin-coating technique and the solution prepared with concentrations (60, 120 g/L) in the 2θ range from 20º to 80º. The anatase phase of TiO2NPs is represented by all sharp peaks observed in the XRD patterns. Five peaks were identified in the anatase phase detected around 2θ values of  25.20°, 37.78°, 48.08°,54.66° and 63.01º which is observed on the spectra of spin coating process attribute to (101), (004), (200), (105) and (204) orientation plane, respectively. These findings indicate that spin coating can be used to obtain powders of TiO2NPs in the monoclinic phase, which agrees well with previous findings (JCPDS card number 01-084-1285).The average crystallite size of TiO2 can be calculated from the Eq.(1) above and increased from 9.78nm to 10.84nm for 60 and 120g/L, respectively, and this is a good agreement to researches [26, 27]. Drop-casting and spin-coating methods have been used to successfully prepare TiO2 nanoparticle, Top-view FESEM images of TiO2 with 200 nm scales are shown in Fig. 7 and 8, respectively. The critical roles of preparing method in changing the fundamental characteristics of TiO2 and its antibacterial activity were examined in detail. According to FESEM images which were analyzed using Image J software, TiO2 was uniformly distributed on FTO substrate. Additionally, the figures also display the TiO2 crystalline that forms has a smooth surface and no agglomeration had developed there. 

Figs. 9 (a and b) show the AFM images and the chart of grain density distribution of the TiO2 NPs films at varying solution concentrations (60 and 120 g/L) via drop-casting method. The substrate surface is well covered with grains that are almost consistently dispersed throughout it, according to AFM scans, which also demonstrate that the films are homogenous. The nanocrystalline (TiO2) grains are visible in the surface morphology, and when the concentration is raised, they mix to produce noticeably denser films. From the images, it is observed that the films consist of grain size 55.05nm and 62.037 nm for 60 g/L and 120 g/L, respectively. The films’ surfaces have some degree of roughness to them. Additional information on the surface morphology of thin films is provided by the surface roughness. In optical coatings, the variation in surface roughness of thin films is significant. It impacts the optical characteristics of thin films and increases optical absorption. These results are nearly in agreement with research [28]. Fig. 10 shows the AFM images of the TiO2 NPs films at two different solution concentrations 60 and 120 g/L.  The photos clearly show that the films have a smooth surface, a high density, and good adhesion to the glass substrate. Also, the surface roughness for synthesizing samples increased with the increasing solution concentrations due to increasing particle size, which increased from 63.61nm to 72.44 nm as shown in (Table 2) when the solution concentrations increase from 60 g/L to 120 g/L. The diameter distribution of the samples demonstrated that the average particle size increased with increasing solution concentrations, which might be attributed to an increase in film crystallanity [29]. This results agrees well with the XRD results.

The optical band gap for the TiO2 films that prepared by drop-casting method was determined by extrapolating the linear portion of (αhυ)2 versus photon energy (hυ) at αhυ=0, then the intercept with x-axis at αhυ=0, give the value of Eg. The energy gap can be calculated from Eq. 2:

As shown in Fig. 10 which illustrate the allowed direct electronic transition. The value of band gaps increased from 2.5 eV to 2.87 eV for (60,120) g/L, respectively. Since the film thickness increased significantly with concentration, the thickness dependence of the band gap can be referred to as I an increase in barrier in polycrystalline films according to change in grain size, since when the grain size increases the wideness of the electronic levels and the band gap increases. This is because the pairings of electron hole pairs are significantly closer to one another, making it impossible to ignore their Columbic contact, resulting in a larger total kinetic energy. Reduced strain and density of dislocations [28]. At the same way noticed the band gap will be increased with increasing the concentration of TiO2 NPs which prepared by spin-coating technique as seen in Fig. 12, and this results were a good agreement to research [30].

Antibacterial Activity of the TiO2 Nanoparticles (NPs)

The antibacterial activity of TiO2 NPs was studied using agar-well diffusion method against each of the previously mentioned microorganisms. The tested bacteria were uniformly flushed onto Muller-Hinton agar plates using a sterile cotton swab, then for 6 mm diameter wells were made using a sterile well drill. Freshly synthesized TiO2 NPs solutions of (60 and 120) g/L concentrations were added to the corresponding wells. The samples were then incubated overnight at 37 °C. After the incubation period, the region of inhibition (in mm diameter) was observed and tabulated as shown in Fig. 13. After the incubation period, positive test results were recorded when an area of inhibition (in mm diameter) was observed around the well as shown in (Table3). TiO2 NPs prepared using a spin-coting process exhibited high antibacterials activity against gram-positive Bacteria (Staphylococcus. Aureus, Staphylococcus epidermidis), Gram-negative bacteria (Pseudomonas.  Klebsiella, Streptococcus sp.), and fungal type (Candida) for both concentrations 60 g/L and 120 g/L. The maximum inhibition zone for gram-positive Bacteria ( Klebsiella. pneumonia) at 60 g/L TiO2 NPs, while 120 g/L TiO2 NPs showed the maximum inhibition zone for gram-positive Bacteria  (Klebsiella. pneumonia)  and gram-negative Bacteria (E. coli). TiO2 NPs (60 g/L) show excellent antibacterial activity against Gram-positive (Klebsiella. Pneumonia with inhabition zone 10 mm) than Gram-negative bacteria (E. coli with inhabition zone 6 mm). When opposed to Gram-positive bacteria, Gram-negative bacteria have a considerably thinner peptidoglycan coating, which plays a critical function in preserving cell integrity. Gram-negative bacteria have more complex cell walls than Gram-positive bacteria, which acts as a diffusion barrier and makes them less vulnerable to antibacterial agents [31]. 

CONCLUSION

On glass substrates, TiO2 thin films were created using the drop-casting and spin-coating techniques. As a function of the concentration, the structural, morphological, and optical characteristics of the films were investigated. The TiO2 films’ XRD patterns demonstrate that a single-phase with an anatase crystal structure exists. A (101) major peak can be seen in the XRD patterns, which is caused by TiO2 crystals that are growing along the c-axis. As the TiO2 nanoparticle concentration rose, the crystallite size also increased. According to AFM pictures, the density of the films rises when the concentration is increased. The films’ morphological characteristics demonstrate. The films’ surfaces have some degree of roughness to them. Band gap grew at both ways (drop-casting) as concentration increased.

ACKNOWLEDGEMENTS

Special thanks to the staff of Laboratory of Chemistry and Physics in University of Baghdad.

CONFLICT OF INTEREST

The authors declare that there is no conflict of interests regarding the publication of this manuscript.