GR1009029B - Preparation of mesoporous titanium dioxide with improved photocatalytic and anti-microbial activity- application to surface paints for the sanitation of indoor and outdoor spaces - Google Patents

Abstract

Novelty: there is disclosed the preparation of mesoporous titanium dioxide exhibiting improved photocatalytic and anti-microbial properties - application of same to surface-coating paints for the sanitation of indoor and outdoor spaces. Technical features: the mesoporous TiO2 is prepared with the sol-gel modified method and is liable to absorb both ultraviolet and visible-spectrum radiation. The improved paints are drastic against nitrogen oxide oxidation in visible and UV radiation conditions; furthermore, the thus- improved paints suspend the growth of bacteria while relative reduction ofcolony-forming units (CFU) is observed. Embodiment: the invention finds application to the building industry namely to the construction of indoor and outdoor surfaces destined for use in eating establishments, schools and sensitive spaces such as hospitals and foodstuff industry .

Description

DESCRIPTION

Preparation of mesoporous titania with improved photocatalytic and antimicrobial action and application in surface paints with the aim of sanitizing indoor and outdoor spaces

Students and inventors

Tiberios Vaimakis, Georgios Skouras, Georgia Tatsi, Marianna Tsoufla, Christina Nannou, Sophia Tsafou, Christos Trapalis, Nadia Todorova, Anastasios Mitsionis

Invention area

The present invention concerns a method of preparing mesoporous titania (TiO2) by the sol-gel method and its use in indoor and outdoor paints with the aim of breaking down gaseous pollutants in the atmosphere as well as self-cleaning surfaces. The improved nanostructured titania exhibits photocatalytic activity in both UV and visible radiation compared to Degussa (P25) which exhibits photocatalytic activity only in UV radiation.

Background of the invention

Titanium dioxide as a photocatalyst is used in many industrial applications as it has many advantages such as being inert, resistant to corrosion, requiring less post-processing and this makes it less expensive, there are enough reserves so there is no question of running out for many more years, it is friendly in the environment and in humans, it is a semiconductor and exhibits increased photocatalytic activity. The photocatalytic ability of TiO2 was discovered in 1972 by Fujishima and Honda. When TiO2 is irradiated with photons with energy greater than the band gap, Eg(eV), electrons leave the valence band and excitedly jump to the conduction band. At the same time, they leave a positive charge (hole) in the position they were in. Such a pair that occurs inside a particle is called an electron-hole pair. OL most characteristic reactions that take place in the photocatalytic process in the presence of titanium oxide are [1,2]:

TiO2+ hv(UV) — > TiO2(eCB+ hVB<+>) (1)

TiO2(hVB<+>) H2O -> TiO2+ H<+>+ OH<*>(2)

TiO2(hVB<+>) OH<'>-> TiO2+ OH' (3)

TiO2(eCB) + O2 > TiO2 + O2' (4)

O2- H<+>-> HO2'(5)

TiO2 as a photocatalyst has received a lot of attention in recent years for air purification applications, especially for the removal of atmospheric pollutants from anthropogenic sources, such as NOx, VOCs, etc. Nitrogen oxides (NOx) pollution, as a result of the extensive burning of biomass and minerals, has become an urgent environmental problem with a strong impact on the earth and human health [3]. Some of the major adverse environmental and health issues arising from high levels of NOx (NO and NO2) are the burden on the formation of the ozone hole, the production of smog that leads to low visibility and respiratory problems, and the formation of toxic solid particles of size less than 2.5μm. NOx derivatives are also able to react with water vapor and produce acid rain similar to other air pollutants.

According to ISO 22197-1:2007 for the removal of Nitric Oxides, the main reactions that take place on the surface of TiO2 are [5-8]:

The ISO 22197-1: 2007 method was created to provide a standard for NO determination and NO2 removal. According to the ISO standard the sample must be pre-irradiated with UV radiation for at least 5 hours in air to decompose any residual organic matter, followed by washing the sample with water. This step is preparation so that the surface exposed to NOx can be considered excellent [9].

A number of studies focused on the application of TiO2 in wax materials and construction components such as paints etc. [10-12]. Colors have been developed to decorate and protect our environment [13]. However, only a few scientific articles have been published about colors and their photocatalytic activity [14-15]. For example, Uhde and Salthammer [16] reported that irradiated dyes produce undesirable and highly toxic by-products such as formaldehyde, acetaldehyde, pentanal, 1-hydroxy-butanone, and hexanal. This observation is further emphasized by Kolarikand Toftum. Auvinen et al. and Geiss et al. found relatively high amounts of organic compounds, such as ketones formed by the decomposition of binders and additives [16-19].

Air purification using photocatalytic dyes has been the focus of other research groups as well [20,21,22]. According to Hochmannova and Vytrasova [20], UV light emitted by fluorescent lights is able to ensure the photocatalytic action of paints incorporating zinc oxide nanoparticles. A number of studies focused on the application of TiO2 in wax materials and construction components such as paints, etc. [10-12]. Most research has focused on the photocatalytic action of TiO2 paints in UV radiation and in indoor paints [23], however UV radiation corresponds to 3-5% of solar radiation. For this reason attention has been focused on the design and development of the new generation of TiO2 or other photocatalysts with the aim of extending the absorption band in the visible spectrum. Efficient utilization of ambient light is an energy-saving method and enhances the photocatalytic activity of photocatalysts [24-31]. It was found that N doping [37,39,131] was effective for the photocatalytic activity of TiO2 under visible radiation [32-34].

A significant number of studies confirm the antimicrobial capacity of nanostructured titania, modified and not with metal ions.

According to many studies, titania nanoparticles (TiO2) in combination with UV radiation, bring about a significant antimicrobial effect on microbial colonies, with the main representatives being E. Coli [35-37] but also Staphylococcus aureus, Shigella flexneri, AcinetobacterPseudomonas putida and Listeria innocua [38,39].

The antimicrobial capacity of titania modified with metal cations, such as those of iron (Fe3+) [40], copper (Cu+)[41] or zinc (Zn2+)[42,43], is often mentioned in the literature. Similar results have been reported. and in studies of N-modified 3SnO2/TiO2 particles for the Gram-negative bacteria E. Coli, Salmonella typhi<'>and for the positive Staphylococcus aureus [44].

The present research refers to the preparation of mesoporous titania and its addition to interior and exterior paints with photocatalytic and antimicrobial action in UV and visible radiation

Method for preparing mesoporous titania

In a Methanol/Ethanol solution with a ratio of 1/1 v/v was added surfactant AOT (aerosol OT, dioctyl sodium sulfosuccinate) and titanium butoxide Ti(ButO)4, with a mole ratio of 1/1. This was followed by stirring for 24h. Then 1M hydrochloric acid was added dropwise to carry out the hydrolysis and the solution was stirred for 24h. This was followed by drying at 90°C for 24h and the baking of the material took place at 450°C for 3h. The mesoporous titania was characterized by X-ray diffraction, dynamic light scattering (DLS), nitrogen adsorption-desorption (BET), diffuse UV-visible recall spectroscopy, photocatalytic oxidation of nitrogen monoxide under UV irradiation and photocatalytic oxidation of carbon monoxide. of nitrogen under visible radiation

From the x-ray diffraction patterns (Figure 1) it is observed that the nanostructured titania is single-phase and consists of anatase. The crystallite size was estimated to be 13nm. The particle size distribution (Figure 2) gave a relatively narrow particle size distribution from 200 to 500 nm with an average diameter of 288 nm. The nitrogen adsorption-desorption isotherm curves at 77K are of type IV and H2 hysteresis loop corresponding to mesoporous titania (Figure 3). maximum pore size 1.6 nm. From the UV-Vis spectrum (Figure 4) it is observed that the nanostructured titania absorbs a large part of the radiation in the visible light region. The energy gap was calculated to be 3.08eV (Figure 5). In the oxidation of nitrogen monoxide (NO) in both UV (Figure 6) and visible (Figure 7) radiation, the sample shows increased photocatalytic activity.

Photocatalytic activity of paints enhanced with mesoporous titania

Two types of paints were used in this research: acrylic and plastic for exterior and interior, respectively. 10g of mesoporous titania was added to 100mL of acrylic paint and correspondingly to 100mL of plastic paint, followed by mechanical stirring for 1h. Special surfaces were coated with 2 layers of plastic and acrylic paint respectively. In the oxidation of nitrogen monoxide under UV radiation, increased photocatalytic activity was observed in both samples with better activity in acrylic paint with mesoporous titania (Figures 8-9). Similarly, both samples showed activity in the oxidation of nitric oxide in visible radiation proportional to the intensity of the absorbed radiation (Figures 10-11).

Antimicrobial action of paints enhanced the mesoporous titania

The bacterium Staphylococcus aureus (Newman Strain), which belongs to Gram-positive bacteria and is the most frequent cause of staphylococcal infections, was examined to study the antibacterial action of mesoporous titania on paint-coated surfaces.

The bacterial culture was grown on an agar plate for 24 hours at 37°C and then a single colony was transferred to 5 mL of liquid LB medium (Luria Broth) and incubated (overnight) at 37°C under mechanical agitation (110 rpm) . Then followed a dilution (1:100) of the pre-culture with nutrient material and incubation in the same conditions for 2 hours, at which time the bacterial strain was in the exponential growth phase, where the nutrient medium is replaced with PBS and the absorbance is measured at 660 nm. From the absorption, the concentration of the bacterial culture was calculated, which was of the order of 10<8>cfu/mL Finally, with successive dilutions in PBS we reach the desired concentration of 10<4>cfu/mL.

First we have the preparation of agar plates, where the bacterial strain is coated and a single colony is transferred to liquid nutrient material LB medium. In 24-place Petri dishes, the surface was coated with a base of plastic and acrylic paints containing 5% of mesoporous titania. The coated plates were placed under a gentle stream of nitrogen for 10 min, left in a common crucible at 100 °C for 30 min, followed by pre-irradiation with UV radiation for 30 min, to completely sterilize the plates at 121 °C. The photocatalytic - antibacterial experiments were carried out in the presence of visible radiation under mechanical stirring using an LED lamp, light emitting diode, 10 W/m<2> at 400nm.

2ml of bacterial culture with a concentration of 10<1>cfu/mL was added to the coated plates based on plastic and acrylic paints, respectively, containing 5% of mesoporous titania, i.e. 10<3> bacteria. The plates were left under continuous mechanical agitation (300 rpm) in the presence of visible radiation in LED (Light Emitting Diode) lamps for various times of 15, 30, 45 and 60 minutes as well as 9 and 24 hours. After the end of the irradiation time, 100μl of each sample was transferred for plating on agar plates. After keeping the plates in an incubation chamber at 37 °C for 24 h, the colonies of the remaining bacteria were counted and compared to their original number as well as to their number in the blank samples. The experiments were carried out in double conditions with the presence of blank samples having only the bacterial culture in uncoated positions of the polyplate as well as the bacterial culture in coated positions with the base of plastic and acrylic paint respectively.

Figures 1-3 show the antibacterial activity in the presence of visible radiation on coated surfaces of plastic paint containing 5% of mesoporous titania. A decrease in colony forming units (CFU) is observed in the samples throughout the irradiation as well as in the blank samples containing only the plastic color base.

Likewise, for the antibacterial activity in the presence of visible radiation on coated surfaces of acrylic paint containing 5% of mesoporous titania, a relative reduction of colony forming units (CFU) is observed in the samples throughout the irradiation period (fig. 4-6).

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Claims (5)

1. Plastic interior paint and acrylic exterior paint containing mesoporous titania. 2. Mesoporous titania according to Claim 1 was prepared by a modified sol-gel method in the presence of surfactant AOT (aerosol OT, dioctyl sodium sulfosuccinate) and titanium butoxide Ti(ButO)4, and by firing the produced gel at 450°C. 3. Mesoporous titania according to claims 1 and 2 added at 5% w/v to interior plastic paint and exterior acrylic 4. Paints prepared according to claims 1, 2 and 3 with photocatalytic action for NO oxidation in UV and visible radiation 5. Paints prepared according to claims 1, 2 and 3 inhibiting the growth of bacteria with a relative reduction in colony forming units (CFU).