(Đồ án hcmute) effects of tio2 on chitosan film and its application in passion fruit preservation

TECHNOLOGY AND EDUCATION MINISTRY OF EDUCATION AND TRAINING HO CHI MINH CITY UNIVERSITY OF GRADUATION THESIS S K L 0 0 9 1 3 5 Effects of TiO2 on chitosan film and its application in p

INTRODUCTION

Pose the problem

Ethylene gas, recognized as the fruit ripening hormone, significantly contributes to the postharvest deterioration of fruits and vegetables To mitigate ripening, it is essential to reduce ethylene levels Active packaging that incorporates TiO2 functions as an effective ethylene scavenger Due to its double bond, gaseous ethylene is highly reactive and can be modified or decomposed through various methods Photocatalytic oxidation of ethylene occurs when it is exposed to ultraviolet (UV) radiation in the presence of a catalyst like titanium dioxide (TiO2) Despite the limited scientific literature on the use of TiO2 screens to influence fruit ripening rates, this scarcity underscores the rationale for selecting TiO2 as an ethylene scavenger.

During the COVID-19 pandemic in Vietnam, particularly during the pre-lockdown, lockdown, and second-wave periods, daily confirmed cases significantly impacted the stock returns of publicly traded companies Agricultural exports, especially seasonal crops like Thai jackfruit and dragon fruit, faced delays, with nearly 5,000 containers awaiting customs clearance Tien Giang, known as the "Fruit Garden" of Vietnam, has over 80,000 hectares dedicated to fruit cultivation, yet many fruit prices have plummeted due to the pandemic Passion fruit, however, has shown strong growth potential, contributing to the economy and providing jobs for farmers and businesses In 2021, Vietnam produced 5.4% of the world's passion fruit, ranking 7th globally To enhance lemon consumption and reduce losses from over-ripeness, research is being conducted on using TiO₂ chitosan film to extend the ripening period of passion fruit.

This study explores how different methods of producing titanium dioxide (TiO2) influence its photocatalytic properties By utilizing two distinct types of TiO2, we aim to gain insights into the synthesis of effective TiO2 Research indicates that the calcination process significantly impacts the size and photocatalytic efficiency of TiO2 By mimicking the production process, we can enhance our understanding of synthetic TiO2.

Figure 1 1 Biggest passion fruit producer in the world

Topic goal

- Determine physical properties of synthesis TiO 2

- Determine effect of TiO2 film to passion fruit ripening

- Determine properties of Chitosan films combining TiO2

Subject and scope of research

- Passion fruit is treated by Chitosan films combining TiO2

- The study determines synthesis of TiO2 production

- The study determines physical properties of chitosan film combining with TiO 2

- The study determines the application and effect of TiO 2 – chitosan film (color, harness, weight loss, gas release)

- The study is done at food technology industry laboratory, University of Technology and Education, Ho Chi Minh city

Research content

- Effect of TiO2 to chitosan film including:

+ UV-vis absorption spectrum and light transmittance

- Application of TiO2 to fruit

The scientific and practical significance of the topic

The study result shows experimental synthesis TiO 2 production

The study result shows experiment of combing TiO 2 to chitosan film which can be use as reference

The study shows the effect of TiO2-chitosan film to passion fruit

The study shows statistic of properties TiO2-chitosan film

The study shows the application potential of using chitosan film covering passion fruit

OVERVIEW

Titanium Dioxide

Titanium dioxide (TiO2), also known as titania, is an inorganic compound that was discovered in the late eighteenth century and mass-produced in the early twentieth century due to its numerous benefits It is widely utilized across various industries, including paints, food, energy, adhesives, paper, plastics, rubber, printing inks, textiles, ceramics, and cosmetics The FDA permits the use of TiO2 as a food color additive, highlighting its significance in the food industry Additionally, titanium dioxide is a key ingredient in sunscreen products, as it effectively blocks ultraviolet light absorption, helping to prevent sunburn and reduce the risk of skin cancer.

Figure 2 1: Titanium dioxide powder 2.1.2 TiO 2 application

In 1916, titanium dioxide emerged as the most widely used white pigment due to its exceptional brightness and high refractive index, second only to a few materials The ideal crystal size for titanium dioxide is approximately 220 nm, which maximizes visible light reflection However, the rutile phase of titanium dioxide can lead to abnormal grain development, affecting its physical properties and optical characteristics Even trace amounts of certain metals can disrupt the crystal lattice, impacting quality control Annually, around 4.6 million tons of pigmentary titanium dioxide are consumed globally, with usage expected to rise In powder form, it serves as a powerful opacifier in various products, including paints, plastics, and food items, with a significant presence in toothpaste tubes Titanium dioxide is often referred to as "brilliant white" or "the perfect white" in the painting industry, and optimal particle sizing enhances its opacity.

Figure 2 3: Marshmallow which have TiO 2 as pigment 2.1.2.2 Thin films

The optical properties of titanium dioxide films, especially their birefringence, are extensively researched Titanium dioxide thin films are produced using serial bideposition and electron-beam evaporation on fused silica substrates, which involves rapid substrate rotation and oblique-angle physical vapor deposition to create nanostructured optical coatings with high birefringence A novel method for fabricating gold-loaded TiO2 thin films (Au/TiO2) has been introduced, enabling their use as recyclable surface-enhanced Raman scattering (SERS) substrates and multifunctional photocatalysts By depositing gold nanoparticles onto a dip-coated macroporous TiO2 thin film, SERS activity is achieved The high photocatalytic activity of TiO2 allows the substrate to decompose adsorbates into small inorganic molecules under UV light, facilitating self-cleaning for subsequent SERS detection cycles Experimental results indicate that Au/TiO2 is a promising candidate for SERS substrates and photocatalysts, demonstrating excellent recyclability in detecting organic contaminants.

Figure 2 4: Application of TiO 2 in thin film which use in energy film

2.1.2.3 Sunscreen and UV blocking pigments

Titanium dioxide (TiO2) serves multiple roles in cosmetic and skin care products, acting as a pigment, sunscreen, and thickener Notably, ultrafine TiO2, when combined with ultrafine zinc oxide, creates an effective sunscreen that helps minimize the risk of sunburn, early photoaging, photocarcinogenesis, and immunosuppression from excessive sun exposure Additionally, to enhance protection against visible light, these UV blockers are sometimes supplemented with iron oxide pigments.

The majority of physical sunscreens contain nanosized titanium dioxide because of its potent UV light absorption properties and resistance to discoloration when exposed to ultraviolet radiation

The stability and effectiveness of sunscreen in protecting the skin from UV rays are enhanced by nanoscale titanium dioxide particles, which range from 20 to 40 nm in size These particles scatter visible light less than traditional titanium dioxide pigments while still providing essential UV protection Mineral UV blockers like titanium dioxide and zinc oxide are commonly used in sunscreens, particularly for babies and individuals with sensitive skin, due to their lower likelihood of causing skin irritation compared to other UV-absorbing ingredients.

Nano-sized titanium dioxide (nano-TiO2) is commonly used in sunscreens and cosmetic products to effectively block UV-A and UV-B rays, offering a safer and more environmentally friendly alternative to organic UV-absorbers The risk assessment for titanium dioxide nanomaterials in sunscreens is evolving due to the distinct properties of nano-TiO2 compared to its micronized counterpart Rutile, a form of titanium dioxide, is preferred in these products due to its superior UV absorption and established safety profile for skin application A 2016 study by the Scientific Committee on Consumer Safety (SCCS) concluded that nano titanium dioxide, composed of 95% to 100% rutile and 5% anatase, does not pose any significant risk of adverse effects when applied to healthy skin.

[14], unless the application method would result in a significant risk of adverse effects

Figure 2 5: Sunscreen product 2.1.2.4 TiO 2 photocatalysis

Photocatalysis has gained significant attention in recent years due to its applications in environmental and energy-related products, such as self-cleaning surfaces and purification systems Titanium dioxide (TiO2) photocatalysis plays a crucial role in these applications, including sterilization and hydrogen evolution To enhance photocatalytic performance and explore new uses for TiO2, the development of new materials is essential The photocatalytic oxidation of gaseous ethylene involves ultraviolet (UV) radiation and TiO2 as a catalyst, which generates reactive oxygen species (ROS) that oxidize ethylene into carbon dioxide and water.

Figure 2 6: Mechanical of TiO 2 photocatalysis 2.1.2.5 Health and safety

Titanium dioxide was previously regarded as "totally harmless" and "completely nontoxic." However, on February 7, 2022, the European Union revoked the authorization for its use in foods (E 171), allowing a six-month grace period Inhalation of titanium dioxide dust poses risks, potentially irritating the nose and throat, while contact with the eyes or skin can also lead to irritation When particles are washed from the eye by tears, they may cause tearing, blinking, and minor transient pain.

Titanium dioxide has been classified as a Group 2B carcinogen by the International Agency for Research on Cancer (IARC), indicating it is possibly carcinogenic to humans Studies have shown that the same biological processes leading to lung cancer in rats—such as particle deposition, reduced lung clearance, and cell damage—are also observed in individuals working in dusty environments Consequently, IARC suggests that findings from animal studies are relevant to workers exposed to titanium dioxide dust in industries lacking adequate dust control measures While current research does not definitively link occupational exposure to titanium dioxide with an increased risk of lung cancer, potential misclassification of exposure and low prevalence may have influenced these results Additionally, concerns have been raised about the cancer risk associated with nano-sized titanium dioxide particles, which can penetrate the body and reach internal organs.

Research indicates that exposure to titanium dioxide (TiO2) nanoparticles can lead to inflammatory reactions and genetic damage in mice, raising concerns about potential cancer risks and genetic disorders, particularly for individuals with occupational exposure The study emphasizes the need to limit ingestion of TiO2 through non-essential additives and food colors While TiO2 is associated with cancer risk, the exact mechanisms remain unclear Molecular studies suggest that the cytotoxic effects of TiO2 are linked to its interaction with lysosomal compartments rather than traditional apoptotic pathways In response to these findings, the US National Institute for Occupational Safety and Health (NIOSH) has established exposure limits for fine and ultrafine TiO2 particles at 2.4 mg/m³ and 0.3 mg/m³, respectively, for time-weighted average concentrations.

Research indicates that smaller titanium dioxide particles may pose a greater carcinogenic risk compared to larger ones There is some evidence linking titanium to the rare yellow nail syndrome, potentially from medical implants or food consumption However, Andrew Maynard, director of the Risk Science Center at the University of Michigan, has minimized the risks associated with titanium dioxide in food, stating that the material used by Dunkin' Brands and other producers is not new or classified as a nanomaterial Most food-grade titanium dioxide particles are significantly larger than the nanoparticle threshold of 100 nanometers.

Chitosan

Chitosan is a linear polysaccharide made up of D-glucosamine and N-acetyl-D-glucosamine linked at the β-(1-4) position, characterized by its biodegradability, biocompatibility, and nontoxicity Its high biodegradation properties make it valuable in the biomedical field Chitosan exhibits various physical properties, such as high viscosity and the ability to complex and chelate, while being insoluble in water and organic solvents, yet soluble in aqueous acidic solutions like acetic acid This unique natural polysaccharide, derived from the deacetylation of chitin, is produced in approximately 10 billion tons annually and is the second most abundant biopolymer after cellulose, found in crab and shrimp shells, fungi, and insects The preparation of chitosan involves four key steps: demineralization, deproteinization, decoloration, and deacetylation.

Isopropyl alcohol

Isopropyl alcohol is a colorless, flammable chemical compound (chemical formula CH3CHOHCH3) with a strong alcoholic odor.[30]

In the Meerwein-Ponndorf-Verley reduction and other transfer hydrogenation processes,

Figure 2 8: chemical composition of isopropyl alcohol

Isopropyl alcohol serves as a versatile solvent and hydride source When heated with sulfuric acid, it can be dehydrated to yield propene or converted to 2-bromopropane using phosphorus tribromide Additionally, isopropyl alcohol can be transformed into acetone, a corresponding ketone, through dehydrogenation over a hot copper catalyst or by employing oxidizing agents such as chromic acid.

Isopropyl alcohol effectively dissolves numerous non-polar substances and evaporates quickly, making it a preferred cleaning solution Unlike many common solvents, it typically leaves no oil residues and is largely non-toxic Its rapid evaporation and lower risk of corrosion compared to water make it ideal for cleaning oil-based residues.

Isopropyl alcohol, part of the alcohol solvent family alongside ethanol, n-butanol, and methanol, is commonly used for cleaning various items It effectively cleans eyeglasses, electrical contacts, audio and video tape heads, DVD and other optical disc lenses, as well as removing thermal paste from heatsinks on CPUs and other integrated circuit packages.

Isopropyl acetate, a solvent formed from the esterification of isopropyl alcohol, can be converted into sodium isopropylxanthate, which serves as a herbicide and reagent for ore flotation when reacted with sodium hydroxide and carbon disulfide Additionally, isopropyl alcohol reacts with titanium tetrachloride and aluminum metal to yield titanium and aluminum isopropoxides, respectively, with the former acting as a catalyst and the latter as a chemical reagent Furthermore, isopropyl alcohol can function independently as a chemical reagent by serving as a dihydrogen donor in transfer hydrogenation.

Passion fruit

Passion fruit (Passiflora edulis) is a visually appealing and nutrient-dense fruit, highly sought after for its diverse uses in products like juice, jelly, and ice cream This perennial woody vine, native to tropical America (specifically Brazil), belongs to the Passifloraceae family The fruit is typically round or oval, featuring a smooth, waxy peel with subtle white spots, available in purple or yellow varieties The interior consists of fragrant membranous sacs filled with orange pulp There are two main varieties: the purple passion fruit (Passiflora edulis Sims) and the yellow passion fruit (Passiflora f flavicarpa Deg.), with the yellow variety being a mutation of the purple type or a natural hybrid with a closely related species.

Passion fruit trees can thrive in any region of the United States, but to achieve a high yield and abundant fruit production, specific ecological conditions must be met.

Purple passion fruit thrives in subtropical climates with an average altitude between 1,000 and 2,000 meters above sea level Consequently, purple passion fruit trees are frequently cultivated in the Central Highlands

Passion fruit thrives in well-drained, light-textured soil that is flat, warm, and moist The ideal soil should have a cultivable layer exceeding 50 cm in thickness, a humus content greater than 2 percent, and a pH level between 5.5 and 6.

The optimal temperature for passion fruit tree growth ranges between 20 and 25 degrees Celsius In northern highland provinces, where hoarfrost occurs, the cold conditions are detrimental to the development of these trees Temperatures below 10 degrees Fahrenheit can be fatal for the plant.

Light: The plant prefers bright light

For optimal fruit development, a consistent annual rainfall of 1,600 mm is essential During the fruiting stage, increased watering is crucial; otherwise, insufficient moisture can lead to atrophied, tough, and unsightly fruit that may ultimately drop prematurely.

Figure 2 9: passion fruit 2.4.2 Nutrition value of passion fruit

Passion fruit provides many vitamins, minerals, and fibers and is not fiber calories

Table 2 1: Nutritional composition of passion fruit per 100g

During the ripening process, fruits release higher levels of ethylene gas as a result of increased respiration A small concentration of ethylene promotes ripening in controlled temperature and humidity environments near consumption areas Ethylene, the first identified plant hormone, plays a crucial role in regulating various processes in plant growth, development, and responses to both biotic and abiotic stresses Its significant impact on fruit ripening and organ abscission highlights its commercial importance in agriculture.

Ethylene is a volatile chemical that plays a crucial role in the ripening of fruit, consisting of 2 carbon and 4 hydrogen atoms While it positively influences fruits by enhancing their color and metabolic activity, it also has negative effects on post-harvest storage The acceleration of ripening caused by ethylene can lead to a decline in fruit quality and increased vulnerability to diseases.

Figure 2 10: Ethylene effect to fruit ripening

Fruit ripening involves a series of changes that affect its color, weight, and composition, with qualities evolving through various growth stages For climacteric fruits like passion fruit, the process is driven by ethylene, leading to softening that impacts postharvest quality and storage As fruits ripen, they become more appealing, typically growing sweeter, softer, and less green, despite an initial increase in acidity Additionally, the release of aroma volatiles enhances the fruit's flavor profile.

The plant hormone ethylene plays a crucial function in fruit ripening

Immature fruits contain low levels of ethylene, which increases as the fruit matures, signaling ripening After harvest, ethylene production escalates, negatively impacting the fruit's shelf life, storage capacity, and susceptibility to diseases Climacteric fruits can continue to ripen post-harvest due to their ability to produce ethylene, while non-climacteric fruits do not produce ethylene and cannot ripen after being harvested Climacteric fruits are also referred to as autocatalytic, as an initial concentration of ethylene boosts further ethylene production.

Figure 2 11: Ethylene release of climacteric fruits and non-climacteric fruits

Table 2 2: Some fruits emit ethylene gas

VH = very high; H = high; M = medium; L = low; VL = very low

Effect of irradiation on the experiment

Photocatalysts are substances that accelerate chemical reactions when exposed to light, combining the concepts of photons and catalysts This process, known as photocatalysis, involves using light and semiconducting materials to initiate reactions For instance, UV light activates TiO2, enhancing the oxidation and decomposition of ethylene gas.

Research on fruit preservation

 Some methods of preserving fruit

Respiration is the primary factor driving the metamorphosis of fruits and vegetables, leading to challenges in respiration and storability, which refers to the quality of produce with minimal loss during storage To address these issues, it is essential to regulate the respiration of the fruit, ensuring that they remain alive while simultaneously reducing their metabolism and respiration rates.

Low temperatures play a vital role in inhibiting respiration and extending the storage life of fruits The technique of low-temperature preservation is well-established and widely used, representing a dominant method in physical storage technology By maintaining fruits at lower temperatures, their metabolic activity is reduced, the growth of thermophilic microorganisms is limited, and the oxidation process is slowed, which collectively minimizes fruit degradation Therefore, careful attention to temperature is essential for effective fruit preservation.

According to TCVN 9688:2013, the recommended cold storage temperature for Apples is approximately -1 to 0 degrees Celsius (ISO 1212:1995)

Certain cultivars of the Antilles group, such as Waldin, require storage temperatures between 10 and 12.5 degrees Celsius In contrast, Fuerte avocados, a hybrid from Mexico and Guatemala, can be stored at approximately 4.5 degrees Celsius for up to three weeks without any deterioration.

The ideal storage temperature for avocados is 7 °C; temperatures below 5 °C can lead to unnatural ripening and poor quality This guideline is based on TCVN 10921:2015 (ISO 2295:1974).

Controlled atmosphere storage preserves food by maintaining an airtight environment with specific concentrations of gases such as O2, CO2, and nitrogen This method significantly reduces the physiological metabolism of fruits and vegetables, allowing for minimal nutrient degradation Additionally, the strong antibacterial properties of this storage technique facilitate extended shelf life.

 Several methods of degassing ethylene

- KMnO4 is the most frequently employed commercially available substance for controlling the activity and quantity of ethylene gas Nevertheless, due to the toxicity of KMnO4

Ingestion of potassium permanganate (KMnO4) can lead to severe health issues, including abdominal pain, bloody vomiting, and stomach perforation, and it should never be used in food due to the risk of necrosis upon contact Ozone (O3) serves as an alternative oxidant, but it is unstable and quickly decomposes into oxygen Additionally, zeolites and carbon-based ethylene adsorbents are crucial for ethylene control; however, this method does not eliminate ethylene but rather transforms it into another gas, requiring further management steps.

Reasons for choosing a research topic

The rise in agricultural production has led to an urgent need for effective preservation methods to ensure that consumers can enjoy fresh produce In Vietnam, signs promoting the sale of surplus fruits like dragon fruit and watermelon highlight the issue, as these fruits are often sold at prices significantly lower than market value, resulting in financial losses for farmers and hindering economic growth The ripening of climacteric fruits, such as passion fruit, is influenced by ethylene, which affects their postharvest quality and storability A promising solution involves using TiO2 to treat the ethylene gas released during the ripening process of these fruits.

[37] to increase the shelf life of the fruit

Figure 2 16: current situation of VN agriculture

MATERIAL AND METHODS

Materials and methods

This study utilized two types of titanium dioxide: industrial-grade titanium dioxide sourced from a leading online supplier in Vietnam and a synthesized form specifically for research purposes Additionally, chitosan powder, acetic acid, glycerol, and other chemicals were procured from a local chemical supplier in Vietnam.

- UV-Vis Halo Vis 20 Spectrophotometer (Dynamica, Switzerland)

- 2- and 4-digit analytical balance (Sartorius, Germany)

- Necessary tools such as beaker, pipette, micropipette, volumetric flask, petri disk,

Determine the amount of gas released

Making coating on passion fruit

Determine the physical properties of films

Figure 3 1: research process diagram 3.3 Method

Titanium dioxide nanoparticles are synthesized using the sol-gel method, involving two distinct solutions The first solution comprises 147 mL of isopropyl alcohol and 50 grams of titanium butoxide in a 500 mL beaker, which is sealed and stirred for 30 minutes to stabilize The second solution consists of 200 mL of water and 12.5 mL of 0.25M HCl This second solution is then added to the first, and the mixture is stirred for 6 hours at room temperature (25°C) After stirring, the mixture is poured into petri dishes, with each dish containing 50 g of the solution, and dried at 150°C for 12 hours Once fully dried, the material is ground into powder and fired at 800°C for 3 hours, resulting in synthetic TiO2 in a white powder form.

3.3.2 Preparation of chitosan films coated with TiO2 to cover the fruit

This research utilizes two distinct types of titanium dioxide: the first is industrial TiO2 sourced from America, purchased from Shoppe, a leading online store in Vietnam The second type is synthesized in the laboratory following the procedure detailed in the course article[44].

Chitosan (CH) films were first prepared by blending the mixture of chitosan powder (4 % m/v) and acetic acid (1 % v/v) on a magnetic stirrer until complete dissolution before adding 30

The addition of glycerol is crucial for achieving the desired plasticity in chitosan films used for storing passion fruit; without it, the film is prone to breaking In section 2.1, titanium dioxide was prepared at varying concentrations of 0%, 20%, 30%, and 40% to identify the minimum effective concentration The chitosan film, enhanced with titanium dioxide, was then applied to passion fruit for preservation studies, with each sample tested three times to ensure accuracy Detailed information about the film mixture can be found in Table 2.3.

Table 3 1: Preparation of chitosan films coated with TiO2 modulated

Sample Total sample solution (g) Chitosan(g)

Table 3 2: Preparation of chitosan films coated with commercial TiO2

Sample Total sample solution (g) Chitosan(g)

3.3.3 Preparation of chitosan films coated with TiO2 on petri dish

This research utilizes two distinct types of titanium dioxide: the first is industrial TiO2 sourced from America, purchased from Shoppe, a leading online store in Vietnam The second type is synthesized in the laboratory following the procedure detailed in the course article[44].

Chitosan (CH) films were first prepared by blending the mixture of chitosan powder (2 % m/v) and acetic acid (1 % v/v) on a magnetic stirrer until complete dissolution before adding 30

The addition of glycerol is crucial for maintaining the plasticity of Chitosan films during the storage of passion fruit; without it, the films are prone to breaking In the experiment, a consistent amount of 0.4 g of solids was applied to each plate, using samples with equal proportions of Chitosan, acetic acid, and glycerol The effect of varying TiO2 concentrations on the Chitosan film was then assessed.

3.3.3.1 Experimental arrangement to determine the effects of TiO2 on chitosan films

Different concentrations of commercial and homemade TiO2 were applied to petri dishes at a rate of 0.4 g solids per plate The liquid was dried in an oven at 45 degrees Celsius for 24 hours to remove moisture, leaving only the particles for film peeling The resulting film was stored in an airtight container with saturated brine to maintain humidity, which is crucial for film quality After stabilization, we evaluated the film's loss on drying, tensile strength (TS), elongation at break (E), water vapor permeability (WVP), water drop penetration time per film thickness (WDPT/d), and transparency of the blended films.

3.3.3.2 Method to determine the moisture content of chitosan films

The experiment on measuring film moisture was conducted as follows: a sample of film was cut and precisely weighed before being dried in a drying chamber at 105 degrees Celsius for

After being chilled in a desiccator with silica gel, the chitosan film was weighed to determine its mass loss This mass loss reflects the amount of water vapor released, indicating the film's moisture content.

The formula used when calculating the percentage of moisture content of chitosan films is:

3.3.3.3 Some mechanical properties of chitosan films

A texture analyzer was utilized to assess the tensile strength (TE) and elongation (EL) characteristics of the film The tensile strength is measured by identifying the maximum load at the point of rupture, while the percentage of elongation is calculated by comparing the film's length at break to its original length before testing.

The expansion and solubility of chitosan film are evaluated by first drying the sample to a consistent weight and then soaking it in water for 12 hours After soaking, the sample is re-weighed following the removal of surface water, with excess moisture blotted away using paper towels The increase in mass is attributed to the water absorbed by the membrane Subsequently, the sample undergoes a second drying process until a constant weight is achieved, with the mass loss indicating the film's solubility.

Formula for calculating water absorption rate:

Formula for calculating film solubility:

3.3.3.4 The absorption spectrum and light transmittance

The transparency of the film was assessed by measuring the percentage of transmitted light with a UV-Vis spectrophotometer (UH-3500 Hitachi) Colorimetric films, cut into rectangles measuring 1.2 × 4 cm, were positioned in the cuvette slot perpendicular to the light beam Air served as the reference for the measurements, and the spectrum of each film was recorded across wavelengths ranging from 200 to 1100 nm.

3.3.3.5 The Water Vapor Permeability (WVP)

The moisture permeability of a membrane is influenced by the pressure differential between its exterior and interior In this study, the membrane is used to seal a glass vial cap, secured with paraffin, while the vial's interior remains unfilled with silica gel to create a pressure difference A relief air gap of less than 1 mm is maintained below the film The cells were stored in hermetically sealed 500 mL chambers with a saturated sodium chloride solution at 25°C to achieve a 75% relative humidity difference After reaching steady-state conditions in 2 hours, the cell mass was measured hourly over a period of 0.5 days.

The Water Vapor Permeability (WVP) is determined by the formula where the film average thickness (d) is measured in millimeters, the permeation rate (m) is calculated through linear regression of mass gain over time, and the permeation area (A) is set at 5.3106×10^{-3} m² Additionally, the difference in relative humidity (ΔRH) is 0.75, while the partial water vapor pressure at the test temperature (Pw) is 3.167 kPa.

When selecting passion fruit, choose unripe fruits with smooth, glossy skin free of wrinkles and damage After careful sorting, the fruits are cleaned with water and a 20% salt solution They are then categorized into three groups: those wrapped in titanium dioxide film, those wrapped in chitosan film, and a control group of normal passion fruit Each group is placed separately for hardness measurement using a specialized device Daily, the titanium dioxide-wrapped fruits are treated with ultraviolet (UV) light from a 5W lamp, positioned 10-15 cm away, for 180 minutes The quality of the passion fruit is evaluated every two days, with three iterations for each treatment pattern.

The hardness of passion fruit is assessed using the Rockwell hardness test, which involves applying stresses with a tungsten carbide ball or a spheroconical diamond indenter Proper preparation of the testing and sitting surfaces is crucial, as inadequate preparation can lead to test failures or inaccurate readings After preparing the surface, a mild load, typically between 3 and 5 kgf, is applied to calibrate the testing apparatus Subsequently, a heavier load, ranging from 15 kgf to 150 kgf depending on the material's strength, is applied and held for a specified duration The depth of the indenter's penetration during the transition from mild to heavy load is then measured to calculate the hardness.

3.3.5 Passion fruit weight loss experiment

RESULT AND DISCUSSION

Synthesis of TiO2

Several methods for producing nano-sized TiO2 particles or TiO2 films have been developed

The sol-gel process, first introduced by Geffcken and Berger in 1939, has gained significant attention due to its simplicity and effectiveness This technique is favored for producing TiO2 because it operates at low reaction temperatures, ensures good chemical homogeneity, requires inexpensive substrates, and yields high-purity products The process involves the reaction of precursors, such as titanium alkoxide, with water, typically in alcoholic solutions, and often includes catalysts like hydrochloric acid to regulate the reaction.

Titanium dioxide nanoparticles are synthesized using the sol-gel method, which involves two distinct solutions The first solution is prepared by mixing 147 mL of isopropyl alcohol with 50 grams of titanium butoxide in a 500 mL beaker, followed by sealing and stirring for 30 minutes to stabilize the mixture The second solution consists of 200 mL of water and 12.5 mL of 0.25M HCl This second solution is then added to the first solution, and the combined mixture is stirred for 6 hours at room temperature (25 °C) After stirring, the solution is poured into petri dishes, with each dish containing 50 g of the mixture, and subsequently dried in a dryer.

The process involves drying materials at 150 °C for 12 hours, followed by grinding the dried pieces into powder This powder is then fired at 800 °C for 3 hours, resulting in synthetic TiO2, which is obtained in a white powder form.

In this experiment, another type of TiO2 was used, the commercial TiO2 used to compare the efficiency in preserving passion fruit and affecting the film properties.

Effect of TiO2 on properties of chitosan films

Using two types of TiO2, synthetic TiO2 and commercial TiO2, to determine the influence of TiO2 on the properties of chitosan films

S20: Chitosan combine with synthetic TiO2 at 20%

S30: Chitosan combine with synthetic TiO2 at 30%

S40: Chitosan combine with synthetic TiO2 at 40%

C20: Chitosan combine with comercial TiO2 at 20%

C30: Chitosan combine with comercial TiO2 at 30%

C40: Chitosan combine with comercial TiO2 at 40%

Figure 4 1: Compare the moisture content of TiO 2 chitosan films Table 4 1: The moisture content of chitosan films and chitosan combine with TiO2

Moisture plays a crucial role in the effectiveness of packaging films, as it allows them to absorb moisture from moderately humid environments, which is essential for preserving perishable goods Accurately determining the moisture content of these films is vital for their application in food preservation Utilizing composites based on CH/IPA (Isopropyl alcohol) presents a promising solution for enhancing the quality of food packaging.

According to [48], the addition of TiO2 improves the water vapor barrier of the film

In this experiment, the moisture content of chitosan films remained constant with increasing concentrations of synthetic TiO2 In contrast, the moisture content increased for commercial TiO2 as its concentration rose, likely due to the presence of hydrophilic impurities in commercial TiO2 that contribute to higher moisture levels.

Chitosan films exhibited a higher moisture content compared to those supplemented with TiO2 Additionally, chitosan films combined with commercial TiO2 had greater moisture content than those with synthetic TiO2 This indicates that the incorporation of TiO2 effectively reduces the moisture content of the films.

4.2.2 Effect of TiO2 on the swelling degree of the chitosan film

Figure 4 2: Swelling degree of TiO 2 – chitosan films

Table 4 2: Swelling degree of the chitosan film and chitosan films combine with TiO2

Increasing the amount of TiO2 does not affect the swelling of either synthetic or commercial TiO2 samples Generally, commercial TiO2 exhibits less swelling compared to synthetic TiO2, likely due to its smaller particle size, which facilitates better dispersion within the polymer matrix of the chitosan film.

The pure chitosan film exhibits greater swelling compared to the chitosan film blended with TiO2, as the presence of TiO2 molecules restricts water from penetrating the polymer's molecular structure, leading to a less swollen film.

4.2.3 Effect of TiO2 on the solubility of the chitosan film

Figure 4 3; Effect of TiO2 on the solubility of the chitosan film Table 4 3: Solubility of the chitosan film and chitosan films combine with TiO2

The graph indicates that synthetic TiO2 exhibits optimal solubility at 40% concentration, whereas commercial TiO2 reaches its peak solubility at 30% This difference suggests that commercial TiO2 is generally less soluble than its synthetic counterpart, likely due to the superior dispersion of commercial TiO2 molecules in water.

The pure chitosan film was most soluble in about 9.21%, the addition of hydrophilic TiO2 molecules increased the water resistance as well as the solubility of the film

4.2.4 .Effect of TiO2 on the Moisture permeability of the chitosan film

Figure 4 4: Effect of TiO2 on the moisture permeability of the film in 12 th hour

Table 4 4: Moisture permeability of the film in 15 th hour

Water Vapor Permeability (WVP) is crucial for determining the shelf life of packaged foods, as it directly affects moisture protection and food stability High water content can lead to spoilage or mold growth during storage In experiments, membranes with TiO2 demonstrated lower WVP compared to those made solely from Chitosan, with the Chitosan membrane achieving the best permeability at 15.09 percent As the TiO2 concentration increased from 20 percent to 40 percent, the moisture permeability of Chitosan membranes enhanced with synthetic TiO2 showed values of 14.91 percent, 14.58 percent, and 14.68 percent, respectively For commercial TiO2, the corresponding moisture permeability values were 14.81 percent, 14.57 percent, and 14.83 percent Both synthetic and commercial TiO2 effectively enhance moisture resistance at a concentration of 30%, as TiO2 hydrophilic molecules disrupt the molecular structure of polymeric films, preventing water permeation.

4.2.5 UV-vis Absorption spectrum and light transmittance of the film

To protect food from the effects of UV light, it is essential to prevent light exposure, making light transmission a key factor in evaluating the UV-blocking effectiveness of films The spectrum of various film types is illustrated in the figure below.

Figure 4 5: Light transmittance of chitosan and chitosan films incorporating TiO2

In comparison to films containing solely Chitosan, the addition of TiO2 significantly increases light reflection This is due to the fact that TiO2 absorbs UV-vis rays [51]

The light transmittance of films containing TiO2 decreases with increasing TiO2 concentration, showing no significant difference between 30% and 40% Commercial TiO2 effectively blocks nearly all UV-vis radiation across most wavelengths Previous research indicates that chitosan films combined with TiO2 achieve effective contrast The impact of increasing synthetic TiO2 from 30% to 40% is minimal, and the efficiency of commercial TiO2 remains nearly the same across concentrations of 20%, 30%, and 40%.

4.2.6 FTIR of synthetic TiO2 and commercial TIO2

Wavelength (nm) Chitosan Syn TiO2 20% Syn TiO2 30% Syn TiO2 40%

CM TiO2 20% CM TiO2 30% CM TiO2 40%

Figure 4 6: FTIR spectra of TIO2

The FTIR spectrum analysis of TiO2 was conducted to verify the molecular interactions between titanium and oxygen The illustration below compares the FTIR spectra of synthesized TiO2 with that of commercial TiO2.

TiO2 exhibits a spectrum ranging from 500 cm\(^{-1}\) to 850 cm\(^{-1}\), indicating the presence of titanium-oxygen bonds In synthetic TiO2, vibrations between 490 cm\(^{-1}\) and 500 cm\(^{-1}\) are clearly detectable, demonstrating successful modulation at the laboratory scale In contrast, commercial TiO2 presents challenges in observing these linkages, but this does not indicate the absence of TiO2.

4.2.7 Mechanical Properties of TiO 2 and commercial TiO 2 with chitosan film

Figure 4 7 Tensile strength of synthetic TiO 2 and commercial TiO 2 with chitosan film chitosan

Figure 4 8: Elongation of synthetic TiO 2 and commercial TiO 2 with chitosan film Table 4 5: Elongation of synthetic TiO 2 and commercial TiO 2 with chitosan film

The mechanical properties of chitosan films are evaluated through tensile strength (TS) and percentage elongation at break (E) Notably, chitosan film exhibits the lowest tensile strength, while the addition of TiO2 significantly enhances its strength The film containing 30% TiO2 achieves the highest tensile strength at 86.601 Pa, surpassing those with 20% and 40% TiO2, which measure 41.254 Pa and 60.477 Pa, respectively Interestingly, chitosan films with commercial TiO2 show a decreasing trend in tensile strength as the TiO2 percentage increases, with the 20% commercial TiO2 sample reaching about 48% In contrast, the synthetic TiO2 samples demonstrate a more pronounced variation in tensile strength with increasing TiO2 content.

Elongation data closely resembles tensile strength data, with chitosan film containing 30% synthetic TiO2 exhibiting the highest elongation among the samples Interestingly, chitosan samples do not have the lowest elongation; that distinction belongs to STiO2 (20%), which measures just 2% elongation, slightly below the chitosan samples Overall, the results indicate no significant difference in elongation between chitosan, synthetic TiO2, and commercial TiO2.

4.2.8 Thickness of TiO 2 -chitosan film

Figure 4 9: Thickness of chitosan film with synthetic TiO 2 and commercial TiO 2

Table 4 6: Thickness of chitosan film with synthetic TiO 2 and commercial TiO 2

Figure 4.9 indicates that the C40 sample exhibits the greatest thickness, comparable to that of pure chitosan film Notably, C40 differs significantly from C20 and C30, which show no substantial differences between them This suggests that the thickness increases with the addition of 40% concentration of commercial TiO₂ Conversely, the S20, S30, and S40 samples demonstrate a decreasing trend in thickness as the concentration of synthetic TiO₂ in the chitosan film increases.

Application of TiO2- Chitosan films on passion fruit preservation

Using two types of TiO2 are synthetic TiO2 and commercial TiO2 for application in the preservation of passion fruit

S20: Chitosan combine with synthetic TiO2 at 20%

S30: Chitosan combine with synthetic TiO2 at 30%

S40: Chitosan combine with synthetic TiO2 at 40%

C20: Chitosan combine with comercial TiO2 at 20%

C30: Chitosan combine with comercial TiO2 at 30%

C40: Chitosan combine with comercial TiO2 at 40%

For purpose of data analysis and data interoretation, it is important to have uniform representation of hue derived from L, a, b space Using standard calculation for hue (arc tan(b/a))

If color located in quadrant I (+a, +b):

If color located in quadrant I (-a, +b):

If color located in quadrant I (-a, -b):

If color located in quadrant I (+a, -b):

4.3.1.1 Sample with UV and sample without UV

Figure 4 11: L of samples with and without UV

Time (days) control samples chitosan film Synthetic TiO2 (with UV) Synthetic TiO2 (no UV)

Figure 4 12: The hue angles of samples with and without UV

As passion fruit ripens, its color undergoes a noticeable change, which can be accurately measured using a portable digital color analyzer that provides L, a, and b statistics This analysis, conducted over four days, investigates the impact of TiO2 photolysis and highlights the influence of UV light on the fruit Additionally, the observed color change is linked to variations in other important characteristics of the passion fruit.

The analysis of figure 4.11 reveals that both chitosan film samples and control samples experience a slight decrease in lightness after two days, followed by a gradual increase on day four In contrast, samples with TiO2 film show an initial increase in lightness on day two, but those without UV treatment exhibit a downward trend thereafter Conversely, TiO2 film samples exposed to UV light continue to increase in lightness by day four, suggesting that UV exposure may enhance the lightness of passion fruit Figure 4.12 indicates that only the hue angles of chitosan film samples decrease slowly over four days, resulting in a redder appearance of the passion fruit By the end of the observation period, both the TiO2 and control samples display a more yellow hue, with the synthetic TiO2 sample (without UV) showing the most significant color change and the highest level of yellowing.

4.3.1.2 Cold temperature (5 o C) and room temperature (25 o C) samples

Time (days) control samples chitosan film Synthetic TiO2 (with UV) Synthetic TiO2 (no UV)

Figure 4 13:L of TiO2-chitosan film under cold temperature and room temperature

Time (days) controlled samples (cold temperature) chitosan (cold temperature) sythetic TiO2 film (cold temperature) commercial TiO2 (cold temperature) controlled samples

Figure 4 14 The hue angles color of samples under cold temperature and room temperature

The study utilized a portable color analyzer to assess the impact of TiO2 photolysis over four days, focusing on the effects of UV light under cold and room temperature conditions Results indicated that the lightness of commercial TiO2 significantly increased on day 2 but dropped sharply to 41 by day 4, while synthetic TiO2 consistently decreased from 52 to 41 Both controlled samples at room and cold temperatures exhibited similar lightness trends, showing no significant changes over the four days However, the hue angle of cold temperature samples shifted towards red, contrasting with the room temperature samples The hue angles of synthetic TiO2 decreased from 35 to 30, indicating a redder tone, while commercial samples displayed drastic changes, with hue angles dropping from 44 to 32 before rising to 45, reflecting a transition from red to yellow due to the inherent white color of commercial TiO2.

Table 4 7: Formula of calculating weight loss percent

4.3.2.1 Samples with different amount of TiO2

Table 4 8: Weigh loss of samples with different amount percentage of TiO 2 in chitosan solution

20% TiO2 (g) 30% TiO2 (g) 40% TiO2 (g) Control sample (g)

Figure 4 15: Weigh loss of samples with different amount percentage of TiO 2 in chitosan solution

The study investigates the impact of varying percentages of TiO2, based on 2% chitosan, over a period of 6 days on weight loss, a key factor in the ripening of passion fruit The objective is to identify the most effective TiO2 concentration to enhance the storage duration of passion fruit.

The controlled samples exhibited the highest weight loss of 40% after six days, while on day two, the 20% TiO2 passion fruits showed increased weight loss starting from day four, likely due to their younger age, higher metabolic rate, and softer rind tissue Conversely, the samples with 20% TiO2 experienced the least weight loss at just 5% By day six, the weight loss for both 20% and 40% TiO2 samples was similar at 37% Notably, the 30% TiO2 samples had the highest weight loss on day two, indicating that TiO2 concentrations influence the ripening time of passion fruit.

The study observed weight loss over time for samples containing varying percentages of TiO2 (20%, 30%, and 40%) compared to a controlled sample Significant differences in weight loss were noted between the TiO2 samples and the control However, further repeated tests and additional samples are necessary to draw definitive conclusions regarding the impact of different TiO2 percentages on weight loss.

4.3.2.2 Samples with UV under cold temperature and room temperature

Figure 4 16: Weight loss between samples with TiO 2 in chitosan solution under cold temperature (5 o C) and control sample of room temperature after 4 days

The study investigates the impact of TiO₂ on passion fruit under cold temperatures, comparing treated and untreated samples Results indicate that control samples exhibited the highest weight loss, with a linear increase in weight loss percentage correlating with storage duration and temperature Notably, after four days, the highest weight loss of 20% occurred at 25°C These findings align with Pruthi (1963), who noted that weight loss in purple passion fruit escalates with elevated temperatures and extended storage Samples treated with TiO₂ under cold conditions demonstrated the lowest weight loss due to enhanced photolysis, while untreated samples and those with only chitosan experienced greater weight losses of 10.3% and 8.3%, respectively Thus, TiO₂ significantly benefits passion fruit preservation in cold storage.

4.3.2.3 Samples with UV and without UV

Time (days) control sample (room temperature) controlled sample (cold temperature) chitosan film

30% synthetic TiO2 samples (cold temperature) Commercial TiO2

Figure 4 17: Line chart show weight loss of sample with and without UV treating after 6 days

The study investigates the weight loss of samples treated with TiO2 both with and without UV exposure Results indicate that UV treatment enhances the effectiveness of TiO2, highlighting its role in extending the storage life of passion fruit The controlled sample and the one without UV treatment exhibited similar and significant weight loss, while the TiO2-treated sample with UV exposure showed reduced weight loss This underscores the importance of using TiO2 in conjunction with UV light to prolong storage duration.

4.3.3 Effect of hardness on fruit ripening

The ripening of climacteric fruits like passion fruit is influenced by ethylene, leading to a softening process that affects postharvest quality and storage potential To assess the impact of chitosan-coated TiO2 film on the hardness of passion fruit, we can simultaneously measure the hardness of wrapped and unwrapped samples The initial hardness on the first day is set at 100%, and as the days progress, the fruit's hardness decreases, reflected as a percentage reduction.

4.3.3.1 Passion fruit's hardness without UV exposure

Time (days) control fruit STiO2 ( with UV) STiO2 ( without UV)

Table 4 9: Prediction of fruit hardness during ripening

Figure 4 18: The line graph of the hardness change of passion fruit without UV irradiation

According to the line graph, there isn't much of a difference in the hardness of samples that are

The study examined the effects of varying TiO2 concentrations in chitosan films, specifically 20%, 30%, and 40%, compared to standard samples The standard sample maintained a TiO2 content of approximately 41.32% in the 30% and 40% samples, while the TiO2 hardness of the fruit decreased significantly to about 35.77% by the end of the study Although the fruit's weight loss was less pronounced with higher TiO2 ratios, it remained greater than that of the standard sample until reaching a concentration of 40% Ultimately, no significant differences were observed between the samples.

4.3.3.2 Passion fruit's hardness with UV exposure

H ar d n es s Perc en ta ge (% )

Time (day) Synthetic TiO2 20% Synthetic TiO2 30% Synthetic TiO2 40% Control sample

Figure 4 19: The line graph of the hardness change of passion fruit with UV irradiation

The line graph indicates that UV radiation exposure enhances the stiffness of modified samples, bringing it closer to that of the reference sample On the fourth day of storage, the UV-irradiated samples with 30% and 40% TiO2 achieved hardness values of 50.57% and 44.56%, respectively, compared to 41.33% for untreated samples Reducing TiO2 to 20% resulted in a hardness approximately 37.55% lower than the standard sample under UV exposure Overall, while the differences among the samples are not pronounced, the highest hardness retention for the fruit occurs at a 30% TiO2 concentration.

4.3.3.3 Compare the difference hardness when storage at different temperature and different type of TiO2

H ar d n es s Perc en ta ge (% )

Time (day) Synthetic TiO2 20% UV Synthetic TiO2 30% UV Synthetic TiO2 40% UV Control sample

Figure 4 20: Compare the difference hardness when storage with prepared TiO2 and commercial TiO2

Research indicates that UV light irradiation of fruit, combined with a 30 percent concentration of TiO2, effectively preserves firmness Consequently, all subsequent trials maintained this fixed concentration of TiO2.

In the study of standard sample storage, various formulations of TiO2 were prepared, including 30 percent TiO2 with and without UV irradiation, as well as 30 percent commercial TiO2 subjected to UV irradiation Additionally, a sample coated solely with chitosan and without TiO2 was included The hardness measurements taken on the final day of storage revealed values ranging from 45 to 47 percent, with the commercial TiO2 at 30 percent with UV irradiation demonstrating the highest hardness at approximately 53.40 percent.

H ar d n es s p erce n ta ge (% )

Control sample Synthetic TiO2 30% UV Synthetic TiO2 30%

Figure 4 21: Compare the difference hardness when storage at different temperature

At lower temperatures, the hardness of the samples showed minimal variation, likely due to the limited sample size or the lack of significant impact from cold storage compared to normal temperature.

In summary, UV-irradiated TiO2 demonstrates superior effectiveness in enhancing fruit hardness compared to unirradiated TiO2, particularly at a concentration of 30 percent However, it is important to note that cold storage does not influence fruit hardness.

The results showed that the tomato fruit treated with TiO2 had a different hardness with the control sample, Tomato fruit treated with TiO2 had stronger hardness than control sample