THE JOINT ACADEMIC PROGRAM OF EXECUTIVE MASTER IN SCIENCES AND MANAGEMENT OF THE ENVIRONMENT BETWEEN INDUSTRIAL UNIVERSITY OF HOCHIMINH CITY AND LIEGE UNIVERSITY or Université fe éX\'H::::: yf INDUSTRIAL TA DUC TRUNG PRODUCTION OF ANTIBACTERIAL GLASS USING NANO SILVER Major: EXECUTIVE MASTER IN SCIENCES AND MANAGEMENT THE ENVIRONMENT MASTER’S THESIS HOCHIMINH CITY, 2022 OF The project was completed at The Industrial University of Hochiminh City Supervisor’s name: Associate Prof Le Hung Anh (Write full name and signature) The thesis was taken at The Industrial University of Hochiminh City date 17 February, 2023 Committee members (name): Associate Prof Nguyen Thanh Binh - Committee Chair Dr Nguyen Thi Thanh Truc ¬ - Commissioner Dr Nguyen Thi Ngoe -‹- - Secretary (Write full name and signature) COMMITTEE > ho CHAIR DEAN OF INSTITUTE OF ENVIRONMENTAL SCIENCE, ENGINEERING AND MANAGEMENT P0$.TS LÊ HÙNG ANH ACKNOWLEDGEMENTS In order to complete this graduation thesis report, I have received a lot of help, guidance and input from many people First of all, | would like to express my sincere thanks to my instructor - lecturer of Ho Chi Minh City University of Industry - Assoc Dr Le Hung Anh and Dr Pham Trung Kien - lecturer at Ho Chi Minh City University of Technology, during the past time, he has guided me very enthusiastically Thanks to the guidance of the teacher, I know how to study, work and research topics scientifically and effectively And thanks to the dedicated guidance and guidance of the teacher, I have gained a lot of knowledge, so that I can complete this graduation thesis report Sincere thanks to the laboratory staff, of the Institute of Science, Technology and Environment Management and the Faculty of Materials Technology for creating the best conditions for equipment and tools during the experiment period At the same time, I would like to express my thanks to the previous classmates of the environment, the wedsite management boards for documents on the environment for creating conditions for the team to learn and investigate and survey to get the completed data project plan Although I have tried to complete the report as much as possible, it inevitably has shortcomings, I hope to receive valuable contributions from teachers and professors ABTRACT Nanosilver (AgNPs) has good bactericidal ability to create a clean environment, minimizing the possibility of spreading diseases from glass and porcelain surfaces The subject covered the nano silver layer on the glass surface by dipping and spinning coating technique Through the methods: FT-IR (assessment of physical and chemical characteristics of solution), thereby determining coconut oil is a good solvent, and the ratio of resinate and coconut oil 1:20 (with gram of solid resinate: 20 ml of coconut oil) selected as the optimal ratio to cover silver resintae with glass XRD (identifying the product to be nano silver), SEM (determining the size of the particle after calcination), EDX (determining the composition of glass material after calcination with Ag + ions), UV-VIS (measuring the transmittance of materials after silver nanoparticles) a defined topic on the glass surface exists a layer of nano silver, the size of the nanoparticles is relatively evenly distributed on the surface of coated glass and the glass sample after coating has UV resistance is quite good In addition, the antibacterial Escherichia coli, test with five types Staphylococcus of bacteria aureus, causing Pseudomonas hospital aeruginosa, infections is Salmonella Typhimurium, Bacillus cereus, the silver-coated glass for silver has very good results All samples influenced the growth of bacteria, with the two types of Escherichia coli, Pseudomonas aeruginosa giving complete resistance Since then, the thesis has had high applicability to reality and is the foundation for some economic sectors in general and the hospital environment in particular TABLE OF CONTENTS LIST OF TABLE LIST OF FIGURES LIST OF ABBREVIATIONS CHAPTER 1: INTRODUCTION 1.1 The necessity of the topic 1.2 SO DjeCtives OF the SHUG: «sind aiustadharentycrenyacsnaciuemuncssnatssotoran alceuuyeen 1.3 Object ofresearch - Scope of research -c-csc ode 1.3.1 Research subjects 1.3.2 Research scope 1.4 Research content 1.5 Scientifiezand practical meanings ' .ccocossoseccecsstex ccnporsiiissancusnesateneasasddvecneendvens TG INOVELY SOE MNE TOPIC, 77 .ctbseeaasteaneertzee sree Snrnnsinessndashbtanedan tro edranenenponcesdenstnsbecttoet CHAPTER: OVER VIEW cississssscesscssoscascssosescessnsssvassonssseasosssdsssessssassosesceasvacseenee Lu Intraduction.of silver nanomaterials sccccsosssessoedesdseasa tivsusncatvasescssooatoucadstepel DAL e Silver Rano CONCE PE i siennciteesunces ovnder'davondldicaauleswnsssannnvedeensdeaeospancacsimeeataetetes See DLO The chatactenisttesoF natiO SUV CR siaxssscssiondseesasbliG04sesc0sesisabksSs 2.1.3 Antiseptic mechanism of nano SilVer ce eeseeeeeceneeeeeceseeeeeceneeeeseneneeneees 2.1.4 Methods of synthesizing nano SỉÏV€T .-+55 tre i 215s Application Of Nano SILVER - :0:coespecdeaneestnennenezeernenttonsaydenonetensebenneeentarstaia 10 D2 OVEVIEW OE COCONUE, OL a tesssscrsccessiens sostssotenrcesdsticcuunscssealoosvenlsunlemedna venders 13 2.2.1 General introduction about coconut-Oil cc ccreieveevsssseennsssencsesstenerenccice 13 2.2.2 Coconut oil production technology - cssscesecslscciceeesceicstesceeqecseceneeseectnsereaces 14 2,263 ADIDIIGAHOI sysxsss1nsEitssesexrsinasasuepgliaslossssgrdkasxEd45EascuoSatisssaxslt U35 40aasu S5, Eg 17 D5: ME(hodS:0T:6LEHLTHESHIDINL se s32 ResisvasdlrerbeestasiorsthefmeraeaisiEetiiag ad tiệc 18 2.3.1 Physical method 2.3.2 Chemical method (Sol - gel) CHAPTER 3: MATERIALS AND METHODS 3.1 Materials and tools 3.2 Lhe research meth Od ology.) c saserissininesteneseonteathondunavietdinssentuonsnerddetsestuestanraee 30 3.3 Test design 11 4.1 Determine the viscosity of a silver resinate mixture - eoconut oil 38 4.2 Determination of silver content in silver resinate mix(ure s+sz+ 39 4.2.1 Determined Dy FU UR thet 6d scssesssxssvosasossa ea cariariassseieneeeciell nauseanasd eanernencbons 39 4.2.2 Determined by XRD method: s sccsseivesesveassseaysvvelssasversteisotvararatotecaee 40 4.3 Determination of silver size and elemental composition in coated and calcined ÏHSS, SAHIDIBRssriecsissssE llslobs2i01200x00p0g315606gasss,xes10x4stsa2aoVsadyoiasÐe th 42 431-:12eterrnninetl/Dy 2K) HTIEKHODseusicieictosarosaaaoslnoglisssasosasiaOcdubni 42 4.3.2 Observe the surface of SEM gÌaSs cu H2 -012121511151 11.1x2 42 4.3.3 Analysis of elemental composition of EDX glass ¿525552 44 4.4 Evaluate the results of silver nano coating on glass by UV - VIS method 44 4.5 Assess the antibacterial properties of nano-silver on representative bacteria TYPES ls scsstste a thestomenaegre cusssenauai es aM RUN Naceemecomu cats ccauce encores elanPa 45 4.6, General: GISCUSSION s:0:.sssscsssssssscassssiacscemnearasninanchiedarmbenieca 25a0i9386/x2xn s2 48 CHAPTER 5: CONCLUSIONS AND RECOMMENDATIONS 50 (i6 ]HSTOHbuoi 220g 10aitlnplEt scS Dạ ti ỆG tho ae GD eseádi di AI 50 GHUOBExoroidsnsosaattiioedbdiiutonsbsdissytgpssaaimaasestidtlsdssislUnicusstUMAuraEai sltansui 51 TREEBERENCES oscycsossesovsenescavisossososvavecssvcusecussusrssvevivuvessbaivitvcivluvastsosesetessioneiaees 52 LIST OF TABLE Table Table Table Table Table Table 2.1 3.1: 3.2: 3.3: 4.1: 4.2: Number of silver atoms in a unit of volume Chemicals used in research Instruments used in the process of research Equipment in the research process Results of viscosity measurement Antibacterial test results of glass (spin coating, dip coating) LIST OF FIGURES Figure 2.1 silver element (Ag) Figure 2.2 Antiseptic mechanism of nano silver Figure 2.3: Application of silver nano in household products Figure 2.4: Application of silver nano in agriculture Figure 2.5: Nano Silver water filter core ae Figure 2.6: Application of silver nano in textiles Figure 2.7: Coconut essential oil $i Figure 2.9: Technology diagram of coconut oil production by hot pressing - hot Prescinorneth edn sce Wes cv nen ti nhi 6m20 Liga tsatifs XE is f0 ues oceraie 16 Figure 2.10 Diagram of coconut oil production technology by centrifugal method SeucustassSocgbuvavslevstitaslnsuvscosctssiudscicedesass ova gevasetoavendes saul hevouds cuesbeucseacstsuecuals een taente ts 17 Figure 2.11: Principle of method of evaporation si LƠ Figure 2.12: Principle of sputtering process Figure 2.13: Evolution of Sol - gel process Figure 2.14: Some methods of Sol - gel membrane coating Figure: 2.15: Dip = coating process cticiccccciissecieiccseseecceeses Figure 2.16: Steps of the Spin - coating process Figure 3.1: Process diagram of manufacturing antibacterial glass Figure 3.2 Chart of experimental assessment 0Ÿ reSuÏfs -+-+++++x+x++ Figure 4.1: FT-IR spectrum of (a) NaOH 1M; (b) coconut oil, (c) AgNO3 and (d) silver resinate Figure 4.2: XRD result of Silver resinate sample after drying 105°C/18h a Figure 4.3: XRD result of Silver Resinate sample after heating 500°C / 3h 41 Figure 4.4: XRD spectrum of (a) uncoated glass sample; (b) sample of dip coated glass, calcined at 500°C/3 hours; and (c) Spinning coated glass sample, calcined at SOOLS/SEROUES ses fiers ae, Mies ent asset fe sssaedgunaen ieee maa rel eee 42 Figure 4.5: SEM images of dipped and spin coated glass samples at different magnifications 43 Figure 4.6: Results of EDX surface dip coated glasses Figure 4.7: Results of EDX spin coating glass surfaC€s . - cccccccccx+ 44 Figure 4.8: Results of transmission oftwo ølass samples ¿ -+ General goal Development of silver nano coating materials to apply in practice, to improve the environment, prevent harmful bacteria to humans > Specific objectives Initial research on manufacturing antibacterial glass by coating nano silver with coconut oil solvents 1.3 Object of research - Scope of research 1.3.1 Research subjects - Nano silver Glass - Coconut oil 1.3.2 Research scope > Space - To be accomplished with the support of the following laboratories: - Solid waste research and intensive research laboratory of the Institute of Science, Technology and Environment Management, Industrial University of Ho Chi Minh City (12 Nguyen Van Bao, Ward 4, Go Vap District, Ho Chi Minh City) - Silicate laboratory of Ho Chi Minh City University of Technology (268 Ly Thuong Kiet, Ward 14, District 10, Ho Chi Minh City) - Center for BioScience and Biotechnology at VNUHCM-University of Science (227 Nguyen Van Cu, Ward 4, District 5, Ho Chi Minh City) > Scale - Laboratory Based on the results of XRD analysis, it shows that the silver resinate produced after drying does not have the appearance of silver molecules but the appearance of volatile organic substances Resinate silver after calcination at 500°C, the presence of Ag* ions exists in nano form and there is no organic matter 4.3 Determination of silver size and elemental composition in coated and calcined glass samples 4.3.1 Determined by XRD method Figure 4.4 shows the XRD spectrum results of (a) uncoated glass samples, (b) sample of dip coated glass, calcined at 500°C/3 hours; and (c) Spinning coated glass sample, calcined at 500°C/3 hours, respectively as follows: Intensity (a.u) tt (c) Spinning coated glass sample, calcined at 500°C/3 hours ee | | 10 ae 15 20 25 39 35 2theta (degree) 40 (b) Dip coating glass sample, calcined at 500°C/3 hours (a) Uncoated glass sample 45 50 Figure 4.4: XRD spectrum of (a) uncoated glass sample; (b) sample of dip coated glass, calcined at 500°C/3 hours; and (c) Spinning coated glass sample, calcined at 500°C/3 hours Discussion: According to the chart, we see: - All three XRD spectra not appear crystals of Ag or AgNOs, indicating that AgNO; salt has been completely dissolved, existing in amorphous form 42 - The amorphous structure of Ag together with the amorphous structure of the glass substrate will help increase the ability to diffuse Ag ions into the glass substrate when heated at 500°C 4.3.2 Observe the surface of SEM glass SEM results of the surface of dipped and spin coated glass samples at different magnifications (Figure 4.5), as follows: (a1) Dip coating 500 C/3h, 1.000X |] (b1) Spinning coated 500 C/3h, 1.000X (a2) Dip coating 500 C/3h, 2.000X (a3) Dip coating 500 C/3h, 5.000X (b2) Spinning coated 500 C/3h, 2.000X (b3) Spinning coated 500 C/3h, 5.000X Figure 4.5: SEM images of dipped and spin coated glass samples at different magnifications Discuss: - Based on analysis by SEM method we can see the formation of crystals on the glass surface - The spinning coating has a larger crystal surface than the dipping coating - The spinning coating has silver crystals on the surface of the glass more than the dipping coating 43 4.3.3 Analysis of elemental composition of EDX glass EDX results of cross section of two samples of embedded lamination glass (Figure 4.6), rotating coating (Figure 4.7) as follows: O-K Si-K E—150um Ag-L [E—150um T— 150um Figure 4.6: Results of EDX surface dip coated glasses O-K Si-K —¬50um Ag-L E—50um E—150um Figure 4.7: Results of EDX spin coating glass surfaces Discussion: The EDX method determines the coating thickness and composition of glass elements after coating with silver nano Based on the analysis results, we see that both glass samples have silver molecules However, the silver molecular density on the spinning glass sample is higher than the silver molecular density on dipping glass sample 4.4, Evaluate the results of silver nano coating on glass by UV - VIS method The results of UV-VIS transmission analysis of two glass samples (spin coating, dip coating) after calcined at 500°C / 3h (Figure 4.8) are as follows: (a) Uncoated glass sample ° (b) Dip coating glass sample, calcine at 500 C/3 hours Transmittance / % {c) Spinning coated glass sample, calcined at 500 C/3 hou 7% it 300 350 400 450 500 550 600 650 700 750 800 Wavelength / nm Figure 4.8: Results of transmission of two glass samples Discussion: UV-VIS method measures the transmittance of a material after silver nano coating Based on the chart we see no difference between dipping and spinning overlay At a wavelength of 420 nm is the characteristic absorption point for silver From 500 nm and above most light is transmitted, UV rays are filtered Therefore, we can conclude that both embedded and rotating glass samples are UV resistant 4.5 Assess the antibacterial properties of nano-silver on representative bacteria types In recent years, the causative agent of nosocomial infections is diverse, but mainly Gram-negative bacteria - Gram-negative bacteria: Echerichia coli, P aeruginosa, Salmonella, Acinetobacter are multi-antibiotic resistant bacteria e Salmonella: often causes infectious diseases, food poisoning, typhoid Escherichia Coli: causes urinary tract and surgical site superinfection Pseudomonas antibiotics; aeruginosa: often cause has properties disease in malignancies, 45 of resistance patients with to antiseptics weakened and resistance, - Gram-positive bacteria: account for about 20% of nosocomial infections such as S aureus, Bacillus, e Staphylococcus aureus is capable of causing many different diseases such as skin infections, bacteremia, pneumonia In this thesis, five strains of bacteria were selected strains of bacteria (E coli, S.aureus, Five representative standard P.aeruginosa, S.Typhimurium, B.cereus) provided by The Center for Biosciences and Biotechnology, University of Science in HCM City The results of assessing the antibacterial properties of glass samples (spin coating, dip coating, uncoated silver resinate) are shown in Table 4.2: Table 4.2: Antibacterial test results of glass (spin coating, dip coating) Bacterial Bacterial concentration | concentration No | Sample Test criteria Antibacterial ability TCVN Escherichia coli 9064:2012 Samples | Antibacterial ability | of spinning coating | glass Test method Bacillus subtilis before after coating coating (0h) (24h) (CFU/ml) (CFU/ml) 4,2 x 10° Not detected 2,1 x 10° 1,8 x 10° : TCVN é Ho Antibacterial ability Staphylococcus TCVN 9064:2012 1,6 x 10 TCVN 9064:2012 3/2510 i 3,5 x 10 i aureus i : sử Antibacterial ability 46 Not detected Pseudomonas aeruginosa Antibacterial ability Salmonella TCVN 9064:2012 1,8 x 10° 2,6 x 107 TCVN 9064:2012 4,2x 10° 1,9 x 107 2,1 x 10° 2,7x 107 Typhimurium Antibacterial ability Escherichia coli Antibacterial ability Bacillus subtilis Antibacterial ability Uncoated glass Staphylococcus TCVN 00611012 ñ TCVN 9064:2012 1,6 x 10 Š 3,4x10 : aureus samples Antibacterial ability Pseudomonas TCVN 9064:2012 3,2 x 10 TCVN 9064:2012 1,8 x 10° : 5,6 x 10 aeruginosa Antibacterial ability Salmonella 1,2 x 10” Typhimurium Source: Antimicrobial test results at the Center for Bioscience and Biotechnology, University of Science, VNU HCMC Note: TCVN 9064-2012 National Standards Paints and Plastics - Measurement of antibacterial activity on surfaces Discussion: Based on the analysis results table, we see: - Uncoated glass samples after 24h all types of bacteria are growing well in large numbers 47 - Samples of spinning coating glass is resistant to all type of Escherichia coli, Staphylococcus aureus, Bacillus Particularly cereus Pseudomonas with aeruginosa, two type Salmonella of Escherichia Typhimurium, coli, Pseudomonas aeruginosa were completely destroyed - Samples of dipping coating glass does not have complete antibacterial but it can inhibit the growth of types of bacteria 4.6 General discussion Through the analysis results obtained, show us: - Coconut oil is suitable as a solvent to create coating silver resinate - Based on the EDX results and the antibacterial test results, the rotational coating method has better results than the dip coating method - Compared to the topic "Fabricating antimicrobial glass using nano silver" by students of Institute of Science, Technology and Environment in 2018, this report has the following differences: + Determining the exact ratio of coconut oil solvent and silver resinate is 1gam resinate for 20ml of coconut oil + Compared to the screen printing method (the topic of "Fabricating anti-bacterial glass using nano silver" in 2018), the rotating and dipping coating method is more advantageous and easier to apply for industry + Compared with the antibacterial results of the project "Manufacturing and testing antibacterial glass using silver nanoparticles" in 2018, selecting bacteria types (Escherichia coli, Staphylococcus aureus, Pseudomonas aeruginosa) achieved very good resistance results with two type Escherichia coli and Pseudomonas aeruginosa, weak resistant Staphylococcus aureus With the theme of "Manufacturing antibacterial glassware using nano silver" in 2019, the project chose to test on types of bacteria: Escherichia coli, Staphylococcus 48 aureus, Pseudomonas aeruginosa, Salmonella Typhimurium, Bacillus cereus , the project achieved 100% resistance to type of Staphylococcus Escherichia aureus, coli and Pseudomonas aeruginosa, and type of Salmonella Typhimurium, Bacillus cereus achieved weak resistance 49 CHAPTER 5: CONCLUSIONS AND RECOMMENDATIONS Conclusion After the research and analysis results, some conclusions can be drawn as follows: - Coconut oil is suitable as a carrier to create silver resinate coating - Through infrared characteristics of the analysis results FT-IR solution Show evaluates the physical that silver reacts with and chemical saponification and produces RCOOAg - Pass the test results viscosity of coating solution The ratio of 1:20 (with gram of solid resinate: 20 ml of coconut oil) is the optimal viscosity ratio And the 1:20 ratio was chosen as the ratio to conduct silver coating on Resinate - Through XRD analysis results, it shows that silver resinate after calcination at 500°C has created Ag* ions exist in nano form, high practical applications - SEM analysis results show that glass samples after firing in both spin and dip coating methods have nano silver on the surface - Through the results of EDX analysis, it shows that glass samples after firing in both coating and dipping methods contain silver elements Nano-silver should have gone inside the structure of the crystal glass, not just on the surface of the glass - In addition, EDX results show that the rotating coating method is more advantageous because the silver density on the rotating glass is higher and more uniformly distributed - UV-VIS analysis results show that the transmittance is reduced compared to the uncoated sample up to 80%, at 420 nm is the typical absorption wavelength of silver Prove that the coating is silver and highly UV resistant - Through the antibacterial and EDX results, it is shown that the spinning coating method is more advantageous because the silver density on the spinning glass is higher and more evenly distributed So spin coating glass has better antibacterial properties than dip coating glass 50 At the end of the research process, it was successfully created coconut oil soap and silver resinate coating Initial development of antibacterial glass, prevention, and resistance to five Staphylococcus Bacillus cereus) specific aureus, This bacteria in Pseudomonas has the health sector aeruginosa, great significance is (Escherichia Salmonella in terms coli, Typhimurium, of the environment and especially the hospital environment Request - Should be applied in hospitals, clinics needing environment free of bacteria Through practice, it is also possible to apply antibacterial glass extension to food, industry, agricultural and aquatic product processing industries to improve the quality of food materials - Survey to find out some other solvents instead of coconut oil but still retain the commercial value of its country Such as replacing coconut oil with peanut oil, cashew oil, palm oil, canola oil - Subsequent studies can provide optimal coating methods for glass to achieve a uniform and beautiful coating - Research and test the antibacterial level of silver-coated glass plates on many different types of bacteria - Can increase the original silver content to achieve better antibacterial results 5] REFERENCES ‘Vietnamese [1] Do Quang Minh (2015), "Glass production technique", National University Press, Ho Chi Minh City [2] Hoang Van Duc, Coconut tree, Hanoi Agricultural Publishing House, 1991 [3] Ngo Quoc Buu, Nguyen Hoai Chau, Tran Thi Ngoc Dung, Nguyen Gia Tien, (2011): Studies on manufacturing of topical wound dressings based on nanosilver produced by aqueous molecular solution method Journal of Experimental Nanoscience, Vol 6, No 4, pp 409 - 421 [4] VNU Journal of Science: Natural Science and Technology, Volume 32, Issue (2016) 53-57 [5] Nguyen Duc Hung and nnk./ VNU Science Review: Natural Science and Technology, Volume 32, No (2016) 53-57 [6] Journal of Science and Technology 53 (6) (2015) 715-722 [7] Tran Thi Ngoc Dung, Ngo Quoe Bieu, Nguyen Hoai Chau, Nguyen Vu Trung, (2009), Researching the disinfecting effect of nano silver solution on vibrio cholerae bacteria causing cholera, Journal of Science and Technology, Vol 47, Issue 2, pp 47 =93 [8] Tran Thi Ngoc Dung, Nguyen Hoai Chau, Ngo Quoc Bieu, Nguyen Thi Ly, Dang Viet Quang, (2009): Research on using nano silver as a disinfectant solution in spray form, Journal of Science and Technology , T 47, Sé 4, pages 95 - 102 [9] Tran Thi Ngoc Dung, Nguyen Hoai Chau, (2015): Research on attaching nano silver to porous ceramic films by in-situ reduction method, Journal of Science and Technology, Vol 53, No 6, page 715 - 722 [10] Truong Van Tan, Articles on nanotechnology on the Web: ERCT.com [11] Le Thanh Son, Nguyen Dinh Cuong, (2014): Research on manufacturing and evaluating the ability to kill bacteria in the air of silver-impregnated filter plates, Journal of Analysis of Chemistry, Physics and Biology, Volume 19, Number 4, pages 15 - 20 [12] Le Khae Top (n.d), Creating films by Sol - Gel method [13] Pham Thi Thu Ha (2011), Synthesis of Ag / TiO2 nano for application in photocatalyst, Graduation thesis of University of Natural Sciences - Ho Chi Minh City [14] Nguyen Ngoc Hung (2011), Research and manufacture of silver nanoparticles and its antiseptic ability, Graduated thesis of University of Technology - Vietnam National University, Hanoi [15] Nguyen Duc Huu, Nguyen Hoai Ha, Tran Mau Danh (2005), Fabrication and application of magnetic nanoparticles in biomedical engineering, Report of the 6th National Physics Conference [16] Do Thi Xuan Thu, Nguyen Thi Ngoc Thuy (2011), Synthesis of nanocomposite Ag/ PVA by chemical reduction method [17] Nguyen Due Nghia, Nano Chemistry, Natural Science and Technology Publishing House, Hanoi, 2007 [45] Nguyen Thi Hang, Nguyen Thi Nhu Tuyen, Lam Thi Ngoc Ngan (2018), Manufacturing and testing antibacterial glass using nano silver English [18] Pichivittayakarn, W va céng su, Effects og fluid flowrate on coconut milk fouling at pasteurization temperature(70°C- 74,5°C), Songklanakarin J Sci Techol., Vol 28, issue 6, 2006, p.1275-1288 [19] P Chen, L Song, Y Fang, Synthesis of silver nanoparticles by — ray irradition in acetic water solution containing chitosan, Radiation Physics and Chemistry, 76(7), p 1165-1168,(2007) [20] S Shrivastava, T Bera, A Roy,G Singh, P Ramachandrarao and D Dash, Characterization of enhanced antibacterial effects of novel silver nanoparticles, Nanotechnology, 18, 103-205(2007) [21] AWWW - Disinfection of water using nanosilver-based platforms at point of use (POU) domestic appliances Arab Water World J XX XIII (5) (2009) 24-27 [22] Jiawei Sheng, Juan Li, JunYu - The development of silver nanoclusters in ionexchanged soda-lime silicate glasses, International Journal of Hydrogen Energy 32 (2007) 2598 — 2601 [23] G.A Mansoori, et.al Environmental application of nanotechnology, Annual Review of Nano Research, Vol.2, Chap.2, 2008, University of Illinois at Chicago, USA [24] Hilonga A., Kim J.-K., Sarawade P B., Quang D V., Godlisten S., Elineema G., Kim H T - Silver-doped silica powder with antibacterial properties Powder Technology 215-216 (2012) 219-222 [25] L Philiponi, Application of Nanotechnology: Environment, Nanoscience Center (NANO) Aarhut Unviversity of Denmark, 2007 [26] Ranjana S Varma, Kothari D C - Nano-composite soda lime silicate glass prepared usinh silver ion exchange, Journal of Noncrystalline Solids 355 (2009) 1246-1251 [27] Peters D P., Strohofer C., Brongersma M L et al - Formation mechanism of silver nano crystals made by ion irradiation of Na+ and Ag+ ion-exchanged sodalime silicate glass”, NIM B 168 (1999) 237-244 [28] Tran Hong Con, Dong Kim Loan, Pham Phuong Thao, (2009): Preparation of nanodimensional silver metal and application for drinking watertreatment, Journal of Science and Technology, T 47, No 2, pp 83 — 90 [29] Tran Thi Ngoc Dung, Ngo Quoc Buu, Dang Viet Quang, Huynh Thi Ha, Le Anh Bang, Nguyen Hoai Chau, Nguyen Thi Ly, Nguyen Vu Trung, (2009): Synthesis of nanosilver particles by reverse micelle method and study of their bactericidal properties, Journal of Physics: Conference Series, 187 (1), 012054, pp 1-8 [30] United Nations Environment Program (UNEP) (2004) [31] Wen-Ru Li, Xiao-Bao Xie, Qing-Shan Shi, HaiYan Zeng, You-Sheng OUYang, Yi-Ben Chen, (2010): Antibacterial activity and mechanism of silver nanoparticles on Escherichia coli, App! Microbiol Biotechnol, Vol 85, pp.1115- 1122 [32] Wenning Shena, Lajun Fenga, Hui Fengb, Zhenzhen Konga, Meijuan Guoa Ultrafine silver(I]) oxide particles decorated porous ceramic composites for water treatment, Chemical Engineering Journal 175 (2011) 592— 599 [33] Graf, Christina; Vossen, Dirk L.J.; Imhof, Arnout; van Blaaderen, Alfons (July 11, 2003), Langmuir 2003, [34] "A General Method To Coat Colloidal Particles with Silica”, 19, 6693-6700 Ngô Võ Thanh Kế, Nguyễn Thị Phương Phong (2009), Investigation of antibacterial activity of cotton fabric incorporating nano siliver colloid, Journal of Physics [35] Nikolaj L.Kildeby, Ole zandersen, Ramus E.roge, Tomlarsen, Rene Petrsen, Jacob F.Riis, (2005) Silver Nanoparticle [36] Fife, Bruce (2005) Coconut Cures Piccadilly Books, Ltd tr 184-185 ISBN 978-0-941599-60-3 [37] H.Bénnemann*, R.M.Richards, Nanoscopic Metal Particles — Synthetic Methods and Potential Applications, European Journal of Inorganic Chemistry, 10, p2455-2480, 2001 [38] H.Jiang, K.S Moon, Z.Zhang, S.Pothukuchi and C.P Wong, Variable frequency microwave synthesis of silver nanoparticles, Journal of Nanoparticle Research, 8, 117-124, 2006 Website [39] https://nanobacsuper.com/nano-bac-va-ung-dung-cua-nano-bac-trongnong-nghiep [40] https://www.slideshare.net/trongthuy2/chuyen-de-nghien-cuu-che-taovat-lieu-nano-bac-diem-8-hot [41] https://www.slideshare.net/ruaconconrua7 61/hong-Ic-1019082kha-lun-ttnghip [42] https://www.slideshare.net/8sOnc1/nghiencuchtohtnanobcvakhnngsatkhuncanokl [43] https://hakufarm.vn/tac-dung-cua-dau-dua/ [44] http://doan.edu.vn/do-an/vat-ly-cong-nghe-che-tao-cac-vat-lieu-tu-cau-truc- nano-40853/ [46] https://www.cs.megill.ca/~rwest/wikispeedia/wpced/wp/c/Coconut_oil.htm