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"[ABSTRAKSintesis TiO2 bermorfologi nanotube array bentuk film (TNTAs) telah dilakukan dengan proses anodisasi logam Ti dalam larutan elektrolit gliserol yang mengandung NH4F, dilanjutkan dengan annealing untuk membuat fasa kristal dari TNTAs. Optimasi berbagai parameter meliputi variasi kadar air dalam larutan elektrolit, perlakuan annealing, penambahan NaBF4, metode dan lama pengadukan serta variasi loading dan metode dalam penambahan dopan logam Pt. Hasil SEM/FESEM menunjukkan bahwa TNTAs berhasil disintesis dengan tube yang rapi, tegak lurus dan mempunyai kisaran diameter dalam antara 49-205 nm, tebal dinding 11-33 nm serta panjang 530-2577 nm. Annealing dengan H2/Ar merupakan cara yang efisien untuk memasukkan dopan C, N dan B dalam matrik TNTAs secara insitu saat anodisasi, sehingga diperoleh penurunan energi band gap sampai pada kisaran 2,20?3,10 eV. Kebanyakan TNTAs berfasa anatase dengan ukuran kristal dari 18?33 nm. TNTAs yang disintesis pada kadar air 25% volume dan annealing dengan 20% H2/Ar merupakan fotokatalis optimal yang menghasilkan kerapatan arus tertinggi. Uji TNTAs untuk memproduksi hidrogen menggunakan gliserol sebagai sacrificial agent. Penambahan 5 mM NaBF4 selama anodisasi menghasilan TNTAs termodifikasi yang mampu menghambat laju rekombinasi elektron-hole sehingga dapat meningkatkan produksi hidrogen sebesar 32 %. Penambahan dopan Pt sebagai electron trapper secara fotodeposisi pada TNTAs hasil anodisasi ultrasonik mampu menghasilkan hidrogen dari larutan gliserol sebesar lima kali lebih tinggi dibandingkan tanpa penambahan Pt.;

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ABSTRACTSynthesis of TiO2 nanotube array (TNTAs) has been performed by anodization process of Ti metal in the glycerol electrolyte solution containing NH4F followed by annealing to induce crystallization. Optimization some parameters was done including the variation of water content in the electrolyte solution, annealing atmosphere, addition of NaBF4, mode of mixing, as well as the variation of loading and the methods of Pt addition on the TNTAs. SEM/FESEM analysis showed that well ordered and vertically oriented of TNTAs with inner diameters of 49-205 nm, wall thicknesses from 11 to 33 nm and lengths from 530 to 2577 nm were synthesized. Annealing with H2/Ar is found to be an efficient method for introducing dopant C, N and B into the lattice of TNTAs via insitu anodization and, therefore, the reducing band gap in the range of 2,20?3,10 eV can be obtained. Most of TNTAs have anatase phase with the crystalline size from 18 to 33 nm. Water content of 25 v% and annealing under H2/Ar of as-synt TNTAs showed optimal condition in producing the highest photocurrent density. The photocatalytic hydrogen production test was performed with glycerol as a sacrificial agent. The addition of 5 mM NaBF4 during anodization resulted modified TNTAs that can reduce recombination of electron-hole and showed up 32 % improvement in hydrogen production. The photodeposition of Pt on the TNTAs that obtained from ultrasonic anodization can enhance hydrogen production five times higher compare to the one with unplatinized TNTAs.;Synthesis of TiO2 nanotube array (TNTAs) has been performed by anodization process of Ti metal in the glycerol electrolyte solution containing NH4F followed by annealing to induce crystallization. Optimization some parameters was done including the variation of water content in the electrolyte solution, annealing atmosphere, addition of NaBF4, mode of mixing, as well as the variation of loading and the methods of Pt addition on the TNTAs. SEM/FESEM analysis showed that well ordered and vertically oriented of TNTAs with inner diameters of 49-205 nm, wall thicknesses from 11 to 33 nm and lengths from 530 to 2577 nm were synthesized. Annealing with H2/Ar is found to be an efficient method for introducing dopant C, N and B into the lattice of TNTAs via insitu anodization and, therefore, the reducing band gap in the range of 2,20?3,10 eV can be obtained. Most of TNTAs have anatase phase with the crystalline size from 18 to 33 nm. Water content of 25 v% and annealing under H2/Ar of as-synt TNTAs showed optimal condition in producing the highest photocurrent density. The photocatalytic hydrogen production test was performed with glycerol as a sacrificial agent. The addition of 5 mM NaBF4 during anodization resulted modified TNTAs that can reduce recombination of electron-hole and showed up 32 % improvement in hydrogen production. The photodeposition of Pt on the TNTAs that obtained from ultrasonic anodization can enhance hydrogen production five times higher compare to the one with unplatinized TNTAs., Synthesis of TiO2 nanotube array (TNTAs) has been performed by anodization process of Ti metal in the glycerol electrolyte solution containing NH4F followed by annealing to induce crystallization. Optimization some parameters was done including the variation of water content in the electrolyte solution, annealing atmosphere, addition of NaBF4, mode of mixing, as well as the variation of loading and the methods of Pt addition on the TNTAs. SEM/FESEM analysis showed that well ordered and vertically oriented of TNTAs with inner diameters of 49-205 nm, wall thicknesses from 11 to 33 nm and lengths from 530 to 2577 nm were synthesized. Annealing with H2/Ar is found to be an efficient method for introducing dopant C, N and B into the lattice of TNTAs via insitu anodization and, therefore, the reducing band gap in the range of 2,20–3,10 eV can be obtained. Most of TNTAs have anatase phase with the crystalline size from 18 to 33 nm. Water content of 25 v% and annealing under H2/Ar of as-synt TNTAs showed optimal condition in producing the highest photocurrent density. The photocatalytic hydrogen production test was performed with glycerol as a sacrificial agent. The addition of 5 mM NaBF4 during anodization resulted modified TNTAs that can reduce recombination of electron-hole and showed up 32 % improvement in hydrogen production. The photodeposition of Pt on the TNTAs that obtained from ultrasonic anodization can enhance hydrogen production five times higher compare to the one with unplatinized TNTAs.]"

"Optimasi berbagai parameter untuk preparasi fotokatalis TiO2 nanotubes dan TiO2 nanowires telah dilakukan, diantaranya dengan kombinasi proses sonikasi dan hidrotermal yang dilanjutkan dengan post treatment (kalsinasi atau hydrothermal post treatment) dan penambahan dopan logam (Cu, Pt) dan dopan nonlogam (N). Karakterisasi terhadap hasil sintesis dilakukan dengan menggunakan analisa TEM, SEM, BET, DRS dan XRD. Dari hasil analisa TEM dan SEM menunjukkan proses kombinasi sonikasi hidrothermal menggunakan NaOH diperoleh morfologi nanotubes dengan diameter luar 40 nm, sedangkan dengan KOH diperoleh struktur nanowires dengan diameter luar sebesar 6 nm. Hasil pengujian XRD menunjukkan fasa kristal baik untuk nanotubes maupun nanowires yang dihasilkan adalah anatase. Uji aktifitas katalis untuk produksi hidrogen menggunakan sacrificial agent metanol.Dari hasil pengujian menunjukkan modifikasi TiO2 dari nanopartikel menjadi nanotubes dapat meningkatkan produksi hidrogen menjadi dua sampai tiga kalinya, sedangkan modifikasi ke bentuk nanowires menjadi dua kali dibandingkan TiO2 P25. Luas permukaan yang tinggi dan morfologi berongga pada nanotubes menyebabkan dispersi dopan Pt pada TiO2 nanotubes menjadi lebih baik sehingga mampu meningkatkan aktivitas fotokatalis dalam memproduksi hidrogen dari air hingga delapan belas kali lebih tinggi dibandingkan tanpa dopan platina. Pemberian dopan nitrogen pada fotokatalis TiO2 nanotube belum mampu menggeser panjang gelombang absorbansi secara signifikan sehingga dengan sumber foton sinar tampak belum dapat menghasilkan hidrogen yang cukup tinggi.

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Optimization of various parameters on the preparation of TiO2 nanotubes and TiO2 nanowires have been conducted, such as combination of sonication and hydrothermal process followed by post-treatment (calcination or hydrothermal post treatment) and the addition of dopant metal (Cu, Pt) and non-metallic dopants (N). The modified catalysts were characterized using TEM, SEM, BET, DRS and XRD. The TEM and SEM analysis showed that the sonication-hydrothermal treatment with aqueous NaOH and KOH lead to the formation of nanotubes and nanowires morphology with an average outer diameter of 40 nm and 6 nm, respectively. XRD analysis showed that the both morphologies have anatase crystalline phase. Performance of the prepared photocatalyst on hydrogen production was examined by using methanol as sacrificial agent.The results indicated the modification of TiO2 nanoparticles into nanotubes could increased in producing hydrogen two-three fold, while the modification to the nanowires into two fold comparing to that of unmodified TiO2 (P25). Larger surface area and porous morphology in nanotubes enhanced the Pt dopant dispersion on TiO2 NT to increase the photocatalyst activity. Furthermore, this increased the production of hydrogen by 18 fold compared to that of non doped TiO2 nanotubes. However introduction of N dopant to the TiO2 nanotubes was not able to shift the absorbtion band toward visible region. Therefore, the high yield of hydrogen production was not achieved by as prepared N doped TiO2, when visible light was used as the photon source."

"Penambahan nanopartikel kedalam fluida dasar dapat meningkatkan konduktivitas panas fluida dasar, sistem seperti ini disebut dengan nanofluida. Penelitian ini memiliki fokus untuk meningkatkan konduktivitas termal fluida dasar dan kestabilannya, pengujian dilakukan dengan portable thermal conductivity meter, particle size analyzer dan heat pipe. Nanofluida berbahan dasar TiO2 mengalami kenaikan konduktivitas termal terbesar pada penambahan 8%v TiO2, pH 8 dan penggunaan surfaktan CTAB sebesar 4 x cmc. Hasil pengujian menunjukkan nanofluida TiO2 meningkat konduktivitas termalnya 21% dari fluida dasarnya, dan nanofluida dengan penambahan surfaktan mampu menekan laju pengendapan terlihat dari ukuran partikel sebesar 196 nm dan intensitas 98,3% serta mampu menurunkan temperatur dievaporator heat pipe sebesar 36% dari fluida dasarnya.

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The addition of nanoparticles into the base fluid can increase the thermal conductivity of the base fluid, the system is called the nanofluida. This research has focused on improving the base fluid thermal conductivity and stability, testing was conducted with a portable thermal conductivity meter, particle size analyzer and the heat pipe. Nanofluida TiO2-based had the largest increase in thermal conductivity on the addition of 8% v TiO2, pH 8, and the use of CTAB surfactant by 4 x cmc. Test results showed nanofluida TiO2 increased thermal conductivity of the fluid is essentially 21%, and with the addition of surfactant nanofluida able to suppress the deposition rate can be seen from the particle size of 196 nm and the intensity of 98.3% and can lower the temperature in the evaporator heat pipe by 36% of the base fluid."

"ABSTRAKPengembangan deterjen cair ramah lingkungan berbasis titania, surfaktan nabati, dan zeolit 4A telah dilakukan. Prinsip kerja deterjen tersebut adalah pengangkatan kotoran oleh surfaktan nabati, kemudian dilanjutkan dengan fotodegradasi katalitik terhadap air buangan cucian oleh titania. Adapun penambahan zeolit 4A berperan untuk meningkatkan kinerja deterjen dalam air sadah (builder). Produk deterjen yang dihasilkan adalah berbentuk cair, sehingga ditambahkan carboxy methyl cellulose (CMC) sebagai pengental dan penstabil deterjen. Hasil penelitian menunjukkan bahwa deterjen non-konsentrat dengan rasio konsentrasi titania 0,1% dan surfaktan palmPAS 0,7% memiliki kemampuan mengangkat kotoran (methylene blue) sebesar 89%, dan kandungan surfaktan sisa pencucian menurun hingga 14%. Komposisi optimal deterjen konsentrat untuk pencucian dengan air non-sadah adalah 1% TiO2, 7% palmPAS, 2% CMC, dan 90% air dengan kemampuan mengangkat kotoran lebih dari 50% pada beban pencucian 2 kali deterjen non-konsentrat. Adapun komposisi optimal deterjen konsentrat untuk pencucian dengan air sadah maksimum 100 ppm Ca2+ adalah 1% TiO2, 7% palmPAS, 2% CMC, 2% zeolit, dan 88% air dengan kemampuan mengangkat kotoran sebesar 35% pada beban pencucian 2 kali deterjen non-konsentrat.

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ABSTRACTThis study has further investigated the development of eco-friendly liquid detergent using titania, natural-based surfactant, and 4A zeolite. The principle of the detergents is the dirt removal by natural-based surfactant, followed by catalytic photodegradation of the laundry?s waste water by titania. The addition of zeolite improves the detergent performance in hard water (builder). As the detergent format is liquid, carboxy methyl cellulose (CMC) was added as the thickener and the detergent?s stabilizer. Research showed that non concentrated detergent with 0,1%Titania-0,7%palmPAS surfactant ratio was able to remove 89% of dirt (methylene blue) together with 14% reduction of the residual surfactants. The optimize condition for concentrated detergent washed with non-hard water is 1% TiO2, 7% palmPAS, 2% CMC, and 90% water. It was able remove more than 50% of dirt for 2 times detergent non-concentrated washing. While the optimize condition for concentrated detergent washed with maximum 100 ppm Ca2+ hard water is 1% TiO2, 7% palmPAS, 2% CMC, 2% zeolite, and 88% water. It was able remove 35% of dirt for 2 times detergent non-concentrated washing."

"Penggabungan teknologi fotokatalisis dan surfaktan yang menggunakan titania dan coconut oil-based primary alkyl sulphate (cocoPAS) untuk mengangkat dan mendegradasi kotoran berupa methylene blue dari pakaian serta menghasilkan limbah dengan konsentrasi cocoPAS yang minimal telah diamati. Penelitian berupa pemvariasian perbandingan konsentrasi cocoPAS dan titania dan juga variasi pH dengan menggunakan jeruk nipis. Kinerja deterjen 0,1%cocoPAS-0,1%titania pada pH 3,6 (penambahan 2,5% jeruk nipis) adalah yang paling efektif, yaitu dapat mengangkat methylene blue dari pakaian 84,31 ppm dari 85,16 ppm atau degradasi methylen blue 99% (1,03 kali lebih baik daripada pH 6,4) dan konsentrasi cocoPAS yang tersisa 2,43 ppm dari 90,88 ppm atau degradasi cocoPAS 97,30% (1,05 kali lebih baik daripada pH 6,4) di bawah sinar UV selama 30 menit.

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Combination of photocatalytic technology and surfactant that used titania and coconut oil-based primary alkyl sulphate (cocoPAS) to remove and degradate methylene blue as dirt and resulting clean waste with minimal concentration of cocoPAS had been investigate. Research method vary cocoPAS and titania concentration and vary pH by vary concentration of lime. Performance of 0,1%cocoPAS-0,1%titania detergent in pH 3,6 (2,5% lime addition) is the most optimum that can remove 84,31 ppm methylene blue from clothes from 85,16 ppm at first or can degredate 99% metylene blue (1,03 times better than in pH 6,4) and concentraton of cocoPAS is remained 2,43 ppm from 90,88 ppm or can degredate 97,30% cocoPAS (1,05 times better than in pH 6,4) under 30 minutes illumination of UV light."

"Degradasi 2,4,6-Triklorofenol dalam limbah cair batubara dan produksi hidrogen secara simultan telah dilakukan dengan menggunakan berbagai katalis yaitu TiO2-P25, Titania Nanotube TiNT serta nanokomposit TiNT-Graphene dengan variasi loading graphene. Nanokomposit TiNT-Graphene berhasil disintesis dengan metode hidrotermal dan sonikasi serta dikarakterisasi dengan UV-Vis DRS, XRD, SEM/EDX/Mapping, BET dan FT-IR. Hasil karakterisasi UV-Vis DRS menunjukkan adanya penurunan band gap pada nanokomposit TiNT-Graphene. Hasil XRD menunjukkan fasa anatase pada TiNT dan nanokomposit dengan fraksi 100. SEM/EDX/Mapping menunjukkan adanya kandungan material TiNT dan graphene dalam morfologi dan komposisi nanokomposit dengan persebaran yang merata. Hasil karakterisasi BET menunjukkan bahwa nanokomposit memiliki luas permukaan yang tinggi sebesar 134,2 m2/g. Namun, tidak terbentuk ikatan Ti-O-C yang ditandai dari hasil karakterisasi FT-IR. Nanokomposit yang optimal diperoleh pada loading graphene 0,6 yang pada sistem simultan dapat mengonversi 2,4,6-Triklorofenol sebesar 89 12 lebih besar dari TiO2-P25 dan memproduksi hidrogen sebesar 986 ?mol 1,7 kali lebih banyak dari TiO2-P25 . Degradasi 2,4,6-Triklorofenol secara kinetika dapat dimodelkan dengan baik menggunakan persamaan reaksi orde satu untuk konsentrasi awal 2,4,6-Triklorofenol maksimal 10 ppm. Hasil uji juga menunjukkan penambahan 2,4,6-Triklorofenol sebesar 50 ppm dapat meningkatkan produksi hidrogen sebesar 626 ?mol 2,7 kali lebih besar.

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Degradation of 2,4,6 Trichlorophenol in coal liquid waste and hydrogen production simultaneously has been tested using catalysts such as TiO2 P25, Titania Nanotube TiNT and TiNT Graphene nanocomposite with graphene loading variation. TiNT Graphene nanocomposite were synthesized using hydrothermal and sonication method and were characterized using UV Vis DRS, XRD, SEM EDX Mapping, BET and FT IR. UV Vis DRS characterization showed a band gap reduction in TiNT Graphene nanocomposite. SEM EDX Mapping characterization result indicated the presence of TiNT and graphene material in nanocomposite rsquo s morphology and composition with equal distribution.

BET characterization result showed that the nanocomposite has a high surface area of 134,2 cm2 g. However, there was no Ti O C bond in nanocomposite that showed in FT IR characterization. Optimal graphene loading of 0.6 was obtained in the simultaneous system with 89 elimination of 2,4,6 Trichlorophenol 12 greater than TiO2 P25 and 986 mol of hydrogen production 1.7 times greater than TiO2 P25 . 2,4,6 Trichlorophenol degradation could be kinetically model by using first order reaction equation for 2,4,6 Trichlorofenol concentration of maximum 10 ppm. Test results also showed that 50 ppm addition of 2,4,6 Trichlorophenol would subsequently enhanced hydrogen production by 626 mol 2.7 times greater."

"ABSTRAKPendorong utama di balik pengembangan agen pembersih adalah untuk mencari baha aktif yaitu surfaktan yang relatif lebih ramah lingkungan. Sekitar 65-70 surfaktan anionik yang diproduksi komersial dihasilkan dari bahan baku tidak terbarukan, sedangkan sisanya diproduksi dari minyak konsumsi seperti minyak kelapa sawit dan kelapa yang nantinya dapat mengganggu kestabilan pangan. Penelitian ini memanfaatkan minyak non konsumsi dengan kadar asam lemak tinggi yaitu minyak jarak pagar untuk menghasilkan metil ester sulfonat MES sebagai salah satu bahan aktif agen pembersih. Penambahan nanopartikel titania dengan dopan tembaga dilakukan guna meningkatkan performa agen pembersih. Metil ester sulfonat disintesis melalui tiga tahap berurutan yaitu esterifikasi, transesterifikasi dan sulfonasi. Esterifikasi dilakukan dengan menggunakan katalis titania dengan bantuan sinar UV-A dengan variasi loading 0-10 dan perbandingan reaktan 1:12-1:48. Transesterifikasi dilakukan dengan menggunakan katalis NaOH 1 dengan minyak jarak pagar dan metanol 1:12. Sulfonasi dilakukan pada suhu 100oC selama 4,5 jam dengan mereaksikan NaHSO3 dan metil ester dengan variasi 1:1-1:3. Katalis disintesis dengan metode fotodeposisi dengan variasi dopan tembaga 1-3. Minyak jarak pagar dengan kandungan FFA 5,64 dapat turun menjadi 2,40 dengan loading katalis titania 7,5 dan rasio minyak jarak dan metanol 1:48. Metil ester sulfonat yang dihasilkan dari proses sulfonasi memiliki nilai tegangan permukaan 33,93-33,12 dyne/cm. Hasil uji bahan akif agen pembersih menunjukan bahwa agen pembersih optimum yaitu MES-20 dan 3 Cu/TiO2-0,1 memiliki nilai deterjensi 87 dengan kemampuan disinfeksi 90,30 selama 30 menit.

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ABSTRACTThe main urge behind the development of new surfactants as one of the active ingredients of cleaning agents is to look for surfactants that are relatively more environmentally friendly. Approximately 65 70 of commercially produced anionic surfactants are produced from non renewable feedstock, while the remainder is produced from edible oils such as palm oil and coconut which can disrupt food stability. This study utilizes non edible oil with high fatty acid content of jatropha oil to produce methyl ester sulfonate as one of the active ingredient of cleaning agent. The addition of titania nanoparticles with copper dopants is performed to improve the performance of cleaning agents. Methyl esters of sulfonates are synthesized through three successive stages of esterification, transesterification and sulphonation. Esterification was performed using titania catalyst with the aid of UV A light with loading variation of 0 10 and reactant ratio of 1 12 1 48. Transesterification was performed by using 1 NaOH catalyst with jatropha oil and methanol 1 12. Sulfonation is carried out at 100 C for 4.5 hours by reacting NaHSO3 and methyl ester with variation of 1 1 1 3. The Cu TiO2 nanoparticles was synthesized by photodeposition method with 1 3 copper dopant variation. Jatropha oil with FFA content of 5.64 can decrease to 2.40 with loading of 7.5 titania catalyst and ratio of jatropha oil and methanol 1 48. The methyl ester sulfonate produced from the sulfonation process has surface tension value of 33.93 33.12 dyne cm. The cleaning agent assay results showed that the optimum cleaning agent MES 20 and 3 Cu TiO2 0,1 had 87 detergency with 90.30 disinfect ability for 30 minutes. "

"Rekayasa karpet yang membersihkan sendiri, anti bakteri, dan bebas bau dilakukan dengan melapisi kitosan-titania nanokomposit pada karpet bulu sintetis. Nanokomposit disintesis dengan menambahkan kitosan ke TiO2 dengan menggunakan metode impregnasi basah. Nanokomposit kemudian ditandai dengan FTIR untuk menentukan ikatan yang terjadi, UV-Vis DRS untuk menentukan celah pita energi, dan SEM-EDX untuk menganalisis morfologi dan komposisi. Tes disinfeksi koloni E. coli dilakukan dengan menggunakan nanokomposit yang disintesis di bawah fotoreaktor akrilik untuk menganalisis kemampuan disinfektan. Setelah mendapatkan komposisi nanokomposit paling optimal berdasarkan tes, nanokomposit terbaik kemudian dilapisi di atas karpet. Serangkaian tes dilakukan pada karpet, termasuk uji pembersihan sendiri dengan mencelupkan karpet ke suspensi lumpur, uji fotodegradasi metilen biru, dan uji degradasi amonia. Hasil karakterisasi FTIR menunjukkan bahwa sejumlah ikatan terjadi antara kitosan dan TiO2, sementara UV-Vis DRS menunjukkan bahwa nanokomposit yang disintesis memiliki nilai celah pita 3,11 eV. Tes desinfeksi E-coli menunjukkan bahwa komposisi nanokomposit terbaik adalah konsentrasi kitosan 3wt%, sedangkan pembersihan sendiri, fotodegradasi metilen biru, dan uji degradasi amonia menunjukkan bahwa penambahan 0,67v% tetraetil ortosilikat adalah penambahan paling optimal dalam pelapisan nanokomposit pada permukaan karpet.

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A self-cleaning, anti bacterial, and odor free carpet engineering is conducted by coating chitosan-titania nanocomposite on a synthetic fur carpet. The nanocomposite is synthesized by adding chitosan to TiO2 by means of wet impregnation method. The nanocomposite is then characterized by FTIR to determine the bonds that occur, UV-Vis DRS to determine the energy bandgap, and SEM-EDX to analyze the morphology and composition.

An E. coli colony disincfection test is done using the synthesized nanocomposite under an acrylic photoreactor to analyze its disinfectant ability. After obtaning the most optimum nanocomposite composition based on the test, the best nanocomposite is then coated on the carpet. A series of tests is done to the carpet, including the self-cleaning test by dipping the carpet to mud suspension, methylene blue photodegradation test, and amonia degradation test.

The FTIR characterization result shows that a number of bonds occured between chitosan and TiO2, while UV-Vis DRS shows that the synthesized nanocomposite has a bandgap value of 3.11 eV. The E-coli disinfection test shows that the best nanocomposite composition is of the 3wt% chitosan concentration, while the self-cleaning, methylen blue photodegradation, and amonia degradation test shows that addition of 0.67v% tetraethyl orthosilicate is the most optimum addition in the nanocomposite coating on the carpet surface."

"Titania nanotubes (TiO2 NT) and Titania nanowires (TiO2 NW) were fabricated using TiO2 Degussa P25 (TiO2 P25) nanoparticle as precursors via a sonication-hydrothermal combination approach. The prepared catalysts were characterized by means of an X-ray diffraction (XRD), scanning electron microscope (SEM), transmission electron microscope (TEM), ultraviolet-visible diffuse reflectance spectroscopy (DRS) and the Brunauer-Emmett-Teller technique (BET). The photocatalytic activity of prepared catalysts was evaluated for photocatalytic H2 evolution from an aqueous methanol solution. The results showed that activity of the catalyst not only depends on the morphology of its catalysts, but also on the crystalinity and surface area. Hydrogen production of TiO2 NT was about three times higher than TiO2 P25 and TiO2 NW was two times higher than TiO2P25."

"Titania nanotube (TNT)-carbon nanotube (CNT) composite had been successfully synthesized using simple mixing under acidic conditions and ultrasonic treatment. The samples were further characterized via field emission scanning electron microscopy (FESEM), X–ray diffraction (XRD), diffuse re?ectance UV-vis spectroscopy, and Brunauer-Emmett-Teller (BET) analysis. The TNT–CNT composite’s ability to degrade phenol, a model of industrial waste, was tested. The effects of CNT composition and calcination temperature on the phenol degradation performance of TNT-CNT composite were investigated. The results show that the TNT-CNT composite exhibits higher photocatalytic activity than TNT or CNT alone. The crystallinity of the catalyst is not the only parameter affecting the photocatalytic activity. Rather, the specific surface area, bandgap, and morphology of the catalyst must also be considered."