International joint supervision of thesis UNIVERSIDADE ESTADUAL PAULISTA “JÚLIO DE MESQUITA FILHO” Programa de Pós-graduação em Ciência e Tecnologia de Materiais and UNIVERSITÉ DE PAU ET DES PAYS DE L’ADOUR Ecole Doctorale Sciences Exactes et leurs Applications Bruna Andressa Bregadiolli STUDY AND DEVELOPMENT OF MATERIALS FOR APPLICATIONS IN HYBRID SOLAR CELLS Brazilian supervisor: Prof. Dr. Carlos Frederico de Oliveira Graeff French supervisor: Dr. Roger. Hiorns 2016 UNIVERSIDADE ESTADUAL PAULISTA “JÚLIO DE MESQUITA FILHO” Programa de Pós-graduação em Ciência e Tecnologia de Materiais Bruna Andressa Bregadiolli ESTUDO E DESENVOLVIMENTO DE MATERIAIS PARA APLICAÇÕES EM CÉLULAS SOLARES HÍBRIDAS BAURU 2016 Bruna Andressa Bregadiolli Estudo e desenvolvimento de materiais para aplicações em células solares híbridas Tese apresentada como requisito à obtenção do título de Doutora à Universidade Estadual Paulista “Júlio de Mesquita Filho” - Programa de Pós-graduação em Ciência e Tecnologia de Materiais, sob a orientação do Prof. Dr. Carlos Frederico de Oliveira Graeff. BAURU 2016 Bregadiolli, Bruna Andressa. Estudo e desenvolvimento de materiais para aplicações em células solares híbridas / Bruna Andressa Bregadiolli, 2016 167 f. : il. Orientador: Carlos Frederico de Oliveira Graeff Tese (Doutorado)–Universidade Estadual Paulista. Faculdade de Ciências, Bauru, 2016 1. titanium dioxide. 2. fullerenes. 3. hybrid materials. I. Universidade Estadual Paulista. Faculdade de Ciências. II. Título. THESIS UNIVERSITE DE PAU ET DES PAYS DE L’ADOUR – UNIVERSIDADE ESTADUAL PAULISTA - BAURU Defended on September 20th, 2016 by Bruna Andressa BREGADIOLLI Submitted in fulfilment of the requirements for the degree of Doctor of Philosophy in Chemistry at UNIVERSITÉ DE PAU ET DES PAYS DE L’ADOUR and UNIVERSDADE ESTADUAL PAULISTA “JULIO DE MESQUITA FILHO” “Study and development of materials for applications in hybrid solar cells” Etude et développement de matériaux pour des applications en cellules solaires hybrides Advisors: Dr. Roger C. HIORNS, and Prof. Carlos Frederico de Oliveira GRAEFF JURY Prof Alejandra Hortencia Miranda GONZÁLEZ Rapporteur Prof Alexandre Fontes FONSECA Rapporteur Prof André Sarto POLO Examinateur Prof Francisco Eduardo Gontijo GUIMARÃES Examinateur Fullerene Derivatives Abstract Main-chain fullerene polymers were prepared using a newly discovered dipolar azido cycloaddition polymerisation (DACAP). This first demonstration employs sterically cumbersome bis(azido-alkyl) comonomers to yield oligo- and poly(aziridinofullerene)s. The products were extensively characterized and devices were made in order to evaluate its behavior in organic photovoltaic devices. This new methodology opens a route to numerous main-chain fullerene polymers. Publications Ramanitra, H.H, Santos Silva, H., Bregadiolli B. A., Khoukh. A., Combe C.M.S., Dowland, S.A., Bégué, D., Carlos F. O. Graeff, C.F.O., Dagron-Lartigau, C, Distler, A., Morse, G., Hiorns, R.C. Synthesis of Main-Chain Poly(fullerene)s from a Sterically Controlled Azomethine Ylide Cycloaddition Polymerization Macromolecules, 2016, 49 (5), pp 1681–1691 DOI: 10.1021/acs.macromol.5b02793 Ramanitra, H.H., Dowland, S.A., Bregadiolli, B.A., Salvador, M. Santos Silva,H., Bégué, D., Graeff, C.F.O., Peisert, H., Chassé, T. Rajoelson, S., Osvet, A., Brabec, C.J., Egelhaaf, H.J. Morse, G., Distler, A., Hiorns, R.C. Increased Thermal Stabilization of Polymer Photovoltaic Cells with Oligomeric PCBM. Journal of Materials Chemistry C, Accepted Manuscript DOI: 10.1039/C6TC03290G Part of the results will be published in: Bregadiolli, B. A., Corcoles, L., Kang, L., Ramanitra, H.H., Combe, C.M.S., Ferreira, R.M., Santos Silva, H., Bégué, D., Lavada, F.C., Dagron-Lartigau, C., Luscombe, C.K., Olivati, C., Graeff, C.F.O., Hiorns, R.C. Syntheses of Main-chain Poly(aziridinofullerene)s and their use in Organic Photovoltaic Devices. ii Santos-Silva, H., Ramanitra, H.H.; Bregadiolli, B.A.; Bégué, D.; Graeff, C.F.O; Dagron- Lartigau, C.; Peisert, H.; Chasse, T.; Hiorns, R.C. Regioregular Oligo- and Poly(fullerene)s for Photovoltaic Applications: Modelled Electronic Behaviours and Synthesis The research leading to fullerene results has received funding from the European Union Seventh Framework Program (FP7/2011) under grant agreement no. 290022, the Region Aquitaine under grant FULLINC 2012. LC acknowledges financial support from the Ministry of Economy and Competitiveness of Spain (FPI grant MAT2012-37776). LNNano (CNPEM - Brazil) is thanked for providing gold IDE. LK and CKL acknowledge support from the National Science Foundation (DMR 1407815 and CHE 1506209) as well as the State of Washington through the University of Washington Clean Energy Institute Exploratory Fellowship Program. Dr. M. Pédeutour is warmly thanked for administrative support. iii Inorganic Oxide Abstract TiO₂ derivatives with distinct morphologies have been successfully obtained by microwave assisted hydrothermal synthesis in acidic and alkaline medium using mild conditions. Titanium tetraisopropoxide (TTIP) was used as precursor in different environmental conditions with low temperatures and short synthesis time. XRD, SEM, EDX, TEM and BET were used to characterize the microstructural properties of the oxides. In the acidic synthesis the reaction time and temperature are not accompanied by significant changes in the structure of the material. However, in the basic conditions, the concentration of Na+ ions strongly influences the particle morphology and growth. The morphology of the nanoparticles shows irregular spheres in acidic conditions, while in alkaline medium, needle-like structures are formed as well as aggregated nanotube-like structures synthesized in only 30 min. Besides the difference in the morphology and structure, in both systems, high surface area was obtained. Publications González, A.H.M., Machado Junior, C., Bregadiolli, B.A., de Farias, N.C., D'Alpino, P.H.P; Graeff, C.F.O. New Materials for Energy and Biomedical Applications. Ceramic Engineering and Science Proceedings. 1ed.: John Wiley & Sons, Inc., 2013, v. , p. 1-13. Da Silva, B.H.S.T., Bregadiolli, B.A., Graeff, C.F.O., Silva-Filho, L.C. NbCl5-Promoted synthesis of novel fluorescein dye derivatives: Spectroscopic and Spectrometric characterization and its application in dye-sensitized solar cells. Accepted Manuscript DOI: 10.1002/cplu.201600530 Part of the results will be published in: Bregadiolli, B. A., Fernandes, S.L., Graeff, C. F. O., Easy and fast preparation of TiO2 nanotubes and nanoparticles using different environmental conditions by microwave assisted hydrothermal technique. iv Hybrid Nanoparticles Abstract This work consists in the synthesis and characterization of TiO2 and Nb2O5 nanoparticles grafted P3HT. Hybrid nanoparticles, core@shell of metallic oxides and P3HT were synthesized. The optical and structural properties of hybrid nanoparticles (TiO2@P3HT and Nb2O5@P3HT) were investigated. The physical and morphological properties have been characterized using TEM, where a homogeneous P3HT shell is observed onto the particles. Photoluminescence measurements reveal a blue shift and quenching of intensity in the emission spectrum of the grafted particles. Those phenomena would be explained by the annihilation of the excitons by polarons at the polymer/oxide interface. Part of the results will be published in: Bregadiolli, B. A., Awada, H, Nunes Neto, O., Dagron-Lartigau, C., Bilon, L., Bousquet, A., Hiorns R.C., Batagin-Neto, A., Guimarães, F. E. G., Graeff, C. F .O, Exciton-polaron annihilation in hybrid systems studied by FLIM-confocal microscopy. – in preparation CBMM is thanked for provide NbCl5. . v This work is dedicated to my parents Amadeu and Maria Helena vi Acknowledgments I would like to give my sincere acknowledgment to: My supervisors: Prof. Dr. Carlos F. O. Graeff for all the support, fruitful discussions and opportunities during all this work and Dr. Roger C. Hiorns for the support and patience for the thousand Skype meetings and discussions to improve this thesis. My friends from the LNMD and from EPCP group (IPREM – UPPA) - the ones who are there and the ones who already left - for the contributions in this work. In special Sílvia Fernandes, João Vitor Paulin, Oswaldo Nunes Neto, Erika Bronze-Uhle, Augusto Batagin Neto, Marina Piacenti and Gustavo Albano. Dr Alejandra Hortencia Miranda Gonzalez and Dr Luiz Carlos da Silva Filho for all the help since the beginning of the project and the contributions in the Exame Geral de Qualificação. Prof Francisco Carlos Lavarda and Ms Rodrigo Marques Ferreira for the simulation results and Dr Christine Luscombe’s group for the solar cells preparation and measurements. Dr Antoine Bousquet and Dr Hussein Awada (IPREM – EPCP) for the contributions to synthesize the hybrid nanoparticles. Professor Francisco Eduardo Gontijo Guimarães – IFSC/USP for the FLIM measurements, Dr Luiz Alberto Colnago - EMBRAPA - São Carlos for the relaxometry measurements and Professor Clarissa Olivatti (DFQB - Unesp – Presidente Prudente) for the conductivity measurements. My first advisor Professor Marcelo Nalin who presented me the research world and had guided my first steps. My family, in special my nephew Davi for the happiness moments and my partner Glauco for the patient and love. FAPESP (2011/02205-5) and CAPES (BEX 11216-12-3) for the scholarship. vii BREGADIOLLI, B. A., Study and development of materials for applications in hybrid solar cells. 2016. 167f. Thesis (PhD in Science and Technology of Materials) - UNESP and (PhD in Polymer Chemistry) - UPPA, Bauru, 2016. ABSTRACT This work aims to study and develop materials for applications in third generation solar cells. The synthesized materials are fullerene derivatives, titanium oxide, and hybrid (polymer@oxide) nanoparticles. The fullerene derivatives, n-type polymers, were designed to contain C60 in the main chain. Different products were obtained, varying the comonomer alkyl length using a new polymerization route discovery in this work. The photovoltaic devices were prepared using the bulk heterojunction configuration and the highest efficiency reached was 1.84 %, representing a very promising performance for a novel material. The titanium dioxide nanoparticles were synthesized using microwave assisted hydrothermal technique in different reaction condition, such as pH, temperature and time, in order to obtain well defined nano-sized morphologies, high yields and high surface areas. Also, it was investigated the influence of the Na+ ions on the crystalline growth and morphologies of the oxides, where nanoparticles, needles and nanotube-like structures were obtained. The hybrid nanoparticles were synthesized using the prepared oxides and a P3HT functionalized in order to bond covalently with the oxides. The nanoparticles were optically characterized and concluded to be possible to use for studies of charge transfer in hybrid systems. Keywords: TiO2, microwave assisted hydrothermal, fullerene derivatives, Poly(azafulleroid)s, grafted nanoparticles. viii BREGADIOLLI, B. A., Estudo e desenvolvimento de materiais para aplicações em células solares híbridas. 2016. 167f. Tese (Doutorado em Ciência e Tecnologia de Materiais) – UNESP e (Doutora em Química de Polímeros) – UPPA, Bauru, 2016. RESUMO Este trabalho tem como objetivo estudar e desenvolver materiais para aplicações em células solares de terceira geração. Os materiais sintetizados são derivados de fulereno, óxido de titânio e nanopartículas híbrido (óxido@polímero). Os polímeros derivados de fulereno, de tipo n, foram planejados para conter C60 na cadeia principal. Três produtos diferentes foram obtidos, variando o comprimento da cadeia alquílica do co-monômero utilizando uma nova rota de polimerização. Os dispositivos fotovoltaicos foram preparados utilizando a configuração de heterojunção no volume e a maior eficiência alcançada foi de 1,84 %, o que representa um desempenho promissor para um novo material. As nanopartículas de dióxido de titânio foram sintetizadas usando a técnica hidrotermal assistida por micro-ondas em diferentes condições reacionais, tais como pH, temperatura e tempo, de modo a obter a morfologia nano dimensionada bem definida, rendimentos elevados e alta área superficial. Além disso, estudou- se a influência dos íons Na+ no crescimento cristalino dos óxidos e em sua morfologia, onde foram obtidas nanopartículas, estruturas tipo agulas e estruturas tipo nanotubos. As nanopartículas híbridas foram sintetizadas utilizando os óxidos sintetizados e um polímero, P3HT, funcionalizado de modo a ligar-se covalentemente aos óxidos. As nanopartículas foram opticamente caracterizadas e concluímos que estas podem ser utilizadas para estudar a transferência de carga em sistemas híbridos. Palavras chaves: TiO2, hidrotermal assistido por micro-ondas, derivados de fulerenos, poli(azafuleroide)s, nanopartículas enxertadas. ix BREGADIOLLI, B. A., Etude et développement de matériaux pour des applications dans les cellules solaires hybrides. 2016. 167f. Thèse (Docteur en Science et Technologie des Materiaux) – UNESP et (Doctorat en Chimie des Polymères)- UPPA, Bauru, 2016. RÉSUME Ce travail vise à étudier et à développer des matériaux pour des applications dans les cellules solaires de troisième génération. Les matériaux synthétisés sont des dérivés de fullerène, l'oxyde de titane et des nanoparticules hybride (polymère@oxyde). Les polymères dérivés de fullerène, de type n, ont été conçues pour contenir C60 dans la chaîne principale. Trois produits différents ont été obtenus, en faisant varier la longueur du comonomère en utilisant une nouvelle voie de polymérisation. Les dispositifs photovoltaïques ont été préparés en utilisant la configuration à hétérojonction en vrac et le rendement le plus élevé atteint était de 1,84 %, ce qui représente une performance prometteuses pour un nouveau matériau. Les nanoparticules de dioxyde de titane ont été synthétisés en utilisant la technique hydrothermique assistée par micro-ondes dans différentes conditions de réaction, tels que le pH, la température et le temps, afin d'obtenir ainsi défini nanométrique morphologie, avec des rendements élevés et une grande surface spécifique. En outre, on a étudié l'influence des ions Na+ sur la croissance cristalline des oxydes et morphologies des oxydes, où c'etait obtenu des nanoparticules, des aiguilles et des structures ressemblant des nanotubes. Les nanoparticules hybrides ont été synthétisés en utilisant l'oxyde synthétisé et un polymére, P3HT, fonctionnalisés afin de lier de manière covalente avec les oxydes. Les nanoparticules sont optiquement caractérisés et ont conclu à être possible d'utiliser pour les études de transfert de charge dans les systèmes hybrides. Mots-Clés: TiO2, hydrothermal assistée par micro-ondes, les dérivés de fullerène, poly(azafuleroide)s, greffé nanoparticules. x LIST OF FIGURES Figure 1: Best research-cells efficiencies chart. ....................................................................... 23 Figure 2: The electron injection process and energy levels diagram of a DSSC. .................... 25 Figure 3: TiO2 crystalline structure for a) rutile, b) anatase and c) brookite. Oxygen atoms represented in red and titanium in white. ................................................................................. 27 Figure 4: Illustration of bulk heterojunction solar cell. ............................................................ 35 Figure 5: Contour plot showing the calculated energy-conversion efficiency (contour lines and gray scale) versus the bandgap and the LUMO level of the donor polymer. Straight lines starting at 2.7 eV and 1.8 eV indicate HOMO levels of –5.7 eV and –4.8 eV, respectively. A schematic energy diagram of a donor PCBM system with the bandgap energy (Eg) and the energy difference (ΔE) are also shown................................................................................................. 37 Figure 6: Illustration of C60 and C70 structures. ........................................................................ 38 Figure 7: Representation of C60-containing polymers. ............................................................. 39 Figure 8: Aziridinofullerenes isomeric products. ..................................................................... 42 Figure 9: Poly(aziridinofullerene) synthesis. ............................................................................ 55 Figure 10: SEC curves of PAF1, PAF2 and PAF3 (THF, 30 ˚C, 350 nm). ............................. 78 Figure 11: FTIR data for PAF1, PAF2 and PAF3. ................................................................... 79 Figure 12: Photographs of solutions of C60, PAF, PAF2 and PAF3, running from left to right, in 1,2-DCB, THF, chloroform, toluene and DMF. ................................................................... 81 Figure 13: 1H NMR (400.6 MHz, 1,4-dichlorobenzene-d4, 85 °C) of PAF1. ......................... 83 Figure 14: 1H NMR (400 MHz, C6D6, room temperature) of PAF2. Note peaks due to impurities at 2.9 and 3.8 ppm, most likely arising from methanol. ........................................................... 83 Figure 15: 1H NMR (400 MHz, C6D6, room temperature) of PAF3. Note peaks due to impurities at 2.7, 2.3, 2.1 and 1.9 ppm, from solvents............................................................................... 84 Figure 16:Thermogravimetric study of: (a) PAF1; (b) PAF2; and (c) PAF3. .......................... 85 Figure 17: DSC thermogram of PAF2. ..................................................................................... 86 Figure 18: Representation of HOMO and LUMO frontier orbitals calculated at the DFT/B3LYP/6-31G(d) theoretical level. .................................................................................. 87 Figure 19: Cyclicvoltammetry of (a) PCBM; (b) PAF1; (c) PAF2 and (d) PAF3. The oxidation potential (Eox) is pointed by the blue arrow and the reduction potential (Ered) is pointed by the red arrow. .................................................................................................................................. 88 Figure 20:Tauc's plot used to calculate the optical band gap. .................................................. 89 xi Figure 21: UV-Visible absorption spectra of solutions of C60, PAF1, PAF2 and PAF3 in chloroform. ............................................................................................................................... 90 Figure 22: Transmittance spectra for PAFs thin films. ............................................................ 91 Figure 23: AFM for a) PAF1 and b) PAF2 films. .................................................................... 92 Figure 24: Statistical studies (at least 10 devices) of the photovoltaic devices made using PAFs or PCBM with P3HT. ............................................................................................................... 93 Figure 25: J-V curves of the photovoltaic devices made using PCBM, PAF1 and PAF2. ...... 94 Figure 26: Statistical studies of the main parameters (16 devices for PAFs and 56 for PCBM). .................................................................................................................................................. 94 Figure 27: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(octyloxy)benzene (2). Note peak at 1.56 and 3.43 ppm respectively due to water and methanol impurities. ............. 97 Figure 28: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(dodecyloxy)benzene (3). Note peak at 3.45 ppm due to methanol impurity .................................................................... 98 Figure 29: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(hexadecyloxy)benzene (4).............................................................................................................................................. 99 Figure 30: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(bromomethyl)-2,5- bis(octyloxy)benzene (5). Note peaks at 1.8 and 3.5 ppm, respectively, due to water and methanol impurities. ............................................................................................................... 100 Figure 31: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(bromomethyl)-2,5- bis(dodecyloxy)benzene (6). Note peaks at 0.1, 1.6 and 3.4 ppm, respectively, due to grease, water and methanol impurities. .............................................................................................. 101 Figure 32: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(bromomethyl)-2,5- bis(hexadecyloxy)benzene (7). Note peaks at 0.1 and 1.6, respectively, due to grease and water impurities. ............................................................................................................................... 102 Figure 33: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(azidomethyl)-2,5- bis(octyloxy)benzene (8). Note peaks at 1.57 and 3.51 ppm, respectively, due to water and methanol impurities, and at 0.1 ppm due to grease. ............................................................... 103 Figure 34: 13C NMR (100.16 MHz, CDCl3, room temperature) of 1,4-bis(azidomethyl)-2,5- bis(octyloxy)benzene (8). ....................................................................................................... 104 Figure 35: 1H NMR (400 MHz, CDCl3, room temperature) of 1,4-bis(azidomethyl)-2,5- bis(dodecyloxy)benzene (9). Note peak at 2.6 ppm due to dimethyl sulfoxide. .................... 105 Figure 36: 13C NMR (100.16 MHz, CDCl3, room temperature) of 1,4-bis(azidomethyl)-2,5- bis(dodecyloxy)benzene (9). .................................................................................................. 106 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786311 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786311 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786313 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786317 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786317 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786319 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786319 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786323 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786323 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786323 xii Figure 37: 1H NMR (400 MHz, CDCl3, room temperature) of 11,4-bis(azidomethyl)-2,5- bis(hexadecyloxy)benzene (10) Note plenty of impurities peaks. ......................................... 107 Figure 38: XRD Patterns for all the samples synthesized in acidic media in a) HM150-XX, b) HM130-XX and c) HM110-XX-10. ....................................................................................... 111 Figure 39: SEM images of samples prepared at a) HM110-15 b) HM150-60 c) HM130-15, d) HM130-30, e) HM150-2 and f) HM150-60 ........................................................................... 113 Figure 40: TEM images obtained with different magnifications (a) and (b), Electron Diffraction Pattern (c) and BET adsorption curve (d) for sample HM150-30 .......................................... 114 Figure 41: XRD patterns for the samples a) HMB110-XX-1, b) HMB130-XX-1 and c) HMB150-XX-1. ...................................................................................................................... 116 Figure 42: SEM image for a) HMB110-30-1, b) HMB110-30-1 (higher magnification), c) HMB130-30-1 (lower magnification), d) HMB130-30-1 (higher magnification 1), e) HMB130- 30-1 (higher magnification 2), f) HMB150-30-1, g) HMB110-5-1 and h) HMB150-15-1. . 118 Figure 43: XRD patterns for the samples a) HMB110-XX-10, HMB130-XX-10 and HMB150- XX-10. .................................................................................................................................... 120 Figure 44: XRD patterns for the samples HMB150-30-10 and HMB150-30-0.1. ................. 122 Figure 45: SEM images for the samples a) HMB150-30-0.1, b) HMB150-30-10 and c) HMB150-30-10 BET adsorption curve. ................................................................................. 122 Figure 46: SEM images of the samples obtained in alkaline media in a) HMB150-60-10, b) HMB150-15-1, c) HMB150-30-1, d) HMB150-60-1, e) HMB150-30-0.1 e f) HMB150-30-10. ................................................................................................................................................ 124 Figure 47: a) TEM image and b) EDX for the sample HMB150-30-10 as synthetised and c) EDX for the sample HMB150-30-10 after HCl washing. ...................................................... 125 Figure 48: XRD pattern for a) TiO2 and b)Nb2O5. ................................................................. 133 Figure 49: TEM images for the grafted particles a) and b) Nb2O5@P3HT and c) and d) TiO2@P3HT. .......................................................................................................................... 134 Figure 50: PL spectra for a) P3HT, TiO2@P3HT and TiO2 and b) P3HT, Nb2O5@P3HT and Nb2O5 using λEx = 455 nm and concentration of 1 x10-5 M. ................................................... 136 Figure 51: Confocal image for the samples in a) TiO2, b) P3HT film, c) TiO2@P3HT and d) Nb2O5@P3HT, using λEx = 455 nm and concentration of 1 x10-5 M. ..................................... 137 Figure 52: Confocal images of the prepared samples in a) P3HT film, b) P3HT in chloroform, c) dried TiO2@P3HT, d) another region of the sample TiO2@P3HT, e) dried Nb2O5@P3HT file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786327 file:///C:/Users/bruna/Desktop/these%20Bruna%20final%20revisada.docx%23_Toc465786327 xiii and f) comparison with intensities for non-illuminated (red) and after illumination for Nb2O5@P3HT......................................................................................................................... 138 Figure 53: a) the P3HT polymer solid-state, b) TiO2@P3HT and c) Nb2O5@P3HT. It is noteworthy that in these images the colors no longer correspond to their issue, but it is equivalent to their lifetime, where blue represents longer and red lower lifetimes using two photons excitation. .................................................................................................................. 140 Figure 54: Illustration of the formation of electric dipoles in the hybrid particles. ............... 142 Figure 55: T2 values plotted as a function of illumination time for the sample TiO2@P3HT: the left side are measurements in the dark after lighting period and right side inside the ellipse measurements made during the illumination. ......................................................................... 143 xiv LIST OF TABLES Table 1: Brief summary of TiO2 derivatives synthesized by hydrothermal and microwave assisted hydrothermal in acidic media. ..................................................................................... 30 Table 2: Brief summary of TiO2 derivatives synthesized by hydrothermal and microwave assisted hydrothermal in alkaline media. .................................................................................. 31 Table 3: Molecular weight distributions as indicated by SEC against polystyrene standards. Note that molecular weights should be multiplied from between 4 and 10 gain a better indication of the actual value. where Mn = the number average molecular weight, Mw = the weight average molecular weight and Ð = Polydispersity index. ........................................................ 79 Table 4: Electronic data for PCBM and the PAFs.................................................................... 89 Table 5: Comparison of absorption peaks of PAFs and C60 in chloroform. ............................. 90 Table 6: Summary of the results shown in Figure 25, where SD denotes standard deviation. 95 Table 7: Morphology, surface area and yield of the synthesized samples. They are named as: a prefix (HM for acidic media or HMB for alkaline media), followed by the temperature, time of treatment and concentration of NaOH for the alkaline media. ............................................... 109 Table 8: Calculated crystallite size. ........................................................................................ 112 xv LIST OF SCHEMES Scheme 1: Synthesis of 1,4-bis(octyloxy)benzene (2) from hydroquinone (1). ....................... 47 Scheme 2: Synthesis of 1,4-bis(dodecyloxy)benzene (3) from hydroquinone (1). .................. 48 Scheme 3: Synthesis of 1,4-bis(hexadecyloxy)benzene (4) from hydroquinone (1). .............. 49 Scheme 4: Synthesis of 1,4-bis(bromomethyl)-2,5-bis(octyloxy)benzene (5). ........................ 49 Scheme 5: Synthesis of 1,4-bis(bromomethyl)-2,5-bis(dodecyloxy)benzene (6). ................... 50 Scheme 6: Synthesis of 1,4-bis(bromomethyl)-2,5-bis(hexadecyloxy)benzene (7). ................ 51 Scheme 7: Synthesis of 1,4-bis(azidomethyl)-2,5-bis(octyloxy)benzene (8)........................... 52 Scheme 8: Synthesis of 1,4-bis(azidomethyl)-2,5-bis(dodecyloxy)benzene (9). ..................... 53 Scheme 9: Synthesis of 1,4-bis(azidomethyl)-2,5-bis(hexadecyloxy)benzene (9). ................. 54 Scheme 10: Synthesis of functionalized P3HT and graft reaction. .......................................... 59 Scheme 11: Syntheses of the comonomers and PAFs: a) 1-bromooctane, K2CO3, 1, acetonitrile, 54 %; b) 1-bromododecane, K2CO3, 1, acetonitrile, 44 %, c) 1-bromohexadecane, K2CO3, 1, acetonitrile, 32 %;d) 2, PFA, HBr, acetic acid, 48%, e) 3, PFA, HBr, acetic acid, 64 %, f) 4, PFA, HBr, acetic acid, 48 %, g) 5, NaN3, DMSO, 67 %, h) 6, NaN3, DMSO, 68 %, i) , NaN3, DMSO, 52 %, j) C60, 8, DCB, 56 %, k) C60, 9, DCB, 68 % l) C60, 10, DCB, 63 %.... 76 Scheme 12: TiO2 formation mechanism. ................................................................................ 126 Scheme 13: Illustration of the grafting reaction ..................................................................... 134 xvi ABBREVIATIONS ATRAP Atom-transfer radical-polymerization BET N2 adsorption at 77 K – Brunauer Emmett Teller CV cyclic voltammetry DEA diethanolamine DMF dimethylformamide DSSC dye sensitized solar cell DTPA diethylenetriaminepentaacetic acid EA ethanolamine EDA ethylenediamine EDTA ethylenediaminetetraacetic acid EDX energy dispersive X-ray spectroscopy EPA exciton-polaron annihilation FF fill factor FLIM fluorescence-lifetime imaging microscopy FTIR Fourier transformed-infrared spectroscopy FWHM full width at half maximum GPC gel permeation chromatography HOMO highest occupied molecular orbital IDA iminodiacetic acid LUMO lowest unoccupied molecular orbital Mn number average molecular weight Mw weight average molecular weight N3 dye (cis-Bis(isothiocyanato) bis(2,2’-bipyridyl-4,4’-dicarboxylato ruthenium(II)) N719 dye (di-tetrabutylammonium cis-bis(isothiocyanato)bis(2,2’-bipyridyl-4,4’- dicarboxylato)ruthenium(II)) NMR nuclear magnetic resonance spectroscopy o-DCB ortho-dichlorobenzene OPV organic photovoltaic xvii P3HT Poly(3-hexylthiophene-2,5-diyl) PAF poly(aziridinofulerene) PCBM [6,6]-phenyl-C61-butyric acid methyl ester PCE power conversion efficiency PEDOT poly(3,4-ethylenedioxythiophene) PL photoluminescence PPV poly(p-phenylene vinylene) PSS polystyrene sulfonate PVA polyvinyl alcohol RT room temperature SACAP sterically controlled azomethine ylide cycloaddition polymerization SC solar cell SEC size exclusion chromatography SEM scanning electron microscopy TBA tetraethylammonium TCO transparent conducting oxide TEA tetraethylammonium TEAOH tetraethylammonium hydroxide TEM transmission electron microscopy TG thermogravimetric analysis THF tetrahydrofuran TTIP titanium (IV) isopropoxide UV-Vis Spectroscopy in the UV-Visible region XRD X-ray diffratometry Z907 dye (bis(isothiocyanato)(4,4'-dicarboxylato-2,2'-bipyridine)(4,4'-dinonyl-2,2'- bipyridine)ruthenium(II)) xviii SUMMARY FOREWORD ............................................................................................................................ xx CHAPTER 1 ............................................................................................................................. 21 INTRODUCTION: MATERIALS FOR THIRD GENERATION PHOTOVOLTAICS ........ 21 1.1 Dye Sensitized Solar Cells (DSSC) .......................................................................... 24 1.2 TiO2 .......................................................................................................................... 26 1.3 Hydrothermal and microwave assisted hydrothermal techniques ............................ 33 1.4 Bulk heterojunction solar cells ................................................................................. 34 1.5 Fullerenes.................................................................................................................. 38 1.6 Hybrid particles ........................................................................................................ 42 CHAPTER 2 ............................................................................................................................. 46 METHODOLOGY AND CHARACTERIZATION TECHNIQUES ...................................... 46 2.1 Methodology ............................................................................................................. 47 2.1.1 Polyfullerenes ...................................................................................................... 47 2.1.2 Inorganic oxide ................................................................................................... 57 2.1.3 Hybrid nanoparticles ............................................................................................ 58 2.2 Characterization Techniques .................................................................................... 60 2.2.1 X ray diffratometry (XRD) .................................................................................. 60 2.2.2 Scanning electron microscopy (SEM) ................................................................. 61 2.2.3 Energy Dispersive X-ray Spectroscopy (EDX) .................................................. 62 2.2.4 Transmission electron microscopy (TEM) ......................................................... 62 2.2.5 N2 adsorption at 77 K – Brunauer Emmett Teller (BET) ................................... 63 2.2.6 Size-exclusion chromatography (SEC) .............................................................. 64 2.2.7 Nuclear magnetic resonance spectroscopy (NMR) ............................................ 64 2.2.8 Fourier Transformed-Infrared Spectroscopy (FTIR) .......................................... 65 2.2.9 Thermogravimetry (TG) ..................................................................................... 65 2.2.10 Differential scanning calorimetry (DSC) ........................................................... 66 2.2.11 UV-Vis spectroscopy .......................................................................................... 67 2.2.12 Optical band gap ................................................................................................. 68 xix 2.2.13 Atomic Force Microscopy (AFM) ...................................................................... 68 2.2.14 Cyclic Voltammetry (CV) .................................................................................. 69 2.2.15 Energy levels calculation .................................................................................... 69 2.2.16 Photoluminescence spectroscopy (PL) ............................................................... 70 2.2.17 Fluorescence lifetime imaging microscopy (FLIM) ........................................... 71 2.2.18 Electrical characterization .................................................................................. 71 CHAPTER 3 ............................................................................................................................. 73 SYNTHESIS OF FULLERENE DERIVATIVES ................................................................... 73 Conclusion .................................................................................................................... 96 NMR SPECTRA ............................................................................................................... 97 CHAPTER 4 ........................................................................................................................... 108 INORGANIC OXIDE SYNTHESIS ...................................................................................... 108 Acidic media ............................................................................................................... 110 Alkaline media ............................................................................................................ 116 Conclusion .................................................................................................................. 130 CHAPTER 5 ........................................................................................................................... 131 HYBRID PARTICLES........................................................................................................... 131 Conclusions ................................................................................................................. 144 CONCLUSION ...................................................................................................................... 145 REFERENCES ....................................................................................................................... 146 xx FOREWORD This thesis is about the results obtained from October 2011 to September 2016 in a Doutorado Direto project in a co-tutelle thesis agreement between Universidade Estadual Paulista “Júlio de Mesquita Filho” (UNESP) and Université de Pau et des Pays de l’Adour (UPPA). The research was conducted most of the time at Laboratório de Novos Materiais e Dispositivos (LNMD) of Departamento de Física – Faculdade de Ciências at UNESP (Bauru - SP, Brazil) under supervision of Professor Carlos Frederico de Oliveira Graeff. The period in Brazil was supported by FAPESP (2011/02205-3). A research period at Equipe Physique et Chimie des Polymères (EPCP) of Institut des Sciences Analytiques et de Physico-chimie pour l'Environnement et les Matériaux (IPREM) in UPPA (Pau, France), under supervision of Dr. Roger Hiorns from January to December 2013 was funded by the Project CAPES/COFECUB (BEX 11216-12-3). Considering the contribution of the period abroad in this PhD research, the agreement for the international joint supervision of thesis between the Brazilian and French universities was approved. The thesis is divided into 5 chapters that are briefly described below: A brief description of the issue addressed in this thesis, such as the main materials use in third generation photovoltaics, is presented in Chapter 1. Chapter 2 describes the characterization techniques and its conditions used in this work. Chapter 3 presents a structural and opto-electrical characterization and application as electron acceptor in OPV of the fullerene derivatives synthesized. Chapter 4 describes the work on TiO2. Lastly in Chapter 5 is demonstrated the hybrid nanoparticles synthesis of TiO2 or Nb2O5 oxide with P3HT. The grafted TiO2@P3HT and Nb2O5@P3HT are characterized by structural and morphological properties. In addition, a deeply study in its optical properties were performed using FLIM characterization in order to better understand their charge transport characteristics. CHAPTER 1 INTRODUCTION: MATERIALS FOR THIRD GENERATION PHOTOVOLTAICS 22 In order to supply the growing demand of electricity consumption, the use of renewable energies, such as photovoltaic cells – solar cells (SC), is rising as a promising option as a form of clean and efficient energy to reduce the use of fossil fuels as non-renewable and polluting (MOULE, 2012). Nevertheless, photovoltaics do not have significant participation in the Brazilian energy matrix (AMBIENTE, 2012). The main reason for the low participation of photovoltaic devices in the energy market is still high cost of energy produced from such devices (ENERGIA, 2012), since the current industry involves devices as silicon-based and single and multi-junction, due to its high efficiency in power conversion (FRAUNHOFER INSTITUTE FOR SOLAR ENERGY SYSTEMS, 2015) with efficiencies of 15 to 25 % (FRAUNHOFER INSTITUTE FOR SOLAR ENERGY SYSTEMS, 2015). The first SCs were constructed by Charles Fritts in 1890 (ZACHARY A. SMITH, 2008). They used selenium as a semiconductor and thin layers of gold to form the junctions. The model was improved by Russell Ohl in 1941 (ZACHARY A. SMITH, 2008). He developed the first silicon cell, now known as first generation solar cells, which consist mainly of bulk crystalline silicon p-n junctions. The first generation of SC was the dominant technology in terms of commercial production, until the advent of the single and multi-junction solar cell (FRAUNHOFER INSTITUTE FOR SOLAR ENERGY SYSTEMS, 2015). The second generation of SC uses thin films as semiconductors. Many materials are employed in this devices, such as amorphous silicon, silicon polycrystalline or microcrystalline and cadmium telluride (REYNOLDS, 1954). Thin film technologies were chosen in order to reduce the amount of material required to production and therefore costs. Nowadays, the single and multi-junctions devices have the best research efficiencies, as observed in the efficiency chart in the Figure 1. 23 Figure 1: Best research-cells efficiencies chart. From: http://www.nrel.gov/ncpv/images/efficiency_chart.jpg (May 2016) The third generation of solar cells are devices that are potentially able to overcome the Shockley–Queisser limit of 31–41 % power efficiency for single bandgap solar cells. Theoretically, an infinite number of junctions would have a limiting efficiency of 86.8% under highly concentrated sunlight. (SHOCKLEY, 1961; CONIBEER, 2007). Common third- generation systems include multi-layer cells made of amorphous silicon or gallium arsenide and dye-sensitized (DSSC), organic, polymer and perovskite solar cells. This work will focus in materials for hybrid (DSSC) and organic (bulk heterojunction) systems. These SCs have low energy conversion efficiency, from 10 – 13 % as observed in Figure 1, but they are good candidates for the current market due to their high optical absorption, ease of processing, allowing production on an industrial scale and good cost benefits (J. CHANDRASEKARAN, 2011). Therefore, research into hybrid systems aims to maintain the low cost of production with the differential to combine semiconductor, optical and electrical http://www.nrel.gov/ncpv/images/efficiency_chart.jpg 24 properties of inorganic materials with properties as mechanical resistivity and easy processability of organic compounds, such as polymers and presents great potential in energy conversion efficiency (REYNOLDS, 1954; ARICI, 2003; SHAHEEN, 2005; J. CHANDRASEKARAN, 2011). 1.1 Dye Sensitized Solar Cells (DSSC) The dye sensitized solar cells (DSSC), also known as Grätzel solar cells, were firstly developed by Professor Michael Grätzel team in Switzerland in 1991 (B. O´REGAN, 1991). In this kind of device, the photoanode is made by a porous film of a semiconductor material deposited on a transparent conducting oxide (TCO) and sensitized by a dye. The positive terminal of the cell, the cathode, is coated with a catalytic material such as platinum layer on TCO. The electrolyte, usually an iodide/triiodide redox pair solution, is interposed between the two electrodes. Specifically, in a DSSC device, the photon of light incident is absorbed by the dye, generating a photo-electron that is injected into the conductive band of the nanocrystalline semiconductor, as presented in Figure 2. The electron diffuses to the negative electrical contact through a circuit and is collected by the cathode, in which, with the aid of the catalyst, enables the reduction reactions of the electrolyte. The dye molecule is oxidized to reduced state original redox couple through a liquid within the pores of electrode (B. O´REGAN, 1991; GRATZEL, 2001; GRÄTZEL, 2003). 25 Figure 2: The electron injection process and energy levels diagram of a DSSC. From: http://www.mdpi.com/2072-666X/5/2/171/htm#B117-micromachines-05-00171 The dyes most used in DSSC are ruthenium complexes, such as N3, N719 and Z907 (YE, 2015). Those materials are very effective due to their intense absorption in the whole visible range. However, these complexes contain Ru as a heavy metal, which is undesirable from environmental and cost aspects. Alternatively, natural dyes such as phthalocyanines and anthocyanins, can be used for the same purpose with great availability, low cost and an acceptable efficiency, up to 1.7% (HALME, 2010; NARAYAN, 2012). The electrolyte is responsible for the inner charge carrier transport between electrodes and continuously regenerates the dye and itself during DSSC operation (WU, J., 2015). Also, the semiconductor film plays an important role in the device efficiency (JOSE, 2009; DHAS, 2011). It should be composed of a material with adequate energy levels and morphology. So far, the most used materials are metal oxides such as TiO2 and ZnO (QUINTANA, 2007). Properties such as particle size, surface area, good adhesion to the substrate and appropriate morphology to promote greater interaction dye/oxide are desirable (JOSE, 2009). Thus, a depth study of the 26 properties of these materials is crucial role in the performance of devices (M. M. RASHAD, 2012). Since TiO2 has been the material of choice for the development of the first DSSC and a fundamental material for photovoltaic devices, this oxide was used as subject of this PhD thesis. In this work, we will focus on the synthesis and characterization of TiO2 with different morphologies synthesized by microwave assisted hydrothermal technique. 1.2 TiO2 Nanocrystalline titania (TiO2) has been intensively investigated due to its numerous applications in many fields such as photocatalysis, photovoltaic cells and gas sensors (CHEN, X., 2007). It is cheap, abundant, chemically stable and a multi-functional material. The properties of TiO2 are significantly dependent on the crystalline phase (anatase, rutile or brookite, illustrated in Figure 3). Wherein, anatase and rutile have a significant role in industrial applications. Experimental data on TiO2 brookite is limited due to its rarity and difficult preparation (LANDMANN, 2012). The rutile phase is typically found in mineral form, being the thermodynamically stable phase. Anatase has a low electron hole recombination rate and due to its high photoactivity is believed to be the most favorable phase for solar energy conversion (CHEN, D., 2009) and photocatalysis (ISMAIL, 2011). It is a n-type semiconductor with an indirect band gap of 3.2 eV (TANG, 1995). Particle size has great influence on the structure and properties of TiO2. In the nanometric regime, anatase is the most stable polymorph (DAR, 2014). 27 Figure 3: TiO2 crystalline structure for a) rutile, b) anatase and c) brookite. Oxygen atoms represented in red and titanium in white. From: Adapted of Landman et al. 2012. (LANDMANN, 2012) The chemical structure of TiO2 is composed by an octahedron with Ti+4 ion in the center, surrounded by six atoms of O-2. Anatase and rutile crystalline phases differ in the number of atoms per unit cell; anatase has four molecules TiO2 and rutile two. Consequently, the anatase structure is more bulky, elongated and less dense than the rutile (CHEN, X., 2007). Furthermore, the anatase phase, due to its structure, has low recombination rate of the electron- hole system (DHAS, 2011). Nanostructured anatase TiO2 electrodes are believed to be essential for achieving high conversion efficiencies and good long-term stability in DSSCs. Although there is no generally accepted explanation, this fact is commonly attributed to the structure and chemical composition of the TiO2 surface in this particular phase. (MUNIZ, 2011) The particle size has great influence on the device efficiency: small particle size have a greater surface area, which optimizes charge transfer process to the surface and decreases the recombination of charges in the bulk, and increase the contact surface with the dye (LANDMANN, 2012). Also, 28 anatase nanoparticles with 10 - 20 nm could result in transparent pastes (ITO, S., 2007). Surface area is another important parameter once large surface area is needed for sufficient dye loading. Thus, for each application, careful tailoring of specific properties such as phase composition, surface area and morphology is requested. Several TiO2 nanostructures such as spheres (DAR, 2014), nanorods (MELCARNE, 2010) and nanotubes (BAVYKIN, 2006; LIU, N., 2014) have been synthesized using different techniques like sol-gel, electrochemical, sonochemical and hydrothermal (BAVYKIN, 2006; OU, 2007). Hydrothermal synthesis is an environmentally friendly methodology to synthetize nanostructured materials (MAO, 2007). The starting material, synthesis conditions and processing can drastically change the end material. For example, Kim et al, (KIM, D.S., 2007) obtained well-defined spherical mesoporous TiO2 prepared from Titanium(IV) isopropoxide (TTIP). Kasuga et al. (KASUGA, 1998) has obtained titanates nanotubes from TiO2 nanopowder with high concentrations of NaOH. The hydrothermal synthesis is typically done using an autoclave with Teflon liners under controlled temperature and/or pressure in aqueous solutions (JIANG, 2006; CHEN, X., 2007; CHEN, D., 2009; NAKAHIRA, 2010). Despite its advantages, the synthesis can take several hours to be completed (CORRADI, 2005). Microwave assisted reactions were found to reduce the hydrothermal synthesis time of TiO2 by typically 1/3 (CORRADI, 2005; MANFROI, 2014; SHEN, 2014), and in addition can produce single crystal, with less waste and lower temperatures. TTIP is commonly used in conventional and microwave assisted hydrothermal synthesis of TiO2 under acid conditions (BAVYKIN, 2006; CHEN, X., 2007; OU, 2007; ISMAIL, 2011; LIU, N., 2014; PANG, 2014), but less in alkaline (SAPONJIC, 2005). Another important characteristic of nanomaterials is the morphology. The size and shape of the nanocrystals, as well as the surface topography is the key to increased electron capture efficiency. Several studies have been conducted to the size control and forms of these 29 nanocrystals and their influence on devices (CHEN, X., 2007; VITTADINI, 2007; HUANG, C.-H., 2011; XIN, 2011). The morphology control of nanomaterials mainly occurs during the synthesis. However, the synthesis of nanoparticles is not a trivial task. These can be obtained from colloidal suspensions, using several different techniques and methods. Table 1 and 2 present some works about the synthesis of TiO2 using hydrothermal and microwave assisted hydrothermal technique in acid and alkaline conditions. 30 Table 1: Brief summary of TiO2 derivatives synthesized by hydrothermal and microwave assisted hydrothermal in acidic media. Reactants Synthetic conditions Nanoparticles characteristics Reference TTIP, complexing agents EDTA, DTPA and IDA, and the alkalis TEA, EDA, EA, DEA and TEAOH. Sol-gel followed by microwave assisted hydrothermal using 900 W, 140 °C, 5 - 7 bar during 1 to 20 min. Variable diameter and nanoparticles in anatase phase with 5-45 nm with irregular shape. Arin et al.(ARIN, 2013) TiCl4, H2SO4, hydrochloric acid 2 M. Microwave assisted hydrothermal using 300 W, 120 to 180 °C and from 30 to 120 min. Anatase aggregated nanoparticles with spherical form and particle sizes similar in all tested conditions. Baldassari et al. (BALDASSARI, 2005) TTIP, propylamine, KCl and ethanol. Sol-gel followed by microwave assisted hydrothermal at 200 °C, 280 psi and 260 W for 80 min. Mesoporous spherical nanoparticles with diameter of 400 to 600 nm with nanocrystals of 10 nm as building blocks and surface area of 132.49 m2.g-1. Chen et al. (CHEN, P., 2013) TiOCl2 in water. Hydrothermal and microwave assisted hydrothermal at 195 °C from 1 to 32 h for conventional system and 5 min to 1 h using the microwave. Regardless of the synthetic method was obtained rutile as the predominant phase. The microwave synthesis gave aggregated particles with spherical morphology of ~ 10 nm and conventional synthesis yielded larger acicular crystals, 50 to 100 nm. Corradi et al. (CORRADI, 2005) Commercial TiO2 nanoparticles (P25) and 2-propanol in water and HNO3. Hydrothermal at 200 °C for 15 h and microwave assisted hydrothermal at 145 °C from 5 to 360 min. Anatase thin films with surface area from 140 to 300 m2.g-1. Wilson et al. (WILSON, 2006) TTIP in ethanol and water with acetic acid as catalyst. Particles synthesized by sol-gel, followed by microwave assisted hydrothermal at 225 and 450 °C using 400 ± 50 W e 425 ± 75 W. Similar crystallinity in anatase phase for all conditions used. Hart et al. (HART, 2004) TiCl4, ethanol and citric acid. Sol-gel followed by microwave assisted hydrothermal at 120 to 180 °C from 30 to 120 min. Mesoporous anatase nanoparticles with size from 5 to 7 nm and surface area from 217 to 323 m2.g-1. Huang et al. (HUANG, C.- H., 2011) 31 TiCl4, HCl and water. Microwave assisted hydrothermal at 190, 100, 50 and 250 psi, equivalent to 192, 164, 138 and 116 °C, respectively from 2 min to 2 h. Rutile and anatase nanoparticles with different morphologies and yields from 25 to 95 %. Komarneni et al. (KOMARNENI, 1999) TTIP, water, hydrochloric acid and NaHPO4–Na2HPO4, Sol-gel followed by hydrothermal or microwave assisted hydrothermal at 240 °C, from 100 to 550 psi and from 1 to 2 h. Anatase nanoparticles with brookite as secondary phase with size from 5 to 10 nm. Lu et al. (LU, C.-W., 2014) Table 2: Brief summary of TiO2 derivatives synthesized by hydrothermal and microwave assisted hydrothermal in alkaline media. Reactants Synthetic conditions Nanotubes characteristics References Homemade rutile and anatase powders with the addition of crystalline nanoparticles after sintering Microwave assisted hydrothermal using 195 W for 90 min. Nanotubes with internal width of 4.48 nm and 12.82 nm in diameter. Xing Wu et al. (WU, X., 2007) TiO2 powder and aqueous NaOH. Microwave assisted hydrothermal during 6 h. Titanate nanotubes with high purity. Length up tens of μm and diameter of 7 nm. Wang et al. (WANG, Y.- A., 2005) Homemade TiO2 and commercial TiO2 (P25) in NaOH 10 M. Microwave assisted hydrothermal using 195 W for 90 min. Nanotubes with width of 8 to 12 nm and lengths from 200 to 1000 nm. Surface area of 145.8 m2 g−1. Xing Wu et al. (WU, X., 2005) Nanoparticles synthesized on the surface of a Ni substrate using commercial TiO2, PVA and NaOH in aqueous media. Microwave assisted hydrothermal using 150 to 200 °C for 3 to 5 h. Nanotubes from 4 to 5 multilayers approximately 10 nm in width and tens of nm long. Cui et al. (CUI, 2012) Commercial anatase and rutile powders in NaOH 10 M. Hydrothermal at 150 °C for 48 h and HCl washing until pH=7 Titanate with 8 to 11 nm width with 2 to 4 walls. Surface area from 222 to 267 m2 g−1. Choi et al. (CHOI, 2010) 32 Commercial TiO2 (P25) in 10 N NaOH. Hydrothermal from 110 to 150 °C for 24 h and HCl 0.1 N washing until pH < 7. Surface area from 207 to 399 m2 g−1. Tsai et al. (TSAI, 2004) TiO2 nanopowders in solutions 5 to 10 M NaOH. Hydrothermal at 110 °C for 20 h a 110 °C followed by 0.1 N HCl washing until pH < 7. Needle like macrometer structures in anatase phase, nanotubes with diameter of 8 nm and length of 100 nm and surface area of 400 m2 g−1. Kasuga et al. (KASUGA, 1998) Commercial TiO2 (P25) in 10 M KOH. Microwave assisted hydrothermal using 500 W, 0.5 to 3 MPa (equivalent to 175 to 260 °C) for from 40 to 70 min. TiO2 nanowire in anatase phase with diameter from 5 to 10 nm and length from 500 nm to 2 μm. Li et al. (LI, L., 2011) Commercial anatase TiO2 in 10 M NaOH. Microwave assisted hydrothermal using from 130 to 200 °C from 30 to 4 h followed by washing until pH 6. Titanate nanotubes, Na2Ti6O13, few μm lenght and average of 11 nm diameter (130 °C / 4 h) and 20 nm (150 °C / 4 h). Manfroi et al. (MANFROI, 2014) Commercial rutile TiO2 in 10 M NaOH. Microwave assisted hydrothermal using 200 °C for 45 min, followed by 0.1 M HNO3 washing. Nanotubes in rutile phase with diameter of 3-10 m and surface area of 214 m2 g−1. Huang et al. (HUANG, K.-C., 2013) Commercial TiO2 (P25), Ag–TiO2 powder in 10 M NaOH. Microwave assisted hydrothermal using 195 W, 150 °C for 4 h followed by 5 N HCl washing until pH ~7. Multi-walled nanotubes titanates structures with a diameter from 8 to 10 nm and a length of some μm with surface area ranging from 52 to 130 m2 g−1. Rodrigues-Gonzalez et al. (RODRÍGUEZ- GONZÁLEZ, 2012) 33 1.3 Hydrothermal and microwave assisted hydrothermal techniques Hydrothermal synthesis has been widely applied to obtain advanced materials, since it allows the morphology control, high purity crystals and control of particle growth using relatively low temperatures (BYRAPPA, 2001a). The method is based on the formation of crystal structures by dissolution and crystallization process with single or heterogeneous-phase reactions in aqueous solution under pressure generated by the system (SU, 2006). This synthesis takes place in aqueous, gels or suspensions mediums denominated as precursor solutions. Also, mineralizers may be added to change the pH of the system and help solubilisation of the precursors and reaction kinetics. To control the dispersion and particle morphology, other reagents such as surfactants or peptizing agents may be added in the reaction (YANG, J., 2001). The reactor is an autoclave (BYRAPPA, 2001a) and it is an important item in the synthesis, and it can variate according with the final objective product and the synthetic environment, however, it must satisfy the following characteristics (BYRAPPA, 2001b): i. be inert to acids, bases and oxidizing agents, ii. easy to assemble and disassemble, iii. having a sufficient length to the desired temperature gradient, iv. be leak-proof in working temperatures and pressures, and v. sturdy enough to withstand high pressures and temperatures in long-term experiments. For the synthesis of metal oxides, for example, typically are used Teflon-coated stainless steel reactors which could be externally heated. Currently, this synthesis method have been used for the synthesis of new materials and stages, stabilizing complexes, crystal growth from various inorganic compounds, the preparation of films, leaching of materials in the extraction of metals, synthetic organic materials among others (SU, 2006). The materials are obtained at low temperatures in a short treatment time and fewer processing steps, which makes economically viable, environmentally friend and industrially interesting technique. 34 In the 90s, Komarneni et al. combined microwave radiation with hydrothermal system for the synthesis of ceramic powders (BYRAPPA, 2001a). The development of this new synthetic route allowed the formation of oxides with different characteristics and properties (BALDASSARI, 2005). In general, the effects caused by microwave radiation are able to encourage chemical reactions that would not occur in conventional heating (BYRAPPA, 2001a; CORRADI, 2005). These effects result from the direct coupling of the material with microwaves, independent of temperature and reaction. Thus, the method is fast, clean and more economical than conventional hydrothermal and has received special attention due to advantages such as, rapid heating and temperature control, which leads to time and energy saving, increased reaction rate for one or two orders of magnitude, formation of new phases and selective crystallization (KOMARNENI, 1999; CORRADI, 2005; HUANG, C.-H., 2011; CUI, 2012; CHEN, P., 2013; ZHU, Y.-J., 2014). In this work, we present an easy and fast route for TiO2 nanostrucutres synthesis using microwave assisted hydrothermal technique in alkaline and acidic mediums. We demonstrate an environmentally friendly synthesis that uses mild conditions, low reaction times and temperatures and gives nanoparticles with different morphologies, high yield and high surface area. We have obtained titanate needle like particles after 30 min of synthesis using TTIP in alkaline media. The facility in producing these nanostructures, its reproducibility and low cost make it attractive for industrial applications. 1.4 Bulk heterojunction solar cells Organic polymer-based photovoltaic devices (OPV) have attracted attention for their low cost, ease of processing, for being light, and even flexible, form of clean and renewable energy (LU, L., 2015). New organic precursors have achieved a power conversion efficiency of the 35 OPVs higher than 10%, as observed in Figure 1. Bulk heterojunction solar cells were firstly reported in 1995 (G. YU, 1995). Since then, much efforts has been made to improve the system (LU, L., 2015). In an organic photovoltaic cell a thin film of organic semi-conductor materials (polymers, oligomers or small molecules) acts as active layer. This layer is placed in between the TCO and a metal electrode, as presented at Figure 4. Materials having a delocalized π electron system can absorb sunlight, create photo-generated charge carriers and transport them (GÜNES, 2007b). Typically, the organic semiconductors are either having an electron donating (donors) or electron accepting (acceptors) properties. The active layer of this device is composed of both electron donor and acceptor materials (KAUR, 2014). For example poly(3- hexylthiophene) - P3HT, a p-type hole conducting material, works as electron donor, whereas phenyl-C61-butyric acid methyl ester - PCBM and its derivatives show a n-type, electron conducting behavior and serve as electron-acceptor material (DANG, 2011). Figure 4: Illustration of bulk heterojunction solar cell. From: http://www.cstf.kyushu-u.ac.jp. 36 The organic solar cells work as follow: in photon absorption, an electron is excited from the HOMO to the LUMO. This electron-hole pair (exciton) relaxes with a binding energy between 0.1–1.4 eV (MAYER, 2007). The excitons must migrate to an interface where there is a sufficient chemical potential energy drop to drive dissociation into an electron-hole pair across the donor and acceptor (MIHAILETCHI, 2004; MAYER, 2007). The phase separation orientations in these devices are random and percolation paths of pure donor or acceptor material can connect the two electrodes. In its place, the current flow is controlled by the use of electrodes having sufficiently different work functions. Such that the anode electrode is chosen as a high work function material and the cathode selected as a low work function metal. As the efficiency of a solar cell is dependent of the open circuit voltage (Voc), short circuit current density (Jsc) and the fill factor (FF), Scharber et al. (SCHARBER, 2006) have predicted 10% as an attainable efficiency of a bulk heterojunction as a function of the band gap and the LUMO level of the donor, optimizing the LUMO level of the donor polymer optimizes the device’s open circuit voltage and consequently the FF, having as high as possible charge carrier mobility of electrons and holes in the donor-acceptor blend, as illustrated in the Figure 5. As observed, it describes the efficiency of bulk-heterojunction solar cells that comprise a donor with a variable band gap in conjunction with an acceptor with a variable LUMO. For highest efficiencies, the difference between the LUMO levels needs to be 0.3 eV, and a band gap in the range of 1.2–1.7 eV, which would correspond to donor HOMO levels of –5.2 to –5.7 eV if the acceptor is PCBM (whose LUMO is assumed to be 4.3 ev). (DENNLER 2009) 37 Figure 5: Contour plot showing the calculated energy-conversion efficiency (contour lines and gray scale) versus the bandgap and the LUMO level of the donor polymer. Straight lines starting at 2.7 eV and 1.8 eV indicate HOMO levels of –5.7 eV and –4.8 eV, respectively. A schematic energy diagram of a donor PCBM system with the bandgap energy (Eg) and the energy difference (ΔE) are also shown. From: Adapted from (DENNLER 2009) For this propose novel materials have been prepared to reach better performance and high efficiencies. Several strategies were investigated to increase the efficiency of solar cells. In this work, we are targeting a new n-type polymer based on fullerenes in the backbone. Fullerene is well-known as an excellent electron acceptor, and it is expected that its polymers will have good solubility to give rise uniform thin films. 38 1.5 Fullerenes Fullerenes are a key topic on nanotechnology and industrial research nowadays. The high electron affinity and superior ability to transport charge make fullerenes the best acceptor component currently available (NAZARIO MARTIN, 2009). Fullerenes were discovered in 1985 by Kroto, Curl and Smalley (IIJIMA, 1991), and resulted in the Nobel Prize in Chemistry in 1996. It became available in notable amounts after 1990 with the preparation process of Krätschmer and Huffman (W. KRÄTSCHME, 1990). The energetically deep LUMO of fullerenes endows the molecule a very high electron affinity relative to the numerous potential organic donors. The triply-degenerate low LUMO of C60 and C70, Figure 6, also allows the molecule to be reversibly reduced with up to six electrons, thus explaining its ability to stabilize negative charge (KAUR, 2014). The carbon atoms within a fullerene molecule are sp2 and sp3 hybridized, of which the sp2 carbons are responsible for the considerably angular strain presented within the molecule. C60 has a localized π-electron system, which prevents the molecule from displaying superaromaticity properties. Figure 6: Illustration of C60 and C70 structures. From: http://what-when-how.com/nanoscience-and-nanotechnology/nanocrystalline- materials-synthesis-and-properties-part-1-nanotechnology/ The development of chemical reactions able to modify the chemical structure of C60 led to new fullerene derivatives which exhibits a variety of outstanding electronic, magnetic, 39 conducting, superconducting, electrochemical and photo physical properties (NAZARIO MARTIN, 2009). The combination of the advantage of this molecule with the properties of other materials as polymers is very challenging. Combination of fullerenes and polymer chemistry is an interdisciplinary field in which all knowledge on the synthesis and study of natural as well as artificial macromolecules can be applied to fullerenes to achieve novel fullerene-based architectures with unprecedented properties and realistic applications (GIACALONE, 2006). Figure 7 shows the representation of some synthesized C60-containing polymers. Figure 7: Representation of C60-containing polymers. From: Giancalone et al.2006 (GIACALONE, 2006). Nowadays, the chemical reactivity of C60 is well established, and a large number of fullerene derivatives have been prepared (GIACALONE, 2006). The extraordinary electronic properties of the fullerene C60 as an n-type semiconductor with relatively high carrier mobility have evoked continued interest in the development of a wide variety of chemically modified fullerene derivatives to application in organic devices, as solar cells (MILLER, 2006; LIAO, 40 2012; LI, C.-Z., 2013). Polymer solar cell advantages include low cost of fabrication, ease of processing, mechanical flexibility and versatility of chemical structure through advances in organic chemistry (GÜNES, 2007b; THOMPSON, 2008). The photo-charge generating layer is made from a blend of a semiconducting chromophoric electron donating p-type polymer, such as the standard bearer P3HT, and an acceptor n-type small molecule, typically PC61BM (HIORNS, 2006). While much has been done to vary p-type materials, not least the introduction of the so- called low-band gap polymers to capture greater degrees of available light and reach efficacies greater than 10 % (BOUDREAULT, 2011; GREEN, 2014), relatively few papers deal with the modification of the fullerene derivative. PC61BM is widely used because of its excellent electron affinity and good charge mobility arising with crystallization (THOMPSON, 2008). However, it forms µm-scale crystals, through a thermally enhanced leaching process, that diminish device efficiencies (MOORE, 2013). Incorporating C60 into a polymer may permit stabilization of the active layer. Moreover, the creation of a metal-free method of polymerizing fullerene would expand the possibilities for use of C60 in anti-cancer and anti-viral treatments (KHARISOV, 2009; LUCAFÒ, 2012; LUCAFÒ, 2013; MARINA A. ORLOVA, 2013; LUCAFÒ, 2014), as it would make possible the exploitation of poly(fullerene) nano- and meso- structures such as micelles and vesicles (J. HOLDER, 1998). C60 is typically incorporated into polymers as a moiety pendent to the main-chain as it is relatively simple to control just one addition to the sphere (DREES, 2005; ADAMOPOULOS, 2006; BALL, 2006; GIACALONE, 2006; HEISER, 2006; SIVULA, 2006; BARRAU, 2008), but such polymers can result in excessive aggregation of C60s (GHOLAMKHASS, 2010). Using C60 as a monomer may reduce the degrees of freedom of movement of C60, making excessive aggregation in the solid state less likely. Incorporating C60 directly into the polymer main-chain, however, is generally not simple as there are 30 [6,6]- 41 double bonds. Prior methods have included using Diels-Alder chemistry (GÜGEL, 1996), methano-bridges (SHI, 1992) and tether-directed pre-modification of C60(ITO, H., 2006), but these can give cross-linking, intractable products, or require multi-step preparative chemistry, respectively. An attempt to resolve this was made using atom transfer radical addition polymerisation (ATRAP) as the reaction is based on radical bis-additions around just one C60 1,4-phenylic ring (RAMANITRA 2016) One down-side of this system though was the high amounts of CuBr required, leading to metal impurities of which even trace amounts can be detrimental to device performances (URIEN, 2007; NIKIFOROV, 2013). An alternative and recently discovered method, the so-called sterically controlled azomethine ylide cycloaddition polymerization (SACAP) of C60, showed that it was possible to reach high molecular weight poly(fullerene)s with certain co-monomers under forced conditions (RAMANITRA 2016). This stimulated us to see if new metal-free polymerizations of fullerene could be developed with different routes. Aziridinofullerenes, are useful synthetic intermediates for highly efficient and regioselective addition of spherical fullerene cages, as acid-induced 1,4-bisaddition of aromatic compounds, [2+2] cycloaddition with alkynes and isomerization to azafulleroids. The aziridino fullerenes have been widely prepared by 1,3 dipolar cycloaddition of azides to C60 followed by thermal or photochemical denitrogenation of the triazolinofullerene adducts (YANG, H.-T., 2014). The reaction results in two isomeric products such as [5,6]-open fulleroids and [6,6]- closed methanofullerenes (YANG, C., 2009a), all the isomeric procuts are presented in Figure 8. From an electronic-structure point of view, the [5,6]-open isomers are appealing since they conserve the 60 π electrons of the C60. 42 Figure 8: Aziridinofullerenes isomeric products. From: Cases et al. (CASES, 2000) Prior work has demonstrated that imino-C60 mono-adducts can exhibit high charge mobilities (YANG, C., 2009a). We were therefore particularly interested to see if the bis-imino adduct chemistry (SCHICK, 1996) could be extended to prepare stable polymers with high electron mobilities, and to explore their applicability to organic photovoltaic devices (OPVs). We report for the first time the discovery that it is possible to deliver oligo- and poly(aziridinofullerene)s (PAFs). The macromolecular structures are prepared using 1,3- dipolar cyclo-additions of diazido comonomers to C60 under catalyst-free conditions and the methodology is such that metals are avoided in the final synthesis. 1.6 Hybrid particles Hybrid nanocomposite materials combine the advantages of inorganic (stability, high electron mobility, nano-scale electrical and optical properties) and organic materials (easy processability, high coefficient absorption) (WRIGHT, 2012). Even though inorganic-organic systems have already been applied in (opto)electronics, including solar cells (GÜNES, 2007a), 43 light emitting diodes (YANG, Y., 2008) and sensors (LEVELL, 2010), the interface between conjugated polymers and nanocrystals is a challenge due to their different properties. The efficient energy transfer between organic and inorganic semiconductors is a widely sought property. However, issues in the interfacial charge separation and transport are not fully understood, there is a critical need for a deeper fundamental understanding of the influence of long-range ordering on collective phenomena such as exciton diffusion and recombination and carrier transport. It is commonly believed that a photogenerated exciton dissociates to generate a bound complex with charge transfer character at a donor/acceptor heterojunction and then separates into fully dissociated charge carriers (LIU, R., 2014). The interfacial charge separation is an important step in the photovoltaic processes of the hybrid materials. For improvement of devices performance and enhance properties of hybrid materials a strategy is to attach the components by covalent bonds (BOUSQUET, 2014). The combination between TiO2 attached with π-conjugated semiconducting polymers serving as photoactive charge transport material have been study by others researchers (BEEK, W. J. E., 2002; BEEK, WALDO J. E., 2004; ODOI, 2006; ZHANG, Y., 2006; XU, 2012; BOON, 2014). In those hybrid systems, there is the possibility of precisely synthesize inorganic nanocrystals and organic polymers with high degree of structural control, to optimize properties of the components, building functional materials. Passivation of nanocrystals surface with organic materials, such as polymers, is one strategy to prevent aggregation and enhance their dispersion in solutions. The most used surfactants with non-conjugated satured chains do not facilitate electron transfer between the materials (XU, 2012). In order to understand the key issues in association with photoinduced charge separation/transportation processes and to improve overall power conversion efficiency, various combinations with nanostructures of hybrid systems have been investigated. Typically, the domain sizes within either component of the heterojunction should be comparable to the diffusion length of an exciton in that material 44 (ARICI, 2003; BRISENO, 2010; BOON, 2012; ISHII, 2012; BABU, 2014; JAYARAMAN, 2014). For soluble media, the large interfacial area is achieved spontaneously by blending the acceptor and donor components together in a solution, which is then cast into thin films (BOUCLE, 2007). Awada et al. have create a macromolecular self-assembled monolayer that could be applied to different metal oxide surfaces and represents a new one-pot strategy based on triethoxysilane coupling reaction (AWADA, 2014). Some other works grew the polymers directly into the oxides. Xu et al. have investigated the charge transfer between triethoxy-2- thienylsilane covalently link P3HT onto TiO2 nanorods. They have found to have a more coil- like conformation in the chemically linked samples with more twisted defects that led to torsional relaxation with a larger amplitude and a longer decay time than those in pristine P3HT and physically mixed samples. Beek et al (BEEK, W. J. E., 2002) have studied grafted TiO2@oligothiophene via a carboxylic acid functionalized group and the influence of alkyl linker length. They have found the rate of electron transfer decreasing as the alkyl spacer length increased. Later (BEEK, WALDO J. E., 2004), they have study heterosupramolecular assemblies of terthiophene moieties and TiO2 nanoparticles, linked by alkyl spacers of different lengths in the rate of charge transfer monitoring the changes in the competing fluorescent decay. They also have found that longer spacers lower the charge transfer rate. Zhag et al.(ZHANG, Y., 2006) grew P3HT onto TiO2 nanotubes via a covalent silane linker, which exhibited more efficient charge transfer from P3HT to TiO2 than physisorbed P3HT. However, the alkyl group used in the linker might cause electron transfer to take place in a weakly-coupled nonadiabatic regime. In this study, we have synthesized grafted nanoparticles, TiO2@P3HT and Nb2O5@P3HT using triethoxysilane-terminated P3HT and homemade TiO2 and Nb2O5 nanoparticles. The energy migration in P3HT and charge transfer from P3HT to the oxides were 45 studied by comparison with the polymer and physically mixed P3HT/oxides. The charge transfer was found to occur evidenced by photoluminescence (PL) quenching and a decay of the life time constant of the grafted samples, differing from the polymer. 46 CHAPTER 2 METHODOLOGY AND CHARACTERIZATION TECHNIQUES 47 2.1 Methodology 2.1.1 Polyfullerenes Chemicals and reagents were used as received from Aldrich unless otherwise indicated and stored in the glove box when required. Solvents were dried from over their respective drying agents under dry nitrogen. All reactions were performed under pre-dried nitrogen and in flame-dried glassware. All polymerizations were performed under stringently controlled anaerobic conditions using typical Schlenk line techniques. Solvents, such as 1,2-dichlorobenzene and toluene, were repeatedly degassed under reduced pressures and flushed with dry nitrogen prior to use. Chemicals were similarly placed under reduced pressure and covered with nitrogen. Syringes used to transfer reagents or solvents were nitrogen purged. Comonomers Synthesis (All the NMR spectra are presented in a special Section in the end of Chapter 3) Synthesis of 1,4-bis(octyloxy)benzene (2) Scheme 1: Synthesis of 1,4-bis(octyloxy)benzene (2) from hydroquinone (1). Hydroquinone (10.0 g, 0.09 mol) and K2CO3 (37.6 g, 0.27 mol) were stirred with acetonitrile (100 mL) for 30 min at room temperature under nitrogen. 1-Bromooctane (12 mL, 48 0.07 mol) was added dropwise and the reaction heated at reflux for 48 h. On cooling to room temperature, the solution was dropped into iced water (500 mL) and the product recovered by filtration. Purification was performed by twice dissolving the product in chloroform and precipitating it from methanol to yield white crystals (16.6 g, 54 %). 1H NMR (400.6 MHz, CDCl3) δ = 0.91 (t, J = 6.0 Hz, 6H, -OCH2(CH2)6CH3), 1.32-1.85 (m, 24H, -OCH2(CH2)6CH3), 3.95 (t, J = 6.0 Hz, 4H, -OCH2(CH2)6CH3), 6.87 (s, 4H, aromatics) ppm. Synthesis of 1,4-bis(dodecyloxy)benzene (3) Scheme 2: Synthesis of 1,4-bis(dodecyloxy)benzene (3) from hydroquinone (1). Hydroquinone (5.0 g, 0.045 mol) and K2CO3 (18.82 g, 0.14 mol) were stirred with acetonitrile (100 mL) for 30 min at room temperature under nitrogen. 1-Bromododecane (32.7 mL, 0.014 mol) was added dropwise and the reaction heated at reflux for 48 h. Once cooled to room temperature, the solution was dropped into iced water (500 mL) and the product recovered by filtration. Purification was performed by twice dissolving the product into chloroform and precipitating it from methanol to yield a white crystalline material (6.7 g, 44 %). 1H NMR (400 MHz, room temperature, CDCl3) δ = 0.91 (t, J = 6.0 Hz, 6H, -CH3), 1.51– 1.22 (m, 36H, -CH2-), 1.78 (t, J = 8.0 Hz, 4H, -CH2-), 1.88 (t, J = 6.0 Hz, 4H, -CH2-), 3.92 (t, J = 6.0 Hz, 4H, -O-CH2), δ 6.84 (s, 4H, -aromatic) ppm. 49 Synthesis of 1,4-bis(hexadecyloxy)benzene (4) Scheme 3: Synthesis of 1,4-bis(hexadecyloxy)benzene (4) from hydroquinone (1). Hydroquinone (5.0 g, 0.045 mol) and K2CO3 (18.82 g, 0.14 mol) were stirred with acetonitrile (100 mL) for 30 min at room temperature under nitrogen. 1-Bromohexadecyldecane (41.6 mL, 0.14 mol) was added dropwise and the reaction warmed to reflux for 48 h. Once cooled to room temperature, the solution was dropped into iced water (500 mL), and the product recovered by filtration. Purification was performed by twice dissolving the product into chloroform and precipitating it from methanol to yield a white crystalline material (7.8 g, 31 %). 1H NMR (400 MHz, room temperature, CDCl3): δ 0.91 (t, J = 6 Hz, 6H, -CH3), 1.51– 1.22 (m, 56H, -CH2-), 1.78 (q, J = 6,0 Hz, 4H, -CH2-), 1.87 (q, J = 6 Hz, 4H, -CH2-), 3.93 (t, J = 6,0 Hz, 4H, -O-CH2), 6.84 (s, 4H, -aromatic). Synthesis of 1,4-bis(bromomethyl)-2,5-bis(octyloxy)benzene (5) Scheme 4: Synthesis of 1,4-bis(bromomethyl)-2,5-bis(octyloxy)benzene (5). 50 1,4-Bis(octyloxy)benzene (5.0 g, 0.015 mol) and the paraformaldehyde (1.12 g, 0.04 mol) were stirred with acetic acid (150 mL) under nitrogen. HBr 31 % in acetic acid (8.3 mL, 0.05 mol) was added dropwise and the reaction warmed to 70 °C for 2 h. Once cooled to room temperature, the solution was quenched with 300 mL of water and the product recovered by filtration. Purification was performed by twice dissolving the product into chloroform and precipitating it from methanol to yield a brownish material (3.78 g, 48 %). 1H NMR (400.6 MHz, CDCl3) δ = 0.91 (t, 6H -OCH2(CH2)6CH3), 1.32-1.85 (m, 24H, - OCH2(CH2)6CH3), 4.01 (t, J = 4.0, 4H, -OCH2(CH2)6CH3), 4.55 (s, 4H, -CH2Br), 6.87 (s, 4H, aromatics) ppm. Synthesis of 1,4-bis(bromomethyl)-2,5-bis(dodecyloxy)benzene (6) Scheme 5: Synthesis of 1,4-bis(bromomethyl)-2,5-bis(dodecyloxy)benzene (6). 1,4-bis(dodecyloxy)benzene (5.0 g, 0.011 mol) and the paraformaldehyde (0.84 g, 0.028 mol) were stirred with acetic acid (150 mL) under nitrogen. HBr 31 % in acetic acid (6.8 mL, 0.036 mol) was added dropwise and the reaction warmed to 70 °C for 2 h. Once cooled to room temperature, the solution was quenched with 300 mL of water and the product recovered by filtration. Purification was performed by twice dissolving the product into chloroform and precipitating it from methanol of yield a brownish material (4.5 g, 64 %). 51 1H NMR (400.6 MHz, CDCl3) δ = 0.91 (t, J = 6.0, 6H -OCH2(CH2)10CH3), 1.20-1.55 (m, 36H, -OCH2(CH2)10CH3), 1.83 (m, 4H, -CH2-), 4.00 (t, J = 6 Hz, 4H, -OCH2(CH2)10CH3), 4.56 (s, 4H, -CH2Br), 6.87 (s, 2H, aromatics) ppm. Synthesis of 1,4-bis(bromomethyl)-2,5-bis(hexadecyloxy)benzene (7) Scheme 6: Synthesis of 1,4-bis(bromomethyl)-2,5-bis(hexadecyloxy)benzene (7). 1,4-bis(hexadecyloxy)benzene (5.0 g, 0.009 mol) and the paraformaldehyde (0.67 g, 0.02 mol) were stirred with acetic acid (150 mL) under nitrogen. HBr 31 % in acetic acid (5.7 mL, 0.03 mol) was added dropwise and the reaction warmed to 70 °C for 2 h. Once cooled to room temperature, the solution was quenched with 300 mL of water and the product recovered by filtration. Purification was performed by twice dissolving the product into chloroform and precipitating it from methanol to yield a brownish material (3.2 g, 48 %). 1H NMR (400 MHz, room temperature, CDCl3): δ 0.91 (t, J = 6 Hz, 6H, -CH3), 1.51–1.22 (m, 56H, -CH2-), 1.78 (q, J = 6 Hz, 4H, -CH2-), 1.87 (q, J = 6 Hz, 4H, -CH2-), 3.93 (t, J = 6 Hz, 4H, -O-CH2), 4.56 (s, 4H, -CH2¬Br), 6.84 (s, 2H, -aromatic). 52 Synthesis of 1,4-bis(azidomethyl)-2,5-bis(octyloxy)benzene (8) Scheme 7: Synthesis of 1,4-bis(azidomethyl)-2,5-bis(octyloxy)benzene (8). 1,4-bis(bromomethyl)-2,5-bis(octyloxy)benzene (3 g, 5.76 x 10-3 mol) and sodium azide (1.11 g, 0.017 mol) were stirred with dimethyl sulfoxide (40 mL) under nitrogen for 12 h. The solution was dropped into iced water (150 mL), and the product recovered with diethyl ether (100 mL). Purification was performed by twice washing the solution with brine and recovering with diethyl ether. Drying over MgSO4, roto-evaporation of the solvent, filtration and drying under air yielded white crystals (1.72 g, 67 %). 1H NMR (400.6 MHz, CDCl3) δ = 0.91 (t, J = 6.0, 6H -OCH2(CH2)6CH3), 1.32-1.85 (m, 24H, -OCH2(CH2)6CH3), 4.01 (t, 4H, -OCH2(CH2)6CH3), 4.45 (s, 4H, -CH2N3), 6.87 (s, 4H, aromatics) ppm. 13C NMR (100.16 MHz, CDCl3) δ = 14.34 (s, O-CH2(CH2)6CH3), 22.70 (s, O- CH2(CH2)5CH2CH3), 26.08 (s, O-CH2CH2CH2(CH2)4CH3), 29.23 - 29.33 (m, O- CH2(CH2)6CH3), 31.74 (s, O-CH2(CH2)4CH2CH2CH3), 49.81 (-CH2-N3), 68.93 (s, O- CH2(CH2)6CH3), 113.74 (s, aromatic), 124.88 (s, aromatic-CH2N3), 150.56 (s, aromatic- OC8H17) ppm. 53 Synthesis of 1,4-bis(azidomethyl)-2,5-bis(dodecyloxy)benzene (9) Scheme 8: Synthesis of 1,4-bis(azidomethyl)-2,5-bis(dodecyloxy)benzene (9). 1,4-Bis(bromomethyl)-2,5-bis(dodecyloxy)benzene (3 g, 4.74 x 10-3 mol) and sodium azide (0.31 g, 0.014 mol) were stirred with dimethyl sulfoxide (40 mL) under nitrogen for 12 h. The solution was dropped into iced water (150 mL), and the product recovered with diethyl ether. Purification was performed by twice dissolving the product in brine and recovering with diethyl ether and dried over MgSO4 to a yield a white material (2.3 g, 68 %). 1H NMR (400 MHz, CDCl3) δ 0.91 (t, J = 6 Hz, 6H, -CH3), 1.63 (m, 40H, -CH2-),1.82 (t, J = 6 Hz, 4H, -CH2-), 4.39 (s, 4H, -CH2-N3), 6.85 (s, 2H, -aromatic). 13C NMR (100.16 MHz, CDCl3) δ = 14.11 (s, O-CH2(CH2)10CH3, 22.69 (s, O- CH2(CH2)9CH2CH3), 26.08 (s, O-CH2CH2CH2(CH2)8CH3), 29.38 (s, O- CH2CH2CH2CH2(CH2)7CH3), 49.95 (s, -CH2-N3), 68.91 (s, O- CH2CH2CH2CH2CH2(CH2)6CH3), 76.70 - 77.34 (m, O-CH2(CH2)10CH3), 113.46 (s, aromatic), 124.18 (s, aromatic-CH2N3), 150.64 (s, aromatic-OC12H25) ppm. 54 Synthesis of 1,4-bis(azidomethyl)-2,5-bis(hexadecyloxy)benzene (10) Scheme 9: Synthesis of 1,4-bis(azidomethyl)-2,5-bis(hexadecyloxy)benzene (9). 1,4-Bis(bromomethyl)-2,5-bis(hexadecyloxy)benzene (3 g, 4.03 x 10-3 mol) and sodium azide (0.78 g, 0.012 mol) were stirred with dimethyl sulfoxide (120 mL) under nitrogen for 12 h. The solution was dropped into iced water (150 mL), and the product recovered with diethyl ether (100 mL). Purification was performed by twice washing the product with brine, recovering with diethyl ether, drying over MgSO4 and then evaporation of the solvents under air. The yield of a creamy-white powder (1.4 g, 52 %). 1H NMR (400 MHz, CDCl3) δ 0.91 (t, J = 6 Hz, 6H, -CH3), 1.30 (m, 56H, -CH2-), 1.82 (t, J = 6 Hz, 4H, -CH2-), 4.00 (s, 4H, -CH2-N3), 4.55 (s, 2H, -aromatic). Poly(aziridinofullerene) synthesis In this synthesis a novel route for polymerization has been stablished, based os the mechanism of the cycloaddition of azidoalkyls to C60, which is well understood (CASES, 2000). 55 Figure 9: Poly(aziridinofullerene) synthesis. Synthesis of PAF1 Thoroughly nitrogen flushed 1,2-dichlorobenzene (1,2-DCB, 80 mL) and C60 (1.0 g, 1.38 x 10-3 mol) were stirred under dry N2 for 30 min at room temperature prior to the addition of the comonomer 8, 1,4-bis(azidomethyl)-2,5-bis(octyloxy)benzene (0.613 g, 1.38 x 10-3 mol), and a subsequent heating at 60 ˚C for 24 h. The solution was stirred for a further 2 h at 100 ˚C. The product was recovered by precipitation in methanol (500 mL), using toluene (5 mL) to add transfer. Soxhlet cycled washing over periods of 12 h and 3 days with, respectively, methanol and hexane, followed by drying under reduced pressure at 100 ˚C resulted in 0.92 g (yield, 56 %) of a black powder. 1H NMR (400.6 MHz, C6D6) δ = 6.95 (broad, -aromatic), 6.3 (d, J = 220 Hz, -CH2-N=), 5.3 (broad, -CH2-N3), 4.2 (broad, -OCH2-), 2.8, 1.6 and 1.3 (broad peaks, -CH2-), 0.93 (broad, -CH3). 56 Synthesis of PAF2 Degassed 1,2-dichlorobenzene (1,2-DCB, 80 mL) and C60 (1.38 x 10-3 mol, 1 g) were stirred under dry N2 for 30 min at room temperature prior to the addition of the comonomer 9, 1,4-bis(azidomethyl)-2,5-bis(dodecyloxy)benzene (1.38 x 10-3 mol, 0.768 g), and a subsequent heating to 60 ˚C for 24 h. The solution was stirred for 2 h at 100 ˚C. Toluene (5 mL) was added, and the product recovered from precipitation in methanol. Soxhlet cycled washing over periods of 12 h and 3 days with, respectively, methanol and hexane, followed by drying under reduced pressure at 100 ˚C resulted in 1.24 g (yield, 68 %) of a brownish powder. 1H NMR (400.6 MHz, C6D6) δ = 6.95 (broad, -aromatic), 6.3 (d, J = 220 Hz, -CH2-N=), 5.3 (broad, -CH2-N3), 4.2 (broad, -OCH2-), 2.8, 1.6 and 1.3 (broad peaks, -CH2-), 0.93 (broad, -CH3). Synthesis of PAF3 Degassed o-DCB (80 mL) and C60 (1.38 x 10-3 mol, 1 g) were stirred under dry N2 for 30 min at room temperature prior to the addition of the comonomer 10, 1,4-bis(azidomethyl)- 2,5-bis(hexadecyloxy)benzene (1.38 x 10 -3 mol, 0.929 g), and a subsequent heating to 60 ˚C for 24 h. The solution was stirred for 2 h at 100 ˚C. Toluene (5 mL) was added, and the product recovered from precipitation in methanol. Soxhlet cycled washing over periods of 12 h and 3 days with, respectively, methanol and hexane, followed by drying under reduced pressure at 100 ˚C resulted in 1.22 g (yield, 63 %) of a brownish powder. Soxhlet cycled washing over periods of 12 h and 3 days with, respectively, methanol and hexane, followed by drying under reduced pressure at 100 ˚C resulted in 1.24 g (yield, 68 %) of a brownish powder. 1H NMR (400.6 MHz, C6D6) δ = 6.95 (broad, -aromatic), 6.3 (d, J = 116 Hz, -CH2- N=), 5.8 (broad, -CH2-N3), 4.1 (broad, -OCH2-), 2.9, 2.7 and 2.3 (broad peaks, -CH2-), 0.89 (broad, -CH3). 57 Device Fabrication (Made by Christine Luscombe’s group UW – USA). Bulk heterojunction organic solar cells were fabricated using glass coated with ITO as transparent substrate. The substrates were cleaned by consecutive sonication in detergent, acetone and isopropyl alcohol in an ultrasonic bath (VWR Model 50T), followed by UV-ozone cleaning (PDC 32G) for 10 min in order to prepare the surface for PEDOT:PSS deposition. PEDOT:PSS (poly(3,4-ethylenedioxythiophene) polystyrene sulfonate - Heraeus Clevios P VP Al4083, 40 nm thickness) was spin-coated onto the clean substrate surface, followed by 10 min of annealing in air at 140 ºC to remove remaining water. The samples were cooled to room temperature and transferred into a N2-filled glovebox. P3HT (Rieke 4002-E)/PCBM (American Dye Source), P3HT/PAF1 or P3HT/PAF2 (1:0.6 wt%/wt%) solutions in anhydrous chorobenzene (CB) (40 mg/mL) were prepared, heated at 60 ºC and stirred overnight inside the glove box. Prior to deposition, the solutions were filtered through a 0.2 m filter. The photovoltaic active materials were then spin-coated on top of the PEDOT:PSS layer to produce an active layer of 100 nm, followed by annealing at 130 ºC for 10 min. The aluminium cathode (100 nm thick) was thermally evaporated through a shadow mask under high vacuum about 4.010-7 torr. Solar characterization of the devices was done in N2 ambient, using a Keithley 2400 source meter unit and an Oriel Xenon Lamp (450 W) coupled with an AM1.5 filter (Air Mass 1.5, 1.5 atmosphere thickness, corresponds to a solar zenith angle of z=48.2°) as a light source and a light intensity of 100 mWcm-2 was used in all the measurements. Devices parameters were tested for at least 16 devices for each sample. 2.1.2 Inorganic oxide Titanium tetraisopropoxide (TTIP) (Alfa-Aesar 97%), HNO3 (Dinâmica) and NaOH (Synth) were used as received. For the acidic synthesis, 12 mL (0.4 mol) of TTIP was added 58 dropwise in 100 mL of water with 0.5 mL of HNO3, 0.01 M (DAR 2014). For the alkalyne synthesis, 12 mL (0.4 mol) of TTIP was added dropwise in NaOH solutions with different concentrations: 0.1, 1 and 10 M. In both cases, the precursor solution was stirred for 6 h at 80 °C. The solution was placed into a Teflon autoclave for the microwave treatment. A modified domestic microwave (Panasonic Piccolo 800 W) coupled with an external temperature controller (Incon CNT120) was used. The synthesis temperature varied from 110 to 150 °C and time from 2 to 60 min. After the microwave treatment, the colloidal solution was washed with water. The solutions were centrifuged at 2500 rpm for 5 min and dried in an oven at 60 °C. The samples were named as follow: a prefix HM (for the acidic media) or HMB (for the alkaline media), followed by the temperature and time of treatment. The concentration of NaOH is presented after the time. The sample HM150-30-10 was washed with HCl 0.1 M in order to remove the excessive Na+ ions (KASUGA, 1998). Details about the synthesis parameters used are presented in the Table 7. 2.1.3 Hybrid nanoparticles Grafting triethoxysilane-terminated P3HT onto oxide nanoparticles The anatase TiO2 nanoparticles used was HM150-30. The Nb2O5 nanoparticles were synthesized by microwave assisted hydrothermal technique. It was used niobium (V) oxide as precursor in acidic media at 150 ºC in 60 min. Functionalized P3HT with the triethoxysilane group was synthesized as previously described by Awada et al. (AWADA, 2014) and presented at Scheme 10. For the graft reaction, the nanoparticles where separately dispersed in THF (2 mg/mL) by ultrassonication during 1 h. The solution of triethoxysilane-P3HT (20 mg/mL) in THF was added to the mixture. 59 Scheme 10: Synthesis of functionalized P3HT and graft reaction. From: Adapted from Awada et al. (AWADA, 2014) The unreacted chains were removed at the end of the reaction by solubilization and washing. The reaction was then preceded at 60 °C for 12 h under inert atmosphere. The medium was cooled to room temperature and the grafted nanoparticles were purified by centrifugation (10.000 rpm, 10 min) with removal of the supernatant containing excess of organic component. The precipitated particles were collected, dried, and stored under nitrogen. A change in the color of the nanoparticles was clearly observable from white to violet after grafting (anchoring the polymer on the oxide) for the TiO2 and from white to orange to Nb2O5 (solid state) probably due its different surface area. 60 2.2 Characterization Techniques 2.2.1 X ray diffratometry (XRD) X rays are electromagnetic radiations that have higher energies and shorter wavelengths. When a beam of X-ray focuses on a solid material, a fraction of this beam is scattered in various directions by electrons associated with each atom or ion (CALLISTER, 1994). Considering two parallel planes of atoms which have the same Miller index h, k and l which are separated by a dhkl interplanar spacing and assuming a beam of X-rays parallel monochromatic and coherent (in phase), with wavelength  focusing on these two planes, according to an angle , the condition for diffraction is defined by Equation (1), known as the Bragg’s Law, where n rep