1. Introduction
Among polymeric materials, typically insulators, the group of conjugated heterocyclic polymers have relatively high electrical conductivity. This is the case of polythiophene (PTh), which has been used in solar cells and sensors since 1982, however its irregular efficiency led to a rapid decline in this application. Now, recent studies have focused on hybrid solar cells of PTh with materials with high electrical affinity, such as TiO2 [1-3]. The studies of ultrafast and efficient photo-induced electron transfer between conjugated polymers and fullerenes have represented an important step in the revival of these organic photovoltaic devices.
A hybrid solar cell is generally formed by at least four distinct layers: an anode, an electronic-hole transport layer, an active layer and a cathode. The active layer is responsible for light absorption and diffusion of charge carriers between donors and acceptors. In a cell of PTh, the anode would be made of indium-tin oxide (ITO); the hole transport layer of a mixture of semiconductive polymers; the active layer would be formed of PTh with metallic particles; and the cathode would be a metallic conductor. Although it is known that the efficiency is higher with crystalline donors and acceptors [4], it has been found that non-crystalline semiconducting polymers and polymer-metal composites synthesized by plasma are very stable materials with promising electronic properties in these functions [5-7].
Considering these possibilities, the synthesis, structure, morphology and properties of plasma composites of PTh with Ti and I as active layers are studied in this work. Plasma techniques are direct methods free of solvents such as chloroform, chlorobenzene and tetrahydrofuran, commonly used in the synthesis of other hybrid solar cells based on semi-ordered polymers such as poly (3-hexyl) thiophene (P3HT). Many studies have focused on synthesizing this type of solar cells, eliminating solvents [8].
2. Methodology
The synthesis was performed in a cylindrical glass reactor of 9 cm diameter and 12 cm length. The base and work pressures were 5 × 10−2 mbar and 7 × 10−1 mbar, respectively. Two flat electrodes were used, the anode was made of stainless steel (SS) 6 cm diameter, and the cathode was made of Ti, 4 cm diameter, mounted on stainless steel bars. The separation between electrodes was 3 mm.
PTh-Ti composites were synthesized in two steps using two power sources, rf and cd, switching during the synthesis. The first step was the synthesis of PTh with a Dressler rf power generator working at 13.56 MHz and 20 W. During this step, a small amount of Ti was released from the electrodes. An Ar flow was used to moderate the flow of monomer into the reactor. To increase the metallic content, the second step was a Ti sputtering process performed with an Advanced Energy MDX magnetron drive at 1000 V with an Ar-air mixture as carrier gas. To achieve the Ti sputtering, the cathode was coupled with 0.127 mm thick Ti sharp foils. This allowed the sputtering of Ti and consequently, the synthesis of PThTi composites. To modify conductivity and hydrophilicity in the composites, PTh was synthesized adding I as a dopant in the first step, with the same metallic sputtering process in the second step. With this addition, PTh-I-Ti composites were formed.
The synthesis time was variable, for PTh, time intervals between 30 to 120 min were used, while for Ti sputtering the time intervals were between 15 to 40 min. The composites were synthesized in the same chamber, being cautious that during polymerization the monomer feed rate was slow enough to avoid that the cathode was fully covered by the polymers. In the second step, the sputtering process was carried out alternating both rf and cd magnetron drives. Adjusting the monomer feed rate to the reactor, through a needle valve; the metal-polymer ratio in the composites was controlled. The composites were formed as thin films on glass substrates placed between the electrodes. In those substrates, the composites were analyzed.
The metallic structure was studied by X-ray diffraction with a Siemens D500 diffractometer from 2˚ to 120˚ in the typical 2θ scale. The metal fraction and its distribution in the polymer matrices were studied by electron microscopy and energy dispersive spectroscopy (EDS). The contact angles between composites and distilled water were obtained with drops of 8, 12 and 16 µl at 25˚C in all cases. The dc electrical conductivity was evaluated by the two-point method at room temperature. It is important to note that this is a volumetric, not superficial, evaluation.
3. Results and Discussion
3.1. Morphology of Composites
The thickness of the films varied from approximately 1 to several micrometers, see Figure 1. During the synthesis, the monomer feed rate into the reactor had to be reduced in order to prevent that the Ti electrode become coated with the polymer, effect that would reduce the releasing of Ti particles. Consequently, as the metal quantity is increased, the composites are thinner than the polymeric layer without metal considering similar reaction time.
The morphology of PTh shows a homogeneously rough surface with several protrusions of about 1 µm on layers of approximately 5 µm, see Figure 1(a). On the contrary, the surface of PTh-Ti composites looks smooth and homogeneous, see Figure 1(b). The addition of the metallic fraction reduced almost completely the protrusions on the surface, although the thickness of the metal layer cannot be differentiated from the substrate. However, there are zones in PTh-Ti where the surfaces were heavily attacked by the energetic plasma particles, near the electrodes, which appear with some pores and slight irregularities, see Figure 1(c).
The addition of I to PTh-Ti formed PTh-I-Ti composites in which many irregularities with particles and agglomerates randomly spread appeared on the surface, see Figure 1(d). The effect of I produced the release of Fe particles from the SS electrode, and this effect modified the smooth surface of PTh-Ti to roughened surfaces in PTh-I-Ti.
3.2. Atomic Ratios
The atomic ratios are tools used to analyze the participation of thiophene molecules, metals and dopants in the composites. Table 1 summarizes the elemental content of C, S, I, Ti, O and Fe in atomic percentage of all composite combinations. C and S are part of the thiophene structure (cyclic −CH = CH-CH = CH-S-), but O is an additional oxidation in the polymers due to interaction with the atmospheric oxygen at the end of the synthesis. The participation of Ti is in the 0.34% - 3.44% interval and I content is 13.89%.
It is interesting to note that when iodine participates in the reaction Fe, 1.69%, is released from the SS electrode. With the participation of iodine, the Ti content in the composites also increases, up to 10 times. This metal sputtering of Ti and Fe can be associated with collisions
Table 1. Elemental analysis of PTh, PTh-Ti and PTh-Ti-I composites in atomic percentage.
with I ions in the plasma. The O content also reflects the iodine influence increasing the O atomic content, from 5.81% in PTh-Ti to 10.12% in PTh-I-Ti. In PTh-Ti is observed the lowest O content. Another origin of O in the composites could be in the oxygen atoms participating in both electrodes.
The increase of metal and oxygen percentages reduces the C participation on the surface with iodine. In PTh and PTh-Ti, the C content is approximately 80%, but reduces to 46.26% as a consequence of iodine. The C/S atomic ratio is 4 in thiophene and it would be approximately the same in polythiophene composites without molecular fragmentation. However, the C/S ratio obtained was different from 4, in PTh C/S = 6.27 indicating molecular fragmentation associated with the high energy of plasma particles in which some sulfur fragments did not participate in the composite, probably because they escaped from the reactor. On its part, PTh-Ti has a moderate amount of metal, with C/S smaller than PTh, 5.46, but remains high relative to C/S in thiophene. This ratio indicates smaller fragmentation than the case before. The lowest C/S ratio was found in PTh-I-Ti, 1.88, suggesting that the more metal in the composites the smaller the C/S ratio. This ratio also indicates fragmentation, but in a different way than the previous cases in which what escaped from the reactor were the carbon fragments and not the sulfur ones because of the iodine participation. It is clear that the high energy associated with the sputtering is able to fragment thiophene rings with the consequence that some of the smaller molecules are extracted from the reactor by the vacuum system.
3.3. Contact Angles
The physical and chemical composition of surfaces plays a key role in the hydrophilic behavior of materials. The forces on the surface can be modified with the addition of superficial layers of different materials. In PTh-Ti, the surface tension increases with the metallic fraction and small contact angles are observed, see Figure 2, in which regardless the synthesis conditions, the films show hydrophilic behavior with angles below 90˚.
Contact angles of all PTh composites with distilled water were calculated between 46˚ and 75˚. PTh has the greatest values, 72˚ - 75˚, associated with its rough surface. The metallic particles added to PTh greatly reduced the roughness on the surface and as a consequence, the contact angles in PTh-Ti reduced to the 62˚ - 70˚ interval. The dopant, iodine, participating in PTh-I-Ti increased the roughness on the surface with respect to PTh-Ti but unexpectedly further reduced the angles sending them to the 46˚ - 55˚ interval. This effect could be due to the hygroscopic character of I atoms inserted on the surface, which appears to have more influence than the hydrophobicity associated with the superficial roughness, see Figure 1(d).
It is worthy to note this effect, because PTh-I-Ti is an example of the great influence of chemical composition of surfaces, because although its surface is much rougher, the inclusion of iodine reduced the contact angles to the lowest values, making it the most hydrophilic composite.
3.4. Diffraction Angles
The X-ray diffraction of PTh-I-Ti composites is shown in Figure 3 and presents superposition of both phases, metallic and polymeric. Figure 3 also includes the main diffraction lines of TiO2 and Fe2O3 oxides to compare with those of the composites, because, as it was shown in
Figure 2. Contact angles of PTh composites. They are the result of their physicochemical characteristics, roughness and chemical composition of surfaces.
Figure 3. X-ray diffraction pattern of PTh-I-Ti. Well defined peaks at 31.6˚ and 66.1˚ can be observed. Dashed (in red) and dotted (in blue) lines represent the diffraction angles of Fe2O3 and TiO2 (Brookite), respectively.
Table 1, PTh-I-Ti has 3.44% of Ti and 1.69% of Fe. The diffractogram shows the prevalence of the polymeric amorphous phase upon the metal, although there are two well defined signals protruding from the amorphous level at 31.6˚ and 66.1˚ that can be associated with two diffraction angles of the TiO2 orthorhombic brookite structure [9,10]. This structure has been reported with photocatalytic activity which can be useful in the properties of PTh-Ti composites of this work. Fe2O3, on its part, do not diffract in those angles, however, the one at 24˚ is overlapped with the amorphous centroid of PTh.
These results suggest that Ti and Fe atoms arranged in a complex interaction with the polythiophene substrate. Considering that both metals start the interaction with PTh without previous combinations with C, the diffraction suggests that they form structures with C and O in contact with PTh. Periodic structures of Ti surrounded by O (O-Ti-O) planes are not discarded.
3.5. Electric Conductivity
The volumetric electric conductivity of PTh composites calculated at room temperature is summarized in Table 2. As shown, conductivity in PTh is 3.52 × 10−6 S/m and increased in PTh-Ti one order of magnitude with the metal content, 20.6 × 10−6 S/cm. However, with the inclusion of I, conductivity in PTh-I-Ti was reduced even to lower values than those of PTh, 1.8 × 10−6 S/m. This reduction can be the result of a competitive effect between I and Ti on the surface, in which both look to have opposite influence on the transference of electric charges.
The influence of metals in polymers is great in the transference of charges in volumetric polymer-metal matrices; however metals in layered polymer-metal composites do not have the same effect, because the main resistance of polymeric layers dominates the transference. In these conditions, the level of conductivity in PTh-Ti composites is between semiconductors and non-conductors, because the constant impact of energetic particles promotes branching and crosslinking in the polymeric phase reducing the movement of electric charges across PTh matrices. However, polymeric films for hybrid solar cells need photoelectric effects and a good union between polymers and metals so the charges can flow to the electrodes of the cell. This kind of union is accomplished in PTh-Ti composites.
Table 2. Electrical conductivity of PTh composites at room temperature.
4. Conclusions
Plasma PTh-Ti layered composites were synthesized by plasma to study the morphology, hydrophilicity and transference of electric charges. The syntheses were combinations of polymerization, doping and sputtering of metals. The results indicated that the high energy associated with the sputtering has the disadvantage of breaking some thiophene rings, but on the other hand it has the advantage of joining polymers and metals in hybrid composites. The metallic fraction was composed by Ti and Fe partially combined with the polymeric fraction giving 2 diffraction angles at 31.6˚ and 66.1˚ which can be associated with two diffraction angles of orthorhombic TiO2 brookite. The amorphous diffraction PTh spectrum looks overlapped with structures of Ti and possibly Fe. The metallic particles released from the electrodes may combine with the substrate in complex arrangements at the interface.
All the composites showed hydrophilic behavior with contact angles between distilled water and composites from 46.1˚ to 74.6˚. Despite the roughness, the chemical composition of surfaces played a key role in the hydrophilic behavior of materials in which the participation of iodine increased the roughness on the surface but reduced the contact angles as a consequence of its affinity with water. The transference of charges increased one order of magnitude in the composites with the metal inclusion, but reduced approximately the same magnitude with the participation of iodine atoms, both components produced opposite effects.
5. Acknowledgements
The authors acknowledge CONACYT in Mexico for the partial financial support to this work with the projects 154757 and 130190. J.C. Palacios acknowledges the financial support of PROMEP-MEXICO with the project FE032/2012-351030.
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