Giovanna Pellegrino*a,
Sabrina Carola Carroccioab,
Francesco Ruffinoac,
Guglielmo G. Condorellid,
Giuseppe Nicotrae,
Vittorio Priviteraa and
Giuliana Impellizzeria
aCNR-IMM, Via S. Sofia 64, 95123 Catania, Italy. E-mail: giovanna.pellegrino@imm.cnr.it
bCNR-IPCB, Via P. Gaifami 18, 95126 Catania, Italy
cDipartimento di Fisica e Astronomia, Università di Catania, Via S. Sofia 64, 95123 Catania, Italy
dDipartimento di Scienze Chimiche, Università degli Studi di Catania and INSTM UdR Catania, V.le A. Doria 6, 95125 Catania, Italy
eCNR-IMM, Z.I. VIII Strada 5, 95121 Catania, Italy
First published on 2nd January 2018
The synthesis of hybrid nano-composites in which an inorganic layer is grown on a polymeric surface via chemical bonds, is a challenging goal for many applications from photocatalysis, to sensing and optoelectronics. Herein, we describe on the growth of ZnO nanostructures by an Atomic Layer Deposition (ALD) technique on polyetherimide (poly(2,2′-bis(3,4-dicarboxyphenoxy)phenylpropane)-2-phenylendiimide ULTEM® 1000) substrates. A surface modification consisting of a thermal photo-oxidization process, applied for different exposure times, has been properly performed on the polymer to promote the production of ALD suitable functionalities as reactive surface-sites. The chemical anchoring of the inorganic species from the gas-phase is demonstrated by spectroscopy and mass analyses to exclusively occur on the pre-oxidized films, whilst the ZnO growth does not occur in the untreated ULTEM® films in the operative ALD conditions. Notably, we demonstrate that two different regimes of growth take place in the oxidized polymer as a function of the photo-exposure time. In particular, the formation of a nanostructured coating of ZnO on the polyetherimide surface is found in the case of short-time photo-exposed polyetherimide (ALD-like regime), whilst an intermixed organic/polymer layer is found on the long-time oxidized films (Vapor Phase Infiltration, VPI-like regime). The photocatalytic activity of the synthesized materials has been tested through the degradation of methylene blue dye in aqueous solution under UV light irradiation, to give a proof of concept of a possible application of the nano-composites.
The huge technological progress registered in the last decade is mainly due to the capability of manipulating the materials at the nanoscale level and realizing functional nano-sized smart systems, having activities and properties deeply different from their bulk counterparts.
The advanced methods of manufacturing has allowed the development of nano-engineering, as robust and powerful tool for the fabrication of low-dimensional materials, previously inaccessible due to physical restrictions. Over the conventional methods, Atomic Layer Deposition (ALD) represents an ideal instrument, which permits the realization of materials with atomic scaling precision, thus guaranteeing a strict control of the structural and chemical properties of the final objects.15–20 The high quality of the ALD materials originate from the peculiar growth mechanism based on selective and self-limiting reactions between the ALD gaseous precursors and the reactive groups exposed at surface of the substrate.21–24 The growth of the material on the substrate is controlled at the atomic scale, uniformly and conformably on large areas.
In addition, compared with other deposition methods, (e.g. Chemical Vapor Deposition (CVD) and sputtering), ALD is performed under much milder conditions of pressure and temperature, and in absence of molecular-level bombardment, thus being compatible with the use of substrates sensitive both to the thermal and mechanical stress, as in the case of polymeric materials.17,25,26
In this respect, the realization of novel inorganic/polymeric hybrid materials by ALD is appealing, being beneficial in a variety of applications including photocatalysis, sensing, energy harvesting and storage, and optoelectronics. Indeed, hybrid systems can combine the structural properties and functionalities of the two organic and inorganic components, which are unattainable from the use of the single phases.27 The ability to control the reaction between the ALD precursors and polymers opens new opportunities in materials processing.28,29 For instance, the flexibility, transparency, lightness, and low costs typical of the plastic substrates can suitably encounter the photocatalytic, optical, and electronic functions of the metal oxides. Nevertheless, due to the severe chemical and physical differences between polymeric and inorganic components, the design of the ALD synthesis of a hybrid organic/inorganic material represents a significant challenge.17,30
It is well known, for instance, that ALD on many polymers can involve subsurface precursor diffusion and reaction, which are not encountered during ALD on inorganic surfaces.19 The mechanism of diffusion of the precursors into the film depends on the organic and structural nature (e.g. topology, composition, molar masses) of the macromolecular materials.31 Vapor phase infiltration (VPI) is an emerging gas phase processing for transforming polymers into organic–inorganic hybrid materials based on the metalorganic precursors diffusion and subsequently reactions with the organic polymers. Such processing technique originates from the atomic layer deposition (ALD) research community, and its processing conditions are similar to ALD, nevertheless, the fundamental phenomenological mechanisms of VPI and ALD are significantly different.32
For highly reactive polymers to the ALD precursors, the reaction rate between the precursors and the surface is fast so that the inorganic phase rapidly nucleates on the surface of the polymer with the consequent formation of a conformal inorganic coating on the surface of the polymer. On polymers such as PVA or cellulose where there is a large density of reactive groups, the ALD reaction can be limited to the top surface of the polymer.19,29
In the case of the unreactive polymers towards the ALD reagents, no growth of the inorganic layer is observed for short times of depositions (few ALD cycles). The formation of the inorganic phase occurs, instead, for higher times of deposition with the precursors that can diffuse into the polymer and react within the film, resulting in an inorganic phase embedded in the organic bulk.33–37 It has been shown that under VPI conditions, no covalent reactions can occur between the precursors and the polymer matrix.38,39 Thus, the weak interaction occurring at the interface between the two components in such organic/inorganic bi-phase, results unattractive for applications, especially in the field of heterogeneous photocatalysis for water purification, wherein the photoactive structures could be easily dispersed in solution.
In order to obtain an appealing system, flexible and functional, it is necessary immobilizing the inorganic photocatalysts by stable chemical bonds on the substrate, to guarantee structural stability and prevent their dispersion in the surrounding media. With this purpose, we properly designed the growth of ZnO nano-structures on a surface-modified polymeric substrate. As substrate was selected the poly(2,2′-bis(3,4-dicarboxyphenoxy)phenylpropane)-2-phenylendiimide ULTEM® 1000 (hereafter simply called ULTEM®), an engineering thermoplastic material with superior durability properties, high modulus, toughness, and chemical resistance. Furthermore, due to its amorphous nature, transparent ULTEM® resin balances both mechanical properties and processability.
The molecular structure of polyimide is the responsible of the high mechanical performance of the ULTEM® resin, but at the same time, it results unsuitable for the ALD grafting reactions, due to the lack of reactive functionalities. In some previous works, the thermal and photo-oxidation reaction pathways of this polymer, thanks to UV light irradiation, were clarified by using Matrix Assisted Laser Desorption Ionization-Time Of Flight (MALDI-TOF) mass spectrometry.40–43 A detailed map of the photo-cleavage mechanisms of polyetherimide ULTEM® was depicted for different time of exposure, permitting us to discriminate among the reaction products of interest. Crucial, in view of the ALD, is the formation of –OH and –COOH groups along the repeat units of the polymer. The presence of such reactive chemical groups could permit a direct growth of the ZnO nanostructures by exploiting chemical bonds at the organic–inorganic interface. In this paper, we originally exploit the formation of reactive functionalities in the polyetherimide to graft the inorganic precursors in the ALD regime, with the formation of the inorganic phase. We show that the assembly of the inorganic phase upon the polymer is addressed by the entity of the oxidative pre-treatment (duration). In fact, different ZnO/polymer hybrid habits are achieved depending on the number and availability of the functional groups in the polymer, these being strongly related to the chemical and structural modification of the macromolecular network during the photo-oxidation treatment.
Fig. 1 (a) Contact angle and (b) FTIR-ATR of the ∼100 μm-thick ULTEM® films as a function of the thermal photo-exposure duration. |
As can be observed from Fig. 1a, the value of contact angle measured in the case of the original ULTEM® film results 83° ± 2°, a value in line with the data reported in literature for poly-ether-imides.44 A gradual diminution of the contact angle is observed by increasing the photo-exposure time, thus indicating, consistently with the mass spectrometry results reported in the literature,41,42 the progressive formation of hydrophilic functionalities on the polymeric surface. MALDI analyses demonstrated, in fact, the formation of oxidized species such as alcoholic and acids moieties resulting from the oxidative procedure.40–42
Fig. 1b shows the evolution of the FTIR-ATR spectra in the diagnostic range between 2000 and 1500 cm−1 as a function of the duration of the photo-exposure. As can be seen from the figure, the FTIR-ATR spectrum of the original polymer shows the characteristic vibrational peaks due to the imides CO double bond. In particular, the contribution positioned at 1776 cm−1 is related to the CO asymmetric stretch, whilst the second band lying at 1720 cm−1 is due to the CO symmetric stretch.45
As can be noticed, the employ of the photo-oxidation procedure on ULTEM®, produces an enlargement of the spectral IR contribution at ∼1700 cm−1. The variation is slightly visible at short time of photo-oxidation (e.g. 3 h and 8 h), becoming remarkable over 24 h. The broadening of the band at ∼1700 cm−1 has been ascribed to the formation of –COOH species, in strict correspondence with the mass spectrometry data.38–40
The presence of reactive chemical functionalities on the polymer surface is a fundamental requirement to graft metal species;46,47 we exploit such characteristic by growing ZnO by ALD on ULTEM®, focusing on the reactivity of the different photo-oxidized samples.
AFM analyses were performed on all the different films, before and after the ZnO deposition, with the aim of examining their morphology. Fig. 2a shows a 2 μm × 2 μm AFM image related to the original ULTEM® substrate before the ALD process. Before the ZnO deposition, the ULTEM® substrates, both the original and the photo-oxidized films reveal very low values of Root Mean Square (RMS), all included in the range between 0.3 and 0.7 nm and an average height in the range between 2 and 5 nm (see Fig. 2b, related to the 24 h-photo-oxidized ULTEM sample in comparison with the original ULTEM of Fig. 2a).
After the ZnO deposition, the AFM image of the untreated sample shows the presence of few distinct features standing on the surface and having an average height of 18.3 nm (Fig. 2c). Such nanostructures are rarefied on the surface, showing a reciprocal distance of the order of ∼1–2 microns. The surface area surrounding such nanodomains presents a very low RMS value of ∼0.5 nm, comparable to that found in the case of the ULTEM® films before the ZnO deposition.
Differently, the AFM image related to the 3 h-photo-oxidized samples after the ZnO process (Fig. 2d), reveals the presence of nano-sized domains, which form a granular layer. The statistics on morphological parameters reveals a peak-to-peak (i.e. the highest probed height difference by the AFM tip) of ∼17.3 nm, comparable to that of Fig. 2c and an increased value of RMS to 1.7 nm. The AFM image related to the 8 h-oxidized film (Fig. 2e) shows values of peak-to-peak (∼17.7 nm) and RMS (1.8 nm) very close to those found in the AFM image of Fig. 2d. The formation of ZnO nano-sized structures is supported by Transmission Electron Microscopy (TEM) analyses (see Fig. 2e-1). The TEM image clearly shows the presence of ZnO nanostructures regularly distributed on the surface. On the basis of the AFM analyses, the surface density of the nanostructures appears increased with respect to the 3 h-sample, plausibly due to the increased number of ALD active functionalities on the surface, similarly to what found by Lee et al. by modulating the –OH/–CH3 ratio in self-assembled monolayer on silicon.48
The AFM images related to the 24- and 48-treated samples show the formation of nano-granular films with values of peak-to-peak and RMS significantly decreased if compared to the two previous cases. Surprisingly, in fact, the morphological parameters result of 5–7 nm and ∼0.5 nm (see Fig. 2f and g, respectively). The differences observed on the ZnO layers grown on long time-if compared to the short time-treated substrates, can arise from the alteration of the polymer structure induced by the prolonged photo-exposure time. Indeed, a modification of the mechanical and esthetic properties of ULTEM® when long photo-exposure is applied has been reported in literature, associated to the decrease of the average molar masses distribution within the polymer.40
In order to have a deeper comprehension of the phenomena occurring between the polymer and the inorganic precursors upon the ZnO deposition, we performed studies on the chemical composition of the ZnO/polymer interface by spectroscopic analyses.
After the ZnO deposition, FT-IR ATR measurements reveal diagnostic changes in the region associated to the CO functionalities (1600–1700 cm−1), with the decrease of the –COOH group in favor of the –COO− at 1600 cm−1 (see Fig. E1, ESI†), thus indicating the coordination of the metal species at the surface. As can be seen in Fig. E1,† an evident spectral variation is observed in the case of 48 h-treated sample, likely due to the higher amount of reactive terminations involved; on the other hand no significant differences are revealed in the spectrum of the original ULTEM® (Fig. E1a†), as expected. From the comparison of the spectra collected, however, no specific indications from FTIR findings can justify the morphological differences found by AFM in the short and long-time treated samples. With the aim of better understanding the data, XPS analyses were performed.
Table 1 reports the atomic percentages of the elements as detected from the spectra of: original, 8 h and 48 h, before and after the ALD process. In the case of the original ULTEM®, the percentages found by XPS are in line with the theoretical values expected for this polymer (C 82.2%, O 13.3%, and N 4.3%).49 The 8 h-photo-oxidized ULTEM® film does not show any appreciable variation in the atomic percentage values (in the range of the XPS uncertainty) whilst, in the case of the 48 h-treated sample, an increase of the oxygen relative atomic percentage is found, because of formation of oxidized species, a discussed in literature.38–40
Original | 8 h | 48 h | ||||
---|---|---|---|---|---|---|
Before ALD | After ALD | Before ALD | After ALD | Before ALD | After ALD | |
C (%) | 80.0 | 83.8 | 80.2 | 68.4 | 63.3 | 58.7 |
O (%) | 14.9 | 11.4 | 14.9 | 24.7 | 30.6 | 32.8 |
N (%) | 5.1 | 4.6 | 4.8 | <0.5 | 6.0 | 1.6 |
Zn (%) | — | <0.2 | — | 6.5 | — | 6.8 |
With the aim of deeper analyzing the chemical structure of the polyetherimide macromolecules as a function of the photo-oxidation time, we collected high resolution spectra in the regions of interest: C 1s, O 1s, N 1s and Zn 2p, the latter after the ZnO deposition. The diagnostic C 1s and O 1s XPS regions are shown in the following, whilst N1 s and Zn 2p are reported in the ESI (Fig. E2†).
Fig. 3a shows the high resolution C 1s XPS region of the untreated ULTEM® film showing the characteristic components at 285.0 eV (due to the C–C, CC and C–H species), a shoulder at 286.4 eV (due to the ether groups), and a distinct band at 288.8 eV (imide groups). The presence of the shake up band at higher binding energy (BE) values (∼292 eV) is also visible in the spectrum, due to the π → π* transition.45
Fig. 3 XPS spectra in the C 1s region related to (a), (d) untreated, (b), (e) 8 h- and (c), (f), 48 h-ULTEM® films, respectively before (top panel) and after (bottom panel) the ZnO ALD deposition. |
Fig. 3b relates to the 8 h-treated polymer. As can be seen, small differences emerge from the comparison with Fig. 3a, consisting in a slight enlargement of the bandwidths (1.5 vs. 1.6 eV) and in a slight increase of the intensity (∼10%) of both the components at ∼286.4 and ∼288.8 eV with respect to that at 285.0 eV. Such spectral variations are compatible with the formation of some C–OH/COOH species50,51 with the photo-exposure.
The C 1s region related to the 48 h-treated sample (Fig. 3c), shows a marked modification of the functional groups of the polymer if compared to the original film. The components associated to the oxidized species (i.e. C–OH at ∼287 eV and –COOH ∼289 eV), severely increased with respect to the main C–C/CC/CH contribution, consistently with the increase of the oxygen percentage in the overall spectrum (see Table 1) and with the reduction of the contact angles values due to the formation of hydrophilic functionalities, as visible in Fig. 1a. In addition, the C 1s signal can be fitted by further enlarging the FWHM of the components (1.75 eV), thus suggesting a certain chemical heterogeneity of the carbon species which constitute the organic chains, due to the formation of the C–OH and –COOH functionalities. The XPS spectra related to the O 1s region are reported in Fig. 4. In the case of the original ULTEM® film (Fig. 4a), according to the molecular structure of the polyetherimide, the O 1s XPS region shows a signal consisting of two components which are due, respectively, to the oxygen species of the imide (532.2 eV) and to the ether (533.7 eV) functionalities,45 both with a FWHM of 1.5 eV.
Fig. 4 XPS spectra in the O 1s region related to (a), (d) untreated, (b), (e) 8 h-and (c), (f), 48 h-ULTEM® films, respectively before (top panel) and after (bottom panel) the ZnO ALD deposition. |
After the 8 hours of photo-exposure treatment, an enlargement of the bandwidths of both the components (1.7 vs. 1.5 eV) and an increase of the intensity of the band at ∼533.7 eV is observed in the spectrum (Fig. 4b) which can be associated to the presence of carboxylic functionalities.52 The O 1s region of the long-time treated polymer (48 h, Fig. 4c), shows similarities with that of the 8 h-treated sample, evidencing the same FWHM (1.7 eV) and similar ratio between the two components. Such spectroscopic findings suggest scarce differences between the typologies of oxygen present on the surface of the 8 h- and 48 h-treated samples.
The modification of the C 1s and O 1s spectral features, after the ZnO deposition by the ALD process, are shown in the bottom panels of Fig. 3 and 4, respectively. As expected, no differences emerge by comparing the C 1s spectra of the original ULTEM® film before and after the ZnO deposition (see Fig. 3a and d) since the negligible amount of ZnO present on the surface (see the Zn atomic percentage in Table 1 and the Zn 2p region in Fig. E2 in ESI†).
In the C 1s spectrum related to the 8 h-treated sample (Fig. 3e), the increase of the component at 285.0 eV with respect to the other two bands positioned slightly shifted at 287.0 eV and ∼289.1 eV, is observed, in comparison with the unprocessed sample (Fig. 3b). This finding can originate from the decrease of the carboxylic and alcoholic functionalities due to the formation of the C–O–Zn groups at the surface.53 In addition, the occurrence of a very small band at 283.6 eV is found in the spectrum after the deposition.
Differently, in the case of the 48 h-treated sample, after the ZnO deposition, no significant changes are observed in the intensity ratio between the component at 285.0 and the other two at bands, which result also in this case at 287.0 eV and ∼289.1 eV (Fig. 3f). In addition, the presence of the band at 283.6 eV, becomes more visible. The position of the band at such low value of binding energy suggests the presence of the C–Zn bond, as discussed by Gregorczyk and co-workers.53 The authors attributed such contribution to the presence of partially reacted DEZ species. The differences emerging from the comparison of the C 1s spectra, suggest different scenarios in the untreated, 8 h and 48 h-treated samples. Further information is gained from the analysis of the O 1s spectral features.
For what concerns the original sample, after the ALD deposition, the O 1s spectrum shows the presence of a very low intense band located at ∼530.6 eV, compatible with the presence of the oxygen bonded to metal (Fig. 4d).54 The low intensity of the band is compatible with the amount of zinc revealed by XPS which is just below the 0.2% (see Table 1, Fig. E2 in the ESI†). Indeed, the presence of a small number of ZnO nano-columns on the surface of the original ULTEM® is observed in the AFM image (see Fig. 2c). The formation of such nanostructures can be ascribed to the negligible amount of reactive functionalities on the ULTEM® surface, likely due to macromolecules having phthalic anhydrides as terminal group that can hydrolyze upon the effect of water during the ALD process.
For what concerns the 8 h-treated sample after the ALD deposition (Fig. 4e), the O 1s XPS spectrum reveals the presence of an intense contribution at 530.6 eV, as a clear indication of the presence of ZnO at the surface. In addition, as can be seen from the figure, the contribution at higher binding energy (–COOH/–OH) is reduced as a consequence of the surface reaction between ZnO and the carboxylic groups. In the spectrum of the 48 h-treated sample, the spectral contribution at 530.6 eV, associated to the Zn–O bond, is still present, but its relative intensity with respect to the other components is decreased in comparison with the case of 8 h-treated sample. Although, the O 1s XPS signals related to the 8 h and 48 h-treated unprocessed samples appear similar (see Fig. 4b and c), after the ZnO deposition, notable differences emerge, mostly related to the weight of the Zn–O component in the O 1s spectrum (see Fig. 4e and f).
The quantitative data in Table 1 further unveil dissimilarities between the 8 h and 48 h-samples before and after the ALD process. It is to be noticed, in fact, that, after the ZnO deposition, the oxygen percentage found in the spectrum of the 8 h-treated sample almost doubles, where just a small increment is seen in the 48 h-treated case. Correspondingly, the percentages of the elements characterizing the polymeric substrate (C 1s and N 1s) significantly decrease in the 8 h-treated sample likely due to the growth of an overlayer of ZnO on the polymer surface. Different is the case of the 48 h-treated sample where, the variation of the elemental percentage before and after the deposition process is less relevant, thus suggesting that the zinc is englobed into the organic bulk.31,33,34 This can affect the surface morphology of the hybrid samples, as revealed by AFM.
By summarizing, XPS analyses indicated that the chemically inert untreated polymer remains practically unaltered under the ALD operative conditions used, whilst the anchoring of the ALD precursor occurs selectively on the photo-oxidized samples thanks to the presence of reactive organic functionalities, such as –OH and COOH. Nevertheless, the present results clearly indicate the formation of the inorganic phase, not only due to the occurrence of the ALD surface reactions. Concurrently, other events, especially in the case of the 48 h treated sample, can take place. Phenomena of gas penetration and diffusion between the polymer chains of the degraded 48 h-treated sample occur, followed by subsurface reactions. This could explain the differences in the qualitative and quantitative XPS data shown in the work (see XPS spectra and table), between the slight surface-modified and the deeply modified ULTEM® films and, also, the differences observed in the surface morphological parameters (Fig. 2). In the first case (8 h) an inorganic nanostructured overlayer is formed on the surface, whilst in the second case (48 h), a hybrid intermixing of Zn–O and polymer is formed. In this respect, the band at 283.6 eV observed in the XPS C 1s region, suggests the presence of the C–Zn-bond, as an indication of partially reacted Zn-precursor present in the material. As can be seen, such contribution is negligible in the spectrum of the 8 h-treated sample (Fig. 3e) in comparison with that of the 48 h-treated sample (Fig. 3f). The altered structural properties of the polymer as a consequent of the long photo-oxidation process (density, flexibility, oligomers with short length), can facilitate the gas permeability and diffusion within the macromolecules, thus favoring the occurrence of uncompleted sub-reactions.
This idea is further confirmed by mass analyses. MALDI spectra of the ULTEM® film, as received and after photo-oxidation, have been previously reported.40–42 Here, for brevity of discussion, we present only the expanded portions of the MALDI spectra in the range of mass (m/z) 1336–1640, related to the 8 h-oxidized ULTEM® film before (Fig. 5a) and after the ZnO deposition (Fig. 5b). The sequel reports also the spectrum of the 48 h-sample after the ALD process (Fig. 5c).
As visible in Fig. 5a, the MALDI spectrum of the 8 h oxidized – sample (∼100 μm-thick) shows the peaks due to both the oligomers from the bulk (e.g. m/z 1355.94, m/z 1368.97, m/z 1576.11) and from the oxidized topmost part of the polymer (m/z 1384.95, m/z 1592.08 and m/z 1608.08).40–42
From the comparison between this spectrum with those of the 8 h- and 48 h-treated samples after the ALD process (Fig. 5b and c), we notice the presence of an increased number of peaks in the mass scale, which indicates the formation of new species. In particular, the peak at m/z 1466.00, is reasonable assigned to the structure containing the ethyl zinc-moiety bonded to phthalic-acetate terminal group of the polymer (see the structure in Fig. 5). As can be seen, in line with the increment of the C–Zn band at 283.6 eV observed by XPS, the relative abundance of that peak in the mass spectrum of the 48 h-sample, is higher if compared to that of the 8 h-sample, plausibly due to the higher amount of suitable functionalities in the sample (FT-IR results). Based on the presented results, the idea is that in the case of 8 h-treated sample, the formation of the inorganic phase is predominantly due to surface reactions between the oxidized polymer at the topmost part of the film and the ALD precursors (ALD-like regime). Then, the underneath portion of the polymer acts as a barrier to the gas infiltration, according to the inert response of the untreated sample under the used ALD conditions. On the contrary, in the case of 48 h-treated sample, the polymer presented a significant decrement of molar masses40 that increased the free volume between the photo-degraded macromolecules.55–57 This would favor the infiltration and diffusion of the ALD reactive gas and the occurrence of sub-reactions with the accessible reactive functionalities. This mechanism has something similar to the growth of the inorganic structure embedded in the reactive polymer by infiltration (VPI-like regime).49 This could also explain the different morphological parameters found by AFM analyses in the polymeric platforms after the ZnO deposition (Fig. 2), with both the values of RMS and peak-to-peak higher in the cases of 3 h and 8 h-treated samples, with respect to the 24 h and 48 h-cases.
According to the Langmuir–Hinshelwood model, we evaluated the photocatalytic reaction rate, k, given by the following equation: ln(C/C0) = −kt, where C is the concentration of the MB, C0 the starting concentration of the MB, and t the time.58
The values of the reaction rate k reported in the ordinate axis are normalized to the k value found in the absence of any catalyst materials (k/kMB). Fig. 6 reports the photocatalytic results after four hours of irradiation for all the investigated samples. As can be seen, the MB, the ULTEM® substrate and the untreated ULTEM® plus the ZnO deposition do not show any photo-catalytic activities, as expected.
The best photo-activity response is displayed in the case of ZnO deposited on the 8 h-treated polymer. In this case, in fact, a nanostructured ZnO layer has been seen to grow over the surface of the polymer. On the other hand, a significant drop of the photocatalytic efficiency is registered in the cases of long-time treated samples. This is reasonably due to the presence of ineffective ZnO phase infiltrated into the polymer matrix or the possible release of low masses compounds from the degraded polymer, which might be competitive to MB during the photo-degradation processes.
In Fig. 7 is reported a sequel of diagnostic parameters as a function of the exposure time (a–d) and compared to the related photo-catalytic activity (e). As suitably displayed, photo-catalytic performance shows a non-linear trend with the contact angle measures and the COOH XPS amount (a, b), reaching the maximum in correspondence of 8 h, where the highest amount of ZnO nanostructures is accomplished (c, d).
Fig. 7 (a) Contact angle; (b) XPS COOH%; (c) O 1s at 530.6 XPS%; (d) RMS and (e) photocatalytic rate as a function of the photo-exposure time. |
Footnote |
† Electronic supplementary information (ESI) available: Fig. E1 – FTIR-ATR spectra related to the untreated, 8 h- and 48 h-treated ULTEM® films before and after ZnO ALD deposition. Fig. E2 – XPS spectra related to the N 1s and Zn 2p regions of untreated, 8 h- and 48 h-treated ULTEM® films after ZnO ALD deposition. See DOI: 10.1039/c7ra11168a |
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