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Article

Hydrophobic Anti-Reflective Coating of Plasma-Enhanced Chemical Vapor Deposited Diamond-Like Carbon Thin Films with Various Thicknesses for Dye-Sensitized Solar Cells  †

1
Department of Electrical Engineering, Chosun University, Gwangju 61452, Korea
2
Department of Electronics, Chosun College of Science & Technology, Gwangju 61453, Korea
*
Author to whom correspondence should be addressed.
A preliminary version of this work is part of J.-S. Song’s Ph.D. dissertation.
These authors contributed equally to this work.
Appl. Sci. 2021, 11(1), 358; https://doi.org/10.3390/app11010358
Submission received: 7 December 2020 / Revised: 23 December 2020 / Accepted: 24 December 2020 / Published: 1 January 2021
(This article belongs to the Special Issue Advances of Diamond Carbon Coatings)

Abstract

:
Diamond-like carbon (DLC) thin films, prepared by a radio frequency plasma-enhanced chemical vapor deposition (PECVD) system, were investigated for application as an anti-reflective coating (ARC) for dye-sensitized solar cells (DSSCs) with a change in film thickness. The strength of the Raman spectrum, G-peak position, and ID/IG ratio, related to sp3 bonds in the DLC thin films, is directly attributed to some tribological properties including surface roughness, hardness, elastic modulus, friction coefficient, and contact angle. Some optical properties, such as transmittance, refractive index, and absorption coefficient, were examined after changing the thickness of DLC thin films. The optimal short-circuit current density (Jsc), open-circuit voltage (Voc), and fill factor (FF) values were obtained for the significantly improved conversion efficiency (CE) from 4.92% to 5.35% in the 60 nm thick PECVD DLC ARC for DSSCs with hard and hydrophobic surfaces.

1. Introduction

Diamond-like carbon (DLC) has been extensively studied for decades owing to its excellent properties, such as very high hardness, low friction coefficient, chemical inactivity, wear resistance, optical transparency, and biocompatibility [1]. The physical and chemical properties of DLC thin films are in a quasi-stabilized form as their characteristics can be effectively controlled under synthesis conditions, which make them useful in a wide range of applications [2]. Recent studies have further expanded the application of DLC thin films by improving biocompatibility, lubrication, stability, and cell adhesion [3,4,5,6]. They have been effectively employed for surface modification, structural bonding [7,8], surface roughing [9,10], hydrophilic/hydrophobic control [11,12], and doping of suitable elements/plasma treating [4,5,6,13]. To improve the efficiency and stability of solar cells, various studies have been conducted on the cleaning and texturing of substrates, enrichment, surface protection, and anti-reflection coatings [14,15]. While DLC thin films are applied as anti-reflective coatings (ARCs) of various solar cells based on c-Si and GaAs, dye-sensitized solar cells (DSSCs) are also expected to be useful for addressing the low energy conversion efficiency (CE) and lack of long-term stability by using the DLC ARC. In this study, a radio frequency (RF) plasma-enhanced chemical vapor deposition (PECVD) system was employed to form DLC thin films as the ARC. DLC thin films were synthesized with various thicknesses at low temperature because the use of ARC in solar cells generally reduces the permeability of incident light into solar cells, and the refractive index of the ARC must be reduced to increase the transmittance. To address these problems, it is necessary to identify optimal conditions for developing DLC ARCs in which the transmittance and refractive index are acceptable at the appropriate thicknesses. The tribological, optical, and structural characteristics of the DLC thin films were also analyzed at different thicknesses to improve the energy CE and long-term stability of DSSCs.

2. Experimental Details

The DLC thin film was deposited using a 13.56 MHz RF-PECVD system on 2 cm × 2 cm glass and silicon substrates. To decontaminate the substrates surfaces before deposition, the substrate was cleaned with ultra-sonication, acetone, methanol, and deionized water (DIW). After cleaning, the native oxide film on the substrate was removed using a hydrogen fluoride (HF) solution. The substrates were dried with N2 gas and then mounted on the holder in PECVD. To improve adhesion between the substrate and DLC thin film, pretreatment was performed in the generated plasma by infusing H2 gas of 100 sccm at an RF power of 140 W for 2 min. The reaction gas was injected with a mixture of methane (CH4) of 25 sccm and H2 of 100 sccm in a fixed condition; a base pressure of 2 × 10−3 Torr, process pressure of 1 Torr, and RF power for plasma of 120 W at room temperature. The thickness of the DLC thin films was adjusted from 20 to 100 nm with a change in the deposition time.
Structural properties of the DLC thin films were analyzed using Raman spectroscopy (Jobin Yvon, LabRamHr, excitation wavelength of 514 nm) [16], and surface characteristics were observed using field effect scanning electron microscope (FESEM, Hitachi, Tokyo, Japan, S-4700) and atomic force microscopy (AFM, Park Systems, Suwon, Korea, XE-200). Tribological characteristics including hardness and elastic modulus of the DLC thin films were examined by using a nanoindenter (MTS Systems Corp., Eden Prairie, MN, USA, Nanoindenter II) and nano scratch tester (Anton Paar GmbH, Graz, Austria, NST3). Optical properties, such as transmittance, refractive index, reflection, and absorption coefficient of DLC thin films were measured using an ultraviolet-visible spectrometer (SCINCO Co. Ltd., Seoul, Korea, S-2100) and spectroscopic ellipsometry (Horiba, Kyoto, Japan, UVISEL2).
The working electrode in a DSSC was fabricated by the doctor blade coating method using a slurry with TiO2 nanoparticles (13 nm, Solarnix SA, Aubonne, Switzerland) on fluorine-doped tin oxide (FTO, Solarnix SA, Aubonne, Switzerland, 8 Ω/sq, 130-nm thickness, 1.5 cm × 2 cm)/glass before it was sintered at 550 °C for 60 min in an active area of 0.25 cm2 to form TiO2 nanocrystalline thin films with a thickness of approximately 10 μm. RF-PECVD DLC thin films were introduced as an ARC on the upper working electrode. The working electrodes were dipped in 0.3 mM ruthenium-complexed dye (Solarnix SA, Aubonne, Switzerland, N719, cis-Bis(isothiocyanato)bis(2,2′-bipyridyl-4,4′-dicarboxylato)ruthenium(II)) as sensitizers for 24 h at room temperature. They were cleaned with ethanol and then dried with N2 gas. Counter electrode was fabricated by dropping 50-μL PtCl4 mixed with chloroplatinic acid (Sigma-Alldrich Inc., St. Louis, MO, USA) of 10 mM and isopropyl alcohol on the FTO/glass and then sintered for 20 min at 450 °C in a furnace. The dye-adsorbed TiO2 working electrodes were bonded with the counter electrodes using a 60 μm hot-melt Surlin spacer (Solaronix SA, Aubonne, Switzerland, SX 1170) at 100 °C using a hot plate. Iodolyte (Solaronix SA, Aubonne, Switzerland, AN-50), as a low-viscosity electrolyte with tri-iodide of 50 mM in acetonitrile, was injected into one of the two holes drilled into the counter electrodes, and the holes were then sealed with a cover glass and Surlin. The performance and the current–voltage characteristics of the DSSCs with different thicknesses of DLC ARC were implemented by a solar simulator (Abet Technologies Inc., Milford, CT, USA, Xe Lamps of 30 W, AM1.5).

3. Results and Discussion

The surface of the DLC thin films was evaluated to identify their tribological properties. The FESEM images of the RF-PECVD DLC thin films showed uniform and smooth surfaces in all specimens; the only significant difference was that the number of small grains tended to slightly increase as thickness increased, from which can be inferred that the density in the DLC thin films increased with growth. Figure 1 shows the root mean square (rms) surface roughness of the DLC thin films with a change in thicknesses. The three-dimensional (3D) AFM images identified a smooth and uniform surface similar to the FESEM images [3,4]. The rms surface roughness increased from 0.70 to 0.94 nm with an increase in thickness, which is believed to have been contributed by the increase in the number of small grains in the surfaces due to the increased kinetic energy of carbon and hydrogen ions in the plasma [17,18], increased bonding for thin-film growth, and increased ion collisions near the surface [19,20] with an increase in the deposition time for increasing the thickness of the DLC thin films with the fixed RF power.
Figure 2 shows the hardness, elastic modulus, and friction coefficient with changes in the thickness of the RF-PECVD DLC thin films. As the thickness of the DLC thin films increased, the hardness and elastic modulus increased, and the maximum values of the hardness and elastic modulus were approximately 14 and 210 GPa, respectively, at thickness of 100 nm. These results indicate that the increased hardness and elastic modulus of the DLC thin films make the thin films denser with increasing thickness, and the ratio of diamond-like (sp3) content to amorphous bonding (sp2) in the DLC thin films increases [21,22]. Increasing the deposition time to increase the thickness of the thin film improves the bonding ratio of carbon and hydrogen, and the increased collisions of ions in the plasma near the surface increase the density of the DLC thin films and contribute to the increase in hardness and elastic modulus [6,7]. The friction coefficient of the DLC thin films showed a tendency to decrease from 0.017 to 0.013 with an increase in thickness. Although the slightly rougher surface in the thicker thin films, as shown in the FESEM and AFM results (Figure 1), had some effect on the increase in the friction coefficient [23], the increased film density of the DLC thin film as the thickness increased reduced the friction coefficient [24], which was affected by the modification in the ratio of sp3 representing the binding of carbon and hydrogen in the thin films [6,7].
Figure 3 shows the contact angle of the DLC thin films with a change in thickness. The value of the contact angle on the surface exhibits a decreasing tendency from 86° to 84°, but it was within the scope of a small change at varying DLC thin films thicknesses. The slight decrease in contact angle might be caused by the increase in the ratio of sp3 showing hydrophilic properties on the surface. Generally, the surface shows the hydrophilic/hydrophobic properties according to the ratio of sp3/sp2 in the thin films [25]. The DLC thin films with higher sp3 bonding fraction had a more hydrophobic surface than those with a higher sp2 bonding fraction because the surface energy of the sp3-terminated surface is very high due to its strong covalent character [26]. Owing to the hydrophobic properties of the DLC thin films, they are used as surface protectable and self-cleanable thin films. All DLC thin films in this study exhibited high contact angle values, which is highly likely to be applied to a functional coating for surface protection and self-cleaning.
The results of the Raman spectrum are presented in Figure 4, including the G-peak position and the ratio of the integrated areas under the D- and G-peaks (ID/IG) in the RF-PECVD DLC thin films as measured with a change in thickness. The Raman spectrum shows the typical spectrum of the DLC thin films with an almost symmetrical carbon peak at approximately 1560 cm−1 and a silicon substrate peak at approximately 950 cm−1, with a weak shoulder at approximately 1370 cm−1 related to the disorder. The strength of the Raman peak increased slightly with an increase in the thickness of the DLC thin films, and Gaussian curve fitting for the Raman spectrum resulted in D (disordered) and G (graphitic) bands near 1370 and 1560 cm−1, respectively. As shown by the results of Gaussian curve fitting for the Raman spectrum (Figure S1), the G-peak shifted from 1558 to 1564 cm−1, and the ID/IG ratio decreased from 0.290 to 0.148, with an increase in thickness. The shift of the G-peak toward a relatively higher wavenumber and decrease in the ID/IG ratio indicates a decrease in the sp3 bonds in the DLC thin films, which is related to the density of the DLC thin film caused by the collision effect of carbon and hydrogen ions on the substrate surface with an increase in deposition time, a decrease in carbon sp3 bonds due to a decrease in hydrogen ions, and an increase in the surface temperature of the thin-film surface [6,7]. In other words, the increase in deposition time brought the sp3 bonding fraction in the DLC thin films to further reduce content of hydrogen as the surface temperature increases due to active binding on the thin-film surface and activation of the increased ions [6,7,8]. Beeman et al. reported that the disorder in the thin film increases as the energy of carbon ions exposed to plasma increases, and the hydrogen content in the thin film decreases the number of sp3 bonds with hydrogen in the thin film; these affected the tribological and optical properties of the DLC thin films with increases in both intensity and full width at half maximum (FWHM) of the G-peak in the Raman analysis.
Figure 5 shows the optical properties, such as transmittance, reflectance, refractive index, and absorption coefficient, measured with an increase in the thickness of the RF-PECVD DLC thin films. The transmittance of the DLC thin films tended to decrease as the thickness increased, and the transmittance of the 550 nm visible light decreased from 69% to 58%. The refractive index and absorption coefficient of the DLC thin films increased from 1.400 to 2.124 (633 nm) and from 0.010 to 0.014, respectively, with an increase in thickness. If DLC thin films can be regarded as a homogeneous medium, the absorption coefficient α(λ) and the absorbance Aabs were described by Beer–Lambert law and estimated by using Formulas (2) and (3):
A ( λ ) = I ( λ ) R ( λ ) T ( λ ) ,
A a b s = l n T ( λ ) I ( λ ) R ( λ ) ,
α ( λ ) =   A a b s d   = d 1 l n I ( λ ) R ( λ ) T ( λ ) ,
where d is the film thickness, A(λ) is the intensity of light absorbed by the film, I(λ) is the intensity of incident light to the film, R(λ) is the intensity of reflected light on the surface, and T(λ) is the intensity of illumination that passes through the film at a certain wavelength of λ. The increase in the thickness of the DLC thin films resulted in increased absorbance, which resulted from the decrease in the transmittance and/or reflectance. It can be concluded that there is a negligible effect of light scattering from the surface because the rms surface roughness was lower than 0.94 nm for all film thicknesses (Figure 1) [27]; therefore, the transmittance will be diminished if the reflectance of the thin films increases with increasing thickness [27]. The transmittance decreased because of the change in the thin-film microstructure due to the decrease in the sp3 bonding fraction [28,29] owing to the increase in the ratio of hydrogen bonds [26], while these results are also associated with an increase in sp2 sites or clusters [26], as shown by the Gaussian curve fitting for the Raman spectrum [8,9,10,11]. The increased refractive index was caused by the increase in sp2 sites or clusters, which resulted from the reduced bound hydrogen content and structurally densified thin films as the thickness of the DLC thin films increased [28].
Figure 6 shows the I-V curve showing the characteristics of DSSCs with the DLC ARC as a function of thickness, and the electrical characteristics of DSSCs with the DLC ARC are summarized in Table 1. The open-circuit voltage (Voc) is determined by the difference between the Fermi level of the TiO2 working electrode and the oxidation/reduction level of the electrolyte. The fill factor (FF) is generally due to the internal DSSC resistances, such as FTO sheet resistance, resistance to charge movement in working/counter electrodes, and diffusion resistance of ion species in the electrolyte. The short-circuit current density (Jsc) of DSSCs could be controlled at a similar level from 11.93 without the DLC ARC to 12.11 and to 11.38 mA/cm2 with the DLC ARC. For DSSCs, the increase in Jsc is associated with an increase in incident photons; an improved Jsc of 12.11 mA/cm2 was obtained at a thickness of 20 nm with an increase in the incident photons through reflection protection, while a diminished Jsc of 9.79 mA/cm2 was observed for a thickness of 80 nm with a sharp decrease in the transmittance from the thicker ARC. The increase in Voc of the DSSCs results from a passivation effect of DLC thin films that suppresses the recombination current [30]. The measured Voc and FF values show differences with changes in the thickness of the DLC ARC. Thus, a significant improvement in the CE was obtained from 4.92% to 5.35% when applying the DLC ARC owing to the amount of photons in the DSSCs with the proper thickness of ARC. In particular, the DSSCs with the DLC ARC of 60 nm showed an improvement of 8.73% in CE compared with the established DSSCs without ARC.

4. Conclusions

The RF-PECVD system was used to manufacture DLC thin films. The tribological, optical, and structural properties of the DLC thin films were analyzed at varying thicknesses, and the correlation between the properties was considered for the application of DLC thin films to the ARC of DSSCs. As the thickness of the DLC thin films increased, the surface roughness and friction coefficient slightly increased, the hardness and elastic modulus increased, and the contact angle decreased somewhat. The transmittance of visible light at 550 nm decreased, while the refractive index and absorption coefficient increased with an increase in thickness. The strength of the Raman spectrum increased slightly; the G-peak shifted toward a relatively higher wavenumber as a result of Gaussian curve fitting for the Raman spectrum; and the ID/IG ratio decreased, which means that the sp3 bonds in the DLC thin films decreased, and the collision between carbon and hydrogen ions in the plasma increased on the surface as the deposition time increased, the carbon sp3 bonds decreased due to the reduction in hydrogen ions, and thus the DLC thin films became densified due to the increased surface temperature. The optimal Jsc, Voc, and FF values with a change in the thickness of the DLC thin films were chosen for the significantly improved CE from 4.92% to 5.35% in the 60-nm-thick DLC ARC for DSSCs, with a hard and hydrophobic surface for protective and self-cleaning surfaces.

Supplementary Materials

The following is available online at https://0-www-mdpi-com.brum.beds.ac.uk/2076-3417/11/1/358/s1, Figure S1: Gaussian fitting of Raman spectra for the RF-PECVD DLC thin films with various film thicknesses: (a) 20, (b) 40, (c) 60, and (d) 80 nm.

Author Contributions

Conceptualization, Y.S.P. and N.-H.K.; investigation, J.-S.S.; data curation, Y.S.P.; writing—original draft preparation, J.-S.S. and Y.S.P.; writing—review and editing, N.-H.K.; project administration, N.-H.K.; funding acquisition, N.-H.K. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Korea Institute of Energy Technology Evaluation and Planning (KETEP) and the Ministry of Trade, Industry and Energy(MOTIE) of the Republic of Korea (No. 20184010201650). This study was supported by a research fund from Chosun University, 2017.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data is contained within the article or supplementary material.

Conflicts of Interest

The authors declare no conflict of interest. The founding sponsors had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, and in the decision to publish the results.

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Figure 1. Field effect scanning electron microscope (FESEM) surface images of the radio frequency plasma-enhanced chemical vapor deposition (RF-PECVD) diamond-like carbon (DLC) thin films with various film thicknesses: (a) 20, (b) 40, (c) 60, and (d) 80 nm. (e) Three-dimensional (3D) images and (f) rms surface roughness of the RF-PECVD DLC thin films for the same conditions obtained by atomic force microscopy (AFM).
Figure 1. Field effect scanning electron microscope (FESEM) surface images of the radio frequency plasma-enhanced chemical vapor deposition (RF-PECVD) diamond-like carbon (DLC) thin films with various film thicknesses: (a) 20, (b) 40, (c) 60, and (d) 80 nm. (e) Three-dimensional (3D) images and (f) rms surface roughness of the RF-PECVD DLC thin films for the same conditions obtained by atomic force microscopy (AFM).
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Figure 2. (a) Hardness and elastic modulus, and (b) friction coefficient in the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm.
Figure 2. (a) Hardness and elastic modulus, and (b) friction coefficient in the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm.
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Figure 3. Contact angle (a) images and (b) values of the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm.
Figure 3. Contact angle (a) images and (b) values of the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm.
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Figure 4. (a) G-peak position and ID/IG ratio, and (b) G-peak width and intensity in the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm.
Figure 4. (a) G-peak position and ID/IG ratio, and (b) G-peak width and intensity in the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm.
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Figure 5. (a) Transmittance, (b) refractive index (n), and absorption coefficient (k) of the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm. The inset of (a) shows reflectance of the RF-PECVD DLC thin films under the same film thicknesses.
Figure 5. (a) Transmittance, (b) refractive index (n), and absorption coefficient (k) of the RF-PECVD DLC thin films with various film thicknesses: 20, 40, 60, and 80 nm. The inset of (a) shows reflectance of the RF-PECVD DLC thin films under the same film thicknesses.
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Figure 6. Dye-sensitized solar cells (DSSCs) (a) without and (b) with the RF-PECVD DLC anti-reflective coatings (ARCs). (c) Cell characteristics (J-V curves) of the DSSCs with different thickness of the RF-PECVD DLC ARC compared with the non-ARC cell.
Figure 6. Dye-sensitized solar cells (DSSCs) (a) without and (b) with the RF-PECVD DLC anti-reflective coatings (ARCs). (c) Cell characteristics (J-V curves) of the DSSCs with different thickness of the RF-PECVD DLC ARC compared with the non-ARC cell.
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Table 1. Optoelectronic properties of the DSSCs with different thickness of the RF-PECVD DLC ARC compared with the non-ARC cell.
Table 1. Optoelectronic properties of the DSSCs with different thickness of the RF-PECVD DLC ARC compared with the non-ARC cell.
Thickness (nm)CE (%)Voc (V)Jsc (mA/cm2)FF (%)
04.920.64911.9363.58
205.000.69112.1159.70
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MDPI and ACS Style

Song, J.-S.; Park, Y.S.; Kim, N.-H. Hydrophobic Anti-Reflective Coating of Plasma-Enhanced Chemical Vapor Deposited Diamond-Like Carbon Thin Films with Various Thicknesses for Dye-Sensitized Solar Cells . Appl. Sci. 2021, 11, 358. https://0-doi-org.brum.beds.ac.uk/10.3390/app11010358

AMA Style

Song J-S, Park YS, Kim N-H. Hydrophobic Anti-Reflective Coating of Plasma-Enhanced Chemical Vapor Deposited Diamond-Like Carbon Thin Films with Various Thicknesses for Dye-Sensitized Solar Cells . Applied Sciences. 2021; 11(1):358. https://0-doi-org.brum.beds.ac.uk/10.3390/app11010358

Chicago/Turabian Style

Song, Jae-Sil, Yong Seob Park, and Nam-Hoon Kim. 2021. "Hydrophobic Anti-Reflective Coating of Plasma-Enhanced Chemical Vapor Deposited Diamond-Like Carbon Thin Films with Various Thicknesses for Dye-Sensitized Solar Cells " Applied Sciences 11, no. 1: 358. https://0-doi-org.brum.beds.ac.uk/10.3390/app11010358

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