Electron transport properties of TiO2 shell on Al2O3 core in dye-sensitized solar cells

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Xie Dongmei, Tang Xiaowen, Lin Yuan, Ma Pin, Zhou Xiaowen. Electron transport properties of TiO₂ shell on Al₂O₃ core in dye-sensitized solar cells. Chinese Physics B, 2018, 27(1): 017804 Copy to clipboard

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Electron transport properties of TiO₂ shell on Al₂O₃ core in dye-sensitized solar cells

Xie Dongmei^{1, 2}, Tang Xiaowen^{1, 2}, Lin Yuan^{1, 2, †}, Ma Pin^{1, 2}, Zhou Xiaowen^{1, 2}

1 Beijing National laboratory for Molecular Sciences, Key Laboratory of Photochemistry, CAS Research/Education Center for Excellence in Molecular Sciences, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100190, China

2 University of Chinese Academy of Sciences, Beijing 100049, China

† Corresponding author. E-mail: linyuan@iccas.ac.cn

Abstract

The performance of dye-sensitized solar cells (DSSCs) is strongly affected by the properties of semiconductor nanoparticles. In this work, we used TiO₂ particles prepared by TiCl₄ hydrolysis n times on Al₂O₃ films (A/T(n)), and investigated morphology, photoelectric, and electron transport properties of A/T(n). The TiO₂ shell was composed of 10–20 nm nanoparticles and the number of nanoparticles increased with increasing TiCl₄ treatment times. The highest photoelectric conversion efficiency of 3.23% was obtained as A/T(4). IMPS results indicated that electron transport rate was high enough to conduct current, and was not the dominating effect to limit the . was mainly determined by dye loading on TiO₂ and the interconnection of TiO₂. These may provide a new strategy for preparing semiconductor working electrodes for DSSC.

PACS: 78.55.Mb;72.20.Jv;84.60.Jt;88.40.H-

Keyword:dye-sensitized solar cell;electron transportation;core-shell structure;intensity-modulated photocurrent spectroscopy

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1. Introduction

In the past 20 years, dye-sensitized solar cells (DSSCs) were intensively investigated by researchers and industries owing to their low cost, easy fabrication and high photoelectric conversion efficiency (PCE).^[1–5]

DSSC consists of a wide-bandgap nanocrystal semiconductor anode, an electrolyte and a counter electrode.^[6,7] In order to realize a high PCE, wide-bandgap semiconductors must satisfy the following requirements: (i) bandgap is larger than 3.2 eV to reduce the adsorption of visible light;^[8] (ii) conduction band edge needs to align with the lowest unoccupied molecular orbital (LUMO) of the dye; (iii) carrier has the fast transport rate; (iv) the rate of recombination between electron in semiconductor and electrolyte is slow. Up to now, few materials can satisfy both requirements (iii) and (iv). TiO₂ has a slow electron recombination rate and a slow electron transport rate. On the contrary, ZnO^[9–14] and SnO₂^[15–19] have fast electron transport rates and a fast electron recombination rate. Among all the semiconductors, DSSCs with TiO₂ as anode have the highest PCE, larger than those with of ZnO and SnO₂. However, the electron transport rate in TiO₂ is lower than that of ZnO and SnO₂. In order to increase PCE of DSSCs, much research has been carried out on the understanding which makes the electron transport rate slow and how to improve the electron transport rate of TiO₂.

The transient current and intensity-modulated photocurrent spectroscopy (IMPS) are used to investigate electron transport properties in semiconductor nanocrystalline film. It is found that the electron transport rate is 1–3 orders of magnitude slower than that of bulk materials and proportional to the square root of electron density. Most popular trap–detrap models can explain these results. Electrons are trapped by defect states during the transport, and the trapped electrons need to be excited by heat to detrap to the conduction band to transport again. With the increase in electron density, the occupation of trapped states is increased, which makes rate of electron trap slower and detrap faster, and consequently the transport rate is increased. Moreover, the disordered distribution of nanoparticles increases the transport path length, then decreases the transport rate.

The core–shell structure is one of the possible methods to enhance electron transport rate. ZnO or SnO₂ nanoparticles covered by TiO₂ may combine the advantages of the high electron transport rate of the core and the low electron recombination rate of the shell. However, the result of the core–shell structure is not as good as we expected. This is because the energy level of the shell does not match with the core and the poor electronic contact between the core and shell, or the recombination between core and electrolyte is not fully inhibited by the shell owing to poor morphology.

In this paper, we designed and fabricated the photoanode of DSSCs, which centered on an Al₂O₃ core surrounded by a TiO₂ shell (A/T(n)). We used this core–shell structure as a model to investigate the effect of electron transport rate on photoelectric properties of cells. and PCE peaked at A/T(4), with values of and 3.32% respectively. This study provides a method to study the mechanism of electron transport in nanocrystalline porous film.

2. Experimental section

2.1. Preparation of TiO₂ compact layer

Isopropyl titanium (0.455 mL) was added to n-propanol (20 mL) to form a TiO₂ paste under stirring for 12 h at room temperature. The TiO₂ compact layer was prepared on the FTO plate using spin-coating technique, and then was heated at 450 °C for 30 min.

2.2. Preparation of A/T(n) photoanode

Al₂O₃ (0.4 g), triton-100 (0.2 g), acetic acid (0.4 ml), and deionized water (2 ml) were first mixed to form the Al₂O₃ paste. The Al₂O₃ paste was ultrasonically dispersed for 2 h first and then stirred for 24 h. The Al₂O₃ films were fabricated on the TiO₂ compact layer using a doctor blade technique, and then were heated at 450 °C for 30 min. The annealed Al₂O₃ films were immersed into an aqueous solution of TiCl₄ (0.07 M) for post-treatment at 70 °C for 30 min.^[20,21] Then, the Al₂O₃ films were flushed with deionized water, dried and annealed again at 450 °C for 30 min to form the A/T photoanode. The thickness of TiO₂ from A/T(n) photoanode could be adjusted by repeating cycles of the TiCl₄ treatment.

2.3. Fabrication of DSSCs

To eliminate the physisorbed water, the A/T photoanode was heated at 100 °C for 40 min and then immersed in ethanol solution of the N3 dye of 0.3 mM for 24 h. The dye-sensitized A/T photoanode together with a platinum foil counter electrode and liquid electrolyte composed of 0.5 M LiI, 0.02 M I₂, 0.3 M 1-methyl-3-hexylimidazolium iodide (HMII),^[22] and 0.5 M 4-tert-butylpyridine in 3-methoxypropionitrile were assembled into a sandwich cell structure.

2.4. Characterization and measurements

The crystallographic structure of the A/T film was characterized by x-ray diffraction (XRD) (Rigaku D/max-2500) Cu Kα radiation with a scan speed of 8°/min. Surface morphology studies were carried out by scanning electron microscopy (SEM, Hitachi S-4800, 15 kV) and high-resolution transmission electron microscopy (HR-TEM, Tecnai G2 20 S-TWIN, 200 kV). The electrochemical performance was investigated by a Keithley 2611 Source Meter (Keithley Instruments, Inc., USA) under AM 1.5 () supplied by a solar simulator (Oriel, 91160–1000). Electrochemical impedance spectroscopy (EIS) data were obtained under illuminations, using a perturbation of ±10 mV over the open-circuit potential by using Solartron 1255B frequency analyzer and Solartron SI 1287 electrochemical interface system. The intensity-modulated photocurrent and photovoltage spectroscopy (IMPS and IMVS) were performed using a green light emitting diode (max = 520 nm) driven by a solartron 1255B frequency-response analyzer. The LED provided both the dc and ac components of the illumination. The UV spectrum measurement was made with aU-3010 spectrophotometer (Hitachi Corp).

3. Results and discussion

3.1. XRD analysis

Figure 1 shows the XRD patterns of FTO, Al₂O₃ film, and A/T(4) film. It can be seen that the diffraction peaks of 25.64°, 35.18°, 43.5°, 52.66°, 57.68°, 66.56° can match well with the standard rhombohedron phase of Al₂O₃ (JCPDF No. 46-1212). Compared to the Al₂O₃ film, the diffraction peaks of 25.34°, 53.49°, 68.3°, 69.1° from A/T(4) film can be assigned to standard anatase phase of TiO₂ (JCPDF No. 21-1272). It is evident that TiO₂ particles can form on the Al₂O₃ particles by TiCl₄ post-treatment. The slight decrease in peak strength of Al₂O₃ may be due to the Al₂O₃ layer coated by the TiO₂ layer from TiCl₄ hydrolysis, which weakens the relative strength.

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	Fig. 1. (color online) XRD patterns of FTO, Al₂O₃ film, and A/T(4) film.

3.2. Morphology of A/T(n)

The Morphology of the Al₂O₃ film and the A/T(n) film is investigated by SEM and TEM (Figs. 2 and 3). It can be seen that the surface of the Al₂O₃ film is relatively rough compared to the A/T(4) film. TiO₂ particles formed by TiCl₄ hydrolysis grow on the Al₂O₃ particles, which make the surface of Al₂O₃ film smooth. The diameter of Al₂O₃ particles measured from the TEM image (shown in Fig. 3(a1)) is approximately 80 nm. As the time of TiCl₄ treatment increases, so does the number of TiO₂ particles and the diameter of TiO₂ is approximately 10–20 nm.

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	Fig. 2. SEM images of Al₂O (a) and A/T(4) film (b).

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	Fig. 3. TEM images of A/T(n) films.

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	Fig. 4. (color online) I–V curve of A/T(n).

3.3. Photoelectric conversion properties

Dye adsorption increases from of A/T(1) to of A/T(4) only improve 50%. The Al₂O₃ films without TiCl₄ treatment also can adsorb dye on the Al₂O₃ particles with the value of . Though Al₂O₃ can adsorb dye, Al₂O₃ cannot generate photocurrent because of its insulating properties. The increased surface area of the new TiO₂ particles formed on the Al₂O₃ surface is mostly canceled out by the overlap of TiO₂ on Al₂O₃ or overlap between TiO₂ particles. Dye adsorption falls to for A/T(5) because the TiO₂ particles may block the channel and prevent the solution of dye connecting with the inner TiO₂ particles. The of A/T(1) is nearly zero, although the dye adsorption is quite large. The electrons neither inject into Al₂O₃ from adsorbed dye nor transfer in the network of Al₂O₃ to form photocurrent. The electrons can inject into TiO₂ from adsorbed dye but cannot transfer from one TiO₂ particles to another because of the isolation of TiO₂ particles. With the increase in TiCl₄ treatment times, the number of TiO₂ particles increases and, consequently, the particles are close to each other and form a conducting network. Electrons can transport in the network. Moreover, the increase in the number of TiO₂ particles formed on the surface of Al₂O₃ particles increases the amount of TiO₂ absorbing dye and reduces the amount of Al₂O₃ absorbing dye, which results in increasing remarkably to with the increase in the TiCl₄ treatment times up to 4. However, is only 5.61 for A/T(5), owing to low dye adsorption and block of the contact between the dye and solution.

The of DSSC of A/T(n) has opposite trends compared to with the increase of n. The has the largest value of 745 mV for n = 1 and decreases with increasing n. The of A/T(4) is the smallest and only 655 mV. If we increase n to 5, the of A/T(n) increases again. Generally, the is determined by the difference of conduction and redox potential of the electrolyte, and the electron recombination rate. The dye absorption may represent the surface area of TiO₂. From the dye absorption data, we know that A/T(4) has largest surface area. The larger the surface area is, the higher recombination rate is. Thus, the and of A/T(n) display opposite behavior with increase in n.

The FF of A/T(n) reduces with the increase in n. The low value of A/T(1) may be due to the large error caused by the low value of .

The of A/T(4) is higher than all of other treatment times, although and FF of A/T(4) are slightly lower than all of other treatment times. We obtained the highest PCE of 3.32% of A/T(4).

3.4. IMPS and IMVS

IMPS and IMVS of A/T(n) (n = 1–5) are shown in Fig. 5. Electron transport time () in A/T(n) is calculated from the frequency of the lowest point in the IMPS plot and listed in Table 2. represents average time of electrons transport from injecting into TiO₂ to reaching the external circuit. The smaller the value of is, the faster the electron transfer rate is. The highest is in accordance with the shortest (2.02 ms) obtained from A/T(4). However, the amplitude of change is less obvious than the change from A/T(1) to A/T(5) (Tables 1 and 2). Hence, the rise of is only partly due to the increase of electron transfer rate. The formation of the conducting network of TiO₂ particles may also affect the . From the TEM images, it can be seen that TiO₂ particles become more and more and closely linked to constitute a conducting network with the increase times of TiCl₄ treatment. The expanding scope of conducting network causes the significant rise in the from A/T(1) to A/T(4). At the same time, the increasing TiO₂ particles in the conducting network can also enhance . Because TiO₂ particles connect to each other closely to form more routes for electron transport that make the electrons injected into the TiO₂ particles reach the substrate easier. Therefore, the electron transport in the network can choose a short path directly to the substrate and we get a very short in A/T(4). For A/T(5), TiO₂ particles may block the channel of electrolyte, and the ion in the electrolyte cannot transport alone with electrons to keep the electric neutrality. The movement of an electron would form an electrical field against the transport of electrons, resulting in the decrease in .

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	Fig. 5. (color online) (a) IMPS and (b) IMVS plot of A/T(n).

Table 1.

Photoelectric conversion parameters of A/T(n).

Table 2.

Electron transportation time and lifetime.

For A/T(1) or A/T(2), the conducting network is sparse, and electrons must be transported over a long curved path to reach the electrode, which increases . However, TiO₂ particles on the top of electrode are difficult to connect to the network, and most of TiO₂ particles in the network are close to the FTO electrode. Therefore, of A/T(1) or A/T(2) is less than 3 times of that of A/T(4).

Generally, electron transport in nanocrystalline is slower than in bulk materials. Compared with pure TiO₂ nanocrystalline film, TiO₂ particle in A/T(n) is smaller, and the transport length is longer owing to the Al₂O₃ core blocking the conducting path. However, the of A/T(n) is the same magnitude as pure TiO₂ films. The volume of TiO₂ particles is smaller than that of pure TiO₂ films, and the electron density in TiO₂ of A/T(n) is higher. High electron density may fill the trap state and accelerate the electron transfer rate.

The electron lifetime τ_n in A/T(n) is also calculated from the frequency of the lowest point in IMVS plot and listed in Table 2. τ_n represents the average time of electrons staying in TiO₂ particles before they recombine with electrolyte or oxidized dye. Generally, longer τ_n means larger . However, this relation is not clear in our experiments. A/T(2) has shortest electron lifetime, but its is not the smallest, and only slightly smaller than A/T(1). We think that the IMVS measurement may has some error on A/T(2) and A/T(3).

3.5. EIS

The Nyquist plot of A/T(1–5) is shown in Fig. 6. In the Nyquist plot, EIS is composed of two semicircles. The interception of the high-frequency semicircle with the X-axis represents the serial resistance ( of the cell, which consists of the resistance of electrolyte, FTO film, and TiO₂ working electrode. TiCl₄ treatment does not affect the resistance of electrolyte and FTO film. The variation of with treatment times is due to the change in the resistance of working electrode, because the increased number of TiO₂ particles provides a better conducting network and reduces the serial resistance of the working electrode. The high-frequency semicircle represents the impedance of the counter electrode, which has nothing to do with the working electrode investigated in this study, and has not been analyzed. The low-frequency semicircle represents the impedance of recombination on the interface of TiO₂ and the electrode. The increased number of TiO₂ particles has larger surface area, but may also block the electrolyte channel. Those two effects lead the to first decrease and then increase after four times treatment.

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	Fig. 6. (color online) EIS plot of A/T(n).

Table 3.

Serial and recombination resistance of A/T(n).

4. Conclusion and perspectives

TiO₂ nanoparticles were formed by TiCl₄ treatment on the framework of insulating Al₂O₃ nanoparticles of diameter 80 nm. The influence of various behaviors, such as photoelectrical, morphology, electron transport, and recombination, on the treatment times was investigated. With the increase in treatment times, the number of particles rather than diameter of particles were increased. and PCE reached peak at A/T(4) of and 3.32% respectively. Electron transport time of A/T(n) obtained from IMPS measurement showed that TiCl₄ treatment times only slightly affected the , and its value was the same amplitude as pure TiO₂. Combining with TEM images of A/T(n), we thought that with the increase in n, the range and the inner connection of the conduction network was increased. The former increased the , and the later decreased the and serial resistance . A/T(n) film provides a new model to understand the insight of electron transportation in semiconducting nanoparticles.

Reference

[1]	Mahmoud S Azam Iraji Z Mehdi M 2014 Chin. Phys. 23 047302
[2]	Wang H Y Wang G S Wu H J Luo Y H Li D M Meng Q B 2016 Acta Phys.-Chim. Sin. 32 201
[3]	Xia R Wang S M Dong W W Fang X D 2017 Acta Phys.-Chim. Sin. 33 670
[4]	Duan Y Fu N Liu Q Fang Y Zhou X Zhang J Lin Y 2012 J. Phys. Chem. 116 8888
[5]	Wang M Bai S Chen A Duan Y Liu Q Li D Lin Y 2012 Electrochim. Acta 77 54
[6]	Fu N Xiao X Zhou X Zhang J Lin Y 2012 J. Phys. Chem. 116 2850
[7]	Fang Y Zhang J Zhou X Lin Y Fang S 2012 Electrochim. Acta 68 235
[8]	Li X Wang C Xia N Jiang M Liu R Huang J Li Q Luo Z Liu L Xua W Fang D 2017 J. Mol. Struct. 1148 347
[9]	Zhang Q 2008 Angew. Chem. Int. Ed. Engl. 47 2402
[10]	Ko S H Lee D Kang H W Nam K H Yeo J Y Hong S J Grigoropoulos C P Sung H J 2011 Nano Lett. 11 666
[11]	Memarian N Concina I Braga A Rozati S M Vomiero A Sberveglieri G 2011 Angew Chem. Int. Ed. Engl. 50 12321
[12]	McCune M Zhang W Deng Y 2012 Nano Lett. 12 3656
[13]	Xu C Gao D 2012 J. Phys. Chem. 116 7236
[14]	Zhang R Pan J Briggs E P Thrash M Kerr L L 2008 Sol. Energ. Mat. Sol. 92 425
[15]	Birkel A Lee Y G Koll D Van Meerbeek X Frank S Choi M J Kang Y S Char K Tremel W 2012 Energ. Environ. Sci. 5 5392
[16]	Gubbala S Russell H B Shah H Deb B Jasinski J Rypkemac H Sunkara M K 2009 Energ. Environ. Sci. 2 1302
[17]	Tetreault N Arsenault É Heiniger L Soheilnia N Brillet J Moehl T Zakeeruddin S Ozin G A Grätzel M 2011 Nano Lett. 11 4579
[18]	Snaith H J Ducati C 2010 Nano Lett. 10 1259
[19]	Gao C Li X Lu B Chen L Wang Y Teng F Wang J Zhang Z Pan X Xie E 2012 Nanoscale 4 3475
[20]	Sommeling P M O’Regan B C Haswell R R Smit H J P Bakker N J Smits J J T Kroon J M van Roosmalen J A M 2006 J. Phys. Chem. 110 19191
[21]	Zhong M Shi J Zhang W Han H Li C 2011 Mater. Sci. Eng. 176 1115
[22]	Bonhote P Dias A Armand M Papageorgiou N Kalyanasundaram K Grätzel M 1998 Inorg. Chem. 37 166