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An Approach to Equivalent Circuit Modelling of Inverted Organic Solar Cells

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DOI: 10.4236/cs.2016.78113    1,336 Downloads   1,699 Views  

ABSTRACT

A low temperature sol-gel process was used to fabricate zinc-oxide and yttrium-doped zinc oxide layers. These zinc-oxide and yttrium-doped ZnO films were used as electron transport layers in conjunction with P3HT and PC16BM type solar cells. It was demonstrated that annealing and doping of electron transport layer influenced the overall organic solar cells performance. Anneals of ~ 150?C provided the highest device performance. Compared to the undoped zinc oxide, the device with yttrium doped zinc oxide layers showed improved efficiency by about 30%. Furthermore an equivalent circuit was proposed to understand the connection between the electrical and optical characteristics of the device. Comparisons between the simulated and experimental current-voltage(I-V) curves displayed only a 1.2% variation between the curves. Clearly, our experimental and simulated studies provide new insight on the equivalent circuit models for inverted organic solar cells and further improvement on photovoltaic efficiency.

Received 4 March 2016; accepted 5 April 2016; published 8 June 2016

1. Introduction

The economic prosperity and the technological development are the key challenges for the world herself and energy plays the most important roles [1] . In today’s world, fossil fuels (gas, coal, oil, etc.) are used extensively for cooling-heating, cooking and operating industrial as well as home appliances [2] . But, this energy sources are offensive to the environment as they produce huge carbon-dioxide (CO2) during the burning period which causes to deplete the ozone layer at atmosphere that influences the green house effects more. It is also responsible for global warming [3] . Since the late 19th century, the global mean surface temperature and the global sea level have increased by 0.3˚C - 0.6˚C and 10 - 25 cm, respectively [4] . These changes have already increased the number of natural disasters and are likely to have devastating effects for human and other life forms all around the world [5] .

In the recent years, the scientists have given more eyes to the solar energy to handle the energy shortage issues all over the world [6] . To this point, organic solar cells (OSCs) are one of the promising solutions [7] - [10] . In OSCs, a phase-separated (BHJ) nanostructure is formed from a blend of fullerene derivative [6,6]-phenyl-C61 butyric acid methyl ester (PC61BM) and regioregular poly(3-hexylthiophene) (P3HT). As the exciton has only a certain lifetime before it collapses (where the electron recombines with the hole), the characteristic distance between an exciton generation site and a donor/acceptor interface must be on order of 5 - 10 nm. At the same time, the photons need to traverse a certain thickness of active layer, often on the order of 100 nm, in order for most of them to be absorbed. The blend of P3HT and PCBM offers a large interfacial area for efficient exciton dissociation [10] . Recently, P3HT:PC61BM based OSC devices were fabricated and characterized by Guo et al. to use it for space applications [11] . These devices were tested under AM0 (air mass zero) illumination. Due to the molecular nature of these organic materials, the manufacturing processes of OSCs are relatively inexpensive. They are easy to fabricate as flexible large area sheets. However, several obstacles must be overcome in order to make them commercially available. One of these obstacles is that OSCs have lower efficiency and lifetimes compared to commercially available Si solar cells [12] - [16] .

In case of OSC devices, the short circuit current (JSC), open circuit voltage (VOC), and fill factor (FF) are widely dependent on the energy level alignment at the interfaces between each layer [17] . For example, application of interfacial layers in OSCs results enhanced VOC [17] - [20] . On the other hand, the use of non-ohmic contacts in between electrode and the organic layers may result in a lower VOC. Moreover, the charge collection efficiency is also increased by the addition of interfacial layers. It also decreases the interfacial contact resistance. As a result, smaller series resistance (RS) and larger shunt resistance (RSH) are achieved [17] [21] [22] .

In one of our previous studies, we fabricated organic solar cell based on a composite of fullerene derivative [6,6]-phenyl-C61 butyric acid methyl ester (PCBM) and regioregular poly (3-hexylthiophene) (P3HT) with an added interfacial layer of AgOx in between the PEDOT:PSS layer and the ITO layer. We investigated the properties of OSC devices with an added AgOx interfacial layer between the PEDOT:PSS and ITO and developed a model that best describes this device. The AgOx and PEDOT:PSS layers form a composite hole transport layer. It increases the fill-factor (FF), power conversion efficiency (PCE) and reduces the physical contact of PEDOT: PSS with ITO. Incorporation of the AgOx interfacial layer shows an increase in fill factor (by 33%) and power conversion efficiency (by 28%). The interfacial modification also results in improved shunt resistances suggesting lesser charge recombination due to cascading hole transport process [23] .

In the inverted structure of OSCs, silver is used as a hole collecting electrode because of its high work function characteristics. For electron transport layer (ETL) n-type metal oxides (such as SnO2, TiO2 and ZnO) are used widely as ETL [24] - [26] . Among the meatal oxides, ZnO has high electron mobility, good transparency, availability, non-toxicity, and hole-blocking properties that make it a good ETL [27] . In organic/polymer based solar cells, dye sensitized solar cells, and perovskite based solar cells pure ZnO has been used as well [27] - [29] . Recently, metal doped n-type buffer layers have been studied by several research groups in order to increase the device performance of inverted solar cells. To improve the optical and electrical properties of ZnO layers metal doping is very efficient [30] . Good n-type dopant atoms can replace the Zn sites in the ZnO crystal and generate free electrons [31] - [36] .

We fabricated an inverted solar cell with the structure of ITO/ZnO/P3HT:PC61BM/MoOx/Ag/Al. The device structure is shown in Figure 1. For OSC, the layers of ITO/PEDOT:PSS act as anode and Al acts as cathode, however for inverted organic solar cell (IOSC), the layers of YZO/ITO and Al play the roles of cathode and anode, respectively. Meanwhile, the layers of YZO/AgOx and MoOx are chosen for electron and hole transport layers. The P3HT:PCBM is the active layer and the incident light enters devices from glass in both structures.

A blend of regioregular poly (3-hexylthiophene) (P3HT) and the fullerence derivative [6,6]-phenyl-C61 butyric acid methyl ester (PCBM) is used. The BHJ offers a large interfacial area for efficient excition dissociation. YZO is used as the anode contact. The effect of ZnO processing temperature on the photovoltaic properties of inverted solar cells is also described. Although higher temperatures leads to improvement in thin film crystallinity and electron mobility, annealed ZnO layers at 150˚C showed best device performance [37] . To enhance the

(a) (b)

Figure 1. Schematic illustration of the IOSC with a structure of ITO/YZO/P3HT:PCBM/MoOx/Al (a), and conventional OSC with a structure of AgOx-ITO/PEDOT:PSS/P3HT:PCBM/LiF-Al (b).

electron transport properties in the ZnO films the effect of yttrium as a doping impurity was investigated. High efficiency organic solar cells were fabricated by doping yttrium in the ZnO electron transport layer and utilizing the optimized annealing conditions.

2. Experimental Details

2.1. Zinc Oxide and Yttrium-Doped Zinc Oxide Precursor Solution

N,N-dimethylformamide (99.8%, Sigma-Aldrich) (MEA) 0.5 M zinc acetate dihydrate ((Zn(CH3CO2)2∙2H2O) was dissolved with monoethanolamine as chelating agent (stabilizer) to prepare ZnO and yttrium doped ZnO precursor solution. Until the mixture solution changed to a clear transparent solution, it was stirred on a hot plate at 60˚C for about 1 hr after adding YCl3∙6H2O in different amounts. All solutions were allowed to age for a day.

2.2. Device Fabrication

All devices were fabricated utilizing 40Ω-sq−1 patterned ITO coated glass substrates. Prior to device fabrication the electrodes were cleaned in ultrasonic baths of methanol, acetone and isopropanol respectively. This was followed by a 15 min ultraviolet ozone (UVO) treatment. On cleaned patterned ITO substrate the ZnO/YZO precursor solution was spin coated at 3000 rpm for 60 s. In order to convert the precursor materials into ZnO, heat treatments were given to solutions at various temperatures for an hour. To remove any organic residues that might be present on the surface, an ultraviolet ozone (UVO) treatment for 2 min was performed on the ZnO/YZO layers. P3HT:PC61BM blends were dissolved in 1,2-dichlorobenzene (DCB) in 1:1 weight ratio. Then blend of P3HT:PC61BM was spin-coated at 600 rpm for 1 min. The photoactive layer was then dried at 150˚C for 15 min. Finally, a structure of MoOx(10 nm)/Ag(10 nm)/Al(70 nm) was deposited by thermal evaporation in vacuum.

2.3. Device Characterization

Using a xenon-lamp solar simulator (Spectra Physics, Oriel Instruments, USA) Current density-voltage (J-V) measurements were performed. Simulated AM 1.5 global solar irradiation (100 mW/cm2) was used for the measurement. Prior to the measurement the light source was calibrated with a standard Si photodiode reference cell (Hamamatsu Photonics, Japan).

3. Results and Discussion

3.1. Annealing Temperature Effect on ZnO Thin Films and Corresponding Solar Cell Performance

In the inverted structure, electrons get transferred to the ITO/ZnO from PC61BM, and holes travels towards to the MoOx/Ag/Al anode from P3HT. Organic stabilizers monoethanolamine (MEA) which was used during ZnO film formation, was removed by a short UVO treatment before the deposition of the active layer (P3HT: PC61BM). The removal of the stabilizer results in increased electronic contact between the ETL and the active layer improving the solar cell efficiency [38] - [40] . The oxygen atom vacancies are filled by prolonged UVO treatment which reduces the number of free electrons in the conduction band, which has an adverse effect on the device performance [41] .

Table 1 shows the data for the inverted solar cell devices fabricated at different temperatures using solution processed and annealed ZnO layers. The OSCs utilizing ZnO ETL annealed at 50˚C exhibited a PCE of 1.3% with a VOC of 0.6 V, a ISC of 1.6 mA, FF of 27.8%. The OSCs fabricated with ZnO layers annealed at 150˚C showed significant improvement in the PCE by ~70% to 2.2% (VOC = 0.60 V, ISC = 1.7 mA, and FF = 41.7%). However for higher temperature anneals of ZnO layers, there was a continuous depreciation of the PCE.

The parameters RSH and RS are two important parameters to explain the device characteristics of the solar cells. For ideal case the series resistance is close to zero and the shunt resistance should approach a large value. Based on the data, a hypothesis is made that heat treatment can modify the surface properties of the ZnO layer. When the ZnO layer was annealed temperature ranging from 50˚C to 150˚C, the value of RS of the device decreases and the PCE increased. However, a further increase of the annealing temperature decreases the value of RSH. This happens due to the higher leakage current resulted from higher surface roughness of ZnO ETLs. Table 1 reveals that excessive annealing of the ZnO layer deteriorates the device performance.

Both the donor/acceptor (D/A) and electrode/photovoltaic (E/P) interface plays important role in developing high-efficiency organic solar cells. The D/A interface is accountable for charge recombination, along with charge dissociation. And the E/P interface is responsible for charge collection to reduce the charge accumulation in generating photocurrent. The conductivity of specific charge carrier is represented by series resistance and the shunt resistance is due to the recombination of charge carriers at the D/A interface.

In organic solar cell structures smooth surface facilitate a uniform interfacial contact between the ETLs and active layers. This leads to an increase of the electron collection efficiency. Inspection of the samples after 150˚C and 450˚C anneals, divulges that the ZnO layer annealed at 450˚C is comparatively rougher. It has a root-mean square (rms) roughness value of 5.7 nm. The ZnO film that is annealed at 150˚C has an rms roughness value of 2.2 nm.

3.2. Effect of Yttrium Doping of ZnO Thin Films on the Efficiency of OSCs

Previous studies showed that doping with yttrium ions decreases the resistivity of ZnO films; however, excessive doping leads to an increase in the resistivity of the films [42] . Donor Y3+ ions substitute onto Zn2+ lattice sites at low doping concentrations. This results in an increased number of charged carriers and provides the initial reduction in resistivity. However the dopant concentration is increased to higher levels, the increased impurity―scattering from the dopant ions dominates and the resistivity starts to rise. Hence, different concentrations of the Y3+ are added to the zinc oxide precursor solution and spin coated on top of ITO layer to observe the effects of doping. Figure 2 shows the UV-Vis absorption spectra of various YZO thin films. It is also clear from the figure that the transmittance spectra have no significant difference regardless of the amount of yttrium added. In the visible region all the films have good optical transmittance. YZO films are very thin and could be considered as completely transparent which could be the reason behind this.

4. Equivalent Circuit Diagram

Most of the solar cells are semiconductors with a p-n junction fabricated in a thin wafer or layer of semiconductors. When solar cells are exposed to light electron-hole pairs are generated which results in the generation of

Table 1. Device parameters of ZnO based inverted organic solar cells under illumination (average of five devices).

photo current In the dark the I-V characteristic of a solar cell have an exponential characteristic similar to that of a diode. The terminal current ID of an idealized diode without resistance may be described in mathematical terms by Shockley’s equation:

(1)

where, V is the terminal voltage, I0 is the reverse current, n is the so-called diode quality factor, k is Boltzmann’s constant, T is temperature, and q is the charge of an electron. Figure 3 represents the equivalent circuit model of a diode with parasitic series resistance. The terminal current of the equivalent circuit is given by the following equation:

. (2)

The simplest model to understand the characteristics of organic solar cells is the single diode model. Figure 4

Figure 2. Optical transmission spectra of sol-gel prepared zinc oxide and yttrium doped zinc oxide layers on ITO coated glass substrates.

Figure 3. Equivalent circuit model of a single diode with a parasitic series resistance.

Figure 4. The equivalent circuit diagram of single diode model.

shows the equivalent circuit diagram of a single diode model with series resistance and shunt resistance. The generation of current upon illumination is represented by the current source. The built in field due to the difference between the donor HOMO and acceptor LUMO level creates and asymmetry of conductivity which is represented by a voltage dependent resistor or the ideal diode D.

Using the Shockley diode characteristics equations mentioned above in Equation (1). The voltage dependence of current can be given by Equation (3), where IL is the photo current.

. (3)

While the diode D is in the dark so that RSH = ∞, RS = 0, then from Equation (3) we get Equation (1). The open circuit voltage is obtained setting the output current zero (I = 0), and is given by Equation (4)

. (4)

In previous studies a two diode model consisting of an extra diode showed more accurate results in describing the characteristics of the organic solar cells. The equivalent circuit of the two diode model is shown in Figure 5. Holes at the ITO electrode from an extra blocking contact that can affect the IV cure in the third quadrant. The second diode represents the effect of this blocking contact. Using the Shockley diode equations we obtain:

. (5)

Setting I = 0 we get the equation for VOC which is

. (6)

In a previous study, we proposed a two diode model with an extra resistance connected in series with the diode based on the device behavior with the change of series and shunt resistance [23] . We used the model to describe the electrical characteristics of PCBM and P3HT based organic solar cell with an added interfacial layer of AgOx in between PEDOT:PSS and ITO. Figure 6 is used to describe the electrical characteristics.

Figure 5. The equivalent circuit diagram of two diode model.

Figure 6. Proposed equivalent circuit model for the inverted organic solar cell.

In this proposed model, the shunt resistance in series the diode D1 represents the shorts due to significant conductivity of the bulk material and the pinholes. The recombination losses near the electrodes may also be accounted by this resistor. If RS is considerably smaller than both of the shunt resistance, the effect of RS1 can be considered with RSH. The shape of FF and VOC of the I-V curve virtually remains unchanged for very high value of RSH. And for negative bias the current has significant field dependency. However, smaller values of RSH reduce VOC and the FF reaches its theoretical minimum.

The main difference between the conventional and inverted organic solar cells is there device structure. The both exhibits same type of electrical characteristics. And both the D/A and E/P interface have critical effect on their efficiency. Based on our experimental results we used the above model to explain the electrical characteristic of the inverted organic solar cell. The I-V characteristics curve from simulation and experimental data is shown in Figure 7. In Figure 8, the I-V characteristics curve for 1.0% at. Y-doped ZnO is shown along with the proposed model and other previously discussed models. Figure 8 shows that proper correlation is achieved between the experimental and simulated I-V plots. And it is clear from Figure 8 that our previous proposed model can successfully describe the electrical characteristics of Y-doped ZnO inverted solar cells. Table 2 shows the data for inverted organic solar cells fabricated at different concentration of yttrium, using solution

Figure 7. Current-voltage (I-V) characteristics of the ZnO and Y doped ZnO based OPV devices under 100 mW/cm2 illumination (device area is 0.2 cm2).

Figure 8. Current-voltage (I-V) characteristics for 1% at Y-doped ZnO based OPV device and different equivalent circuit models under 100 mW/cm2 illumination (device area is 0.2 cm2).

Table 2. Device parameters of ZnO based inverted organic solar cells under illumination (average of five devices).

processed and annealed ZnO layers.

The efficiency of the inverted organic solar cell fabricated with 1.0 at. % Y-doped ZnO exhibited the best photovoltaic performance among all the devices, with PCE of 2.9%, I of 2 mA-cm−2, VOC of 0.6 V and FF of 49.3%. There was only 1.2% variation between the simulated and experimental I-V plots.

5. Conclusion

In this work we shown, the performance of ZnO ETLs in P3HT:PCBM inverted solar cell structure with optimized annealing conditions. It was found that for sol-gel processed ZnO annealing condition, the ZnO layer played a dominant role in determining the solar cell device performance. Further our work reports that yttrium doping into ZnO can improve the PCE of organic solar cells even more. Yttrium into zinc oxide layer resulted in a 30% improvement of PCE. Lastly, an equivalent circuit diagram was proposed to explain the characteristics of the device. A comparison between the experimental and simulated I-V curve was also shown. It was reported that this device correlates with the proposed equivalent circuit model from our previous study.

Acknowledgements

This research was partially supported by the National Science Foundation (C. Ying, Grant No. DMR-0902277).

Conflicts of Interest

The authors declare no conflicts of interest.

Cite this paper

Hossain, N. , Das, S. and Alford, T. (2016) An Approach to Equivalent Circuit Modelling of Inverted Organic Solar Cells. Circuits and Systems, 7, 1297-1306. doi: 10.4236/cs.2016.78113.

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