1. Introduction

In the present era, the leading role in the increase of renewable energy production on a global scale is played by the public company sector of the European Union (EU) and is represented by 20% of energy needs based on renewables reached by national targets [1,2]. In the near future, the EU could become a global leader in renewable energy (see the revised “Directive of the European Parliament and of the Council on the promotion of the use of energy from Renewable Sources” [3]) and would ensure at least 27% renewables (RE) in the final EU energy consumption and possibly 35% RE in the total energy consumption by 2030. Taking into account that the photovoltaics (PV) could have a leading role in the RE global scale, their cost would drop significantly [4]. The number of PV installations would be increased and that would drive the cost of PV down. Based on essential reports of (1) the International Energy Agency Photovoltaic Power System Programme (IEA PVPS) [5]; (2) the Renewable Energy Policy for the 21st Century (REN21) [6]; and (3) Joint Research Centre (JRC) of the European Commission (EC) [7], the PV market is growing more and more, especially in China and India. A very good example is highlighted by the organic photovoltaic (OPV) technology that could compete with the conventional technologies in both roof- and ground-mounted systems [8]. The gap between theoretical limits of solar cell efficiencies and those determined at the laboratory scale, as well as at the industrial level, has obtained an increased incentive that would allow the experimental efficiencies to reach the calculated theoretical limits. At the same time, new materials for advanced solar cells with an emphasis on cost, performance, and environmental aspects were developed [9,10]. Metal oxide heterojunction tandem solar devices could be considered more advantageous in comparison with DSSC and OPV solar cells due to their very good qualities (accessible, non-expensive, non-polluting, and easy exploiting) [11]. Cuprous oxide (Cu₂O) is a very attractive candidate based on its special features: direct forbidden bandgap, strong absorption of visible light, and high minority carrier diffusion length [12,13]; it could act as an efficient solar absorber layer. An important drawback of such a layer is determined by its intrinsic defects (copper vacancies and oxygen interstitials), as well as low solubility of doping impurities [14]. c-Si-based tandem solar cells are of special interest for the PV community. However, some types of top solar cells have clear qualities but also present certain drawbacks. III-V/Si tandem solar cells exhibit important high efficiency and stability, but have a high manufacturing cost. Perovskites/Si tandem developed rapidly and achieved 30% efficiency, but present low stability in an outdoor environment. That is why Cu₂O/Si tandem has an acceptable high theoretical efficiency, decent stability, earth-abundant raw material to reduce costs, and development prospects based on good device performance.

Special research was explored to find corresponding n-type oxides for heterojunction Cu₂O-based solar cells [15,16,17]. A very interesting tandem heterojunction solar cell configuration is represented by a ZnO(AZO)/Cu₂O top sub-cell combined with a c-Si bottom sub-cell [18,19]. The main merits of a such a combination would be (1) large scale availability; (2) non-toxicity; (3) plenty of material. The remarkable qualities of a ZnO layer could be defined by (1) direct band gap of 3.3 eV; (2) large exciton binding energy of 60 meV at room temperature; (3) high electron diffusivity; (4) high electrical conductivity.

The exciton binding energy of 60 meV at room temperature is a unique property of ZnO. This means ZnO can emit light effectively. It is remarked that for emitted material, the larger exciton binding energy, the stronger the interaction between the electron and hole. It means the rate of emitted recombination is easier and therefore this is an important property when it is considered optical material.

Thin film solar cells based on Cu₂O/ZnO heterojunction were selected as an excellent candidate for future generations of solar cells with a maximum reported conversion efficiency of 8.1% [20,21] and an estimated theoretical efficiency of 30% depending upon the optical absorption, E_g, carrier transfer, and luminescence efficiency of the top sub-cell [22,23].

Copper oxide semiconducting material including its band structure and the method of the production of Cu₂O has a high applicability for solar cells [12,13,16,18,19,20,24]. A deep analysis reveals that (1) the high resistivity of starting material is responsible for the low value of electrical power conversion efficiency of Cu₂O-based solar cells. (2) Non–existence of a technique of doping Cu₂O to obtain a low resistivity n-type semiconductor allows conversion efficiencies greater than 2% for p-n homo-junction Cu₂O solar cell to be fabricated. (3) A copper copper-rich or oxygen-deficient surface makes all Schottky barriers essentially a Cu/Cu₂O structure. The copper oxide-based semiconductors fulfill the most important criteria of the future progress: availability, sustainability, non-toxicity (elements of hope), and ease of synthesis.

The organization of this paper is based on the correlation of the following essential HTSC items, namely: (1) solar device architecture; (2) fabrication techniques of Cu₂O, ZnO and Cu₂O/ZnO heterojunction; (3) characterization of Cu₂O and ZnO layer structures; (4) modelling and simulation (electrical and optical) of HTSC with Cu₂O/ZnO heterojunction; (5) stability and reliability approach.

The main objective of this article is determined by a unified approach of HTSC with the stress on three main features: (1) fabrication and characterization of Cu₂O and ZnO structures; (2) numerical modelling; and (3) stability and reliability.

Another objective is to highlight the N-doped cuprous oxide heterojunction solar cell as a promising candidate for high-efficiency solar devices.

2. Fabrication Techniques and Device Architecture

2.1. Basics on Tandem Devices

The maximum absorbed solar energy can be obtained by stacking several tandem junctions with different bandgaps.

The maximum theoretical conversion efficiency of corresponding solar tandem devices is:

(a) 44% (two junctions), 54% (three junctions), and 66% (infinite number of junctions) for non-concentrated solar radiation [25];

(b) 55% (two junctions), 63% (three junctions), and 86% (infinite number of junctions) for concentrated solar radiation [26].

Multi-junction experimental tandem solar cells presented a high conversion efficiency of: (a) 46% with four junctions and concentrated solar radiation, and (b) 38.8% with four junctions and non-concentrated solar radiation [27].

The best possible ZnO/Cu₂O tandem heterojunction would be obtained with an optimized Cu₂O layer deposited on glass substrate under different conditions [24].

2.2. Device Architecture

One of the main directions for the development of high-efficiency solar cells is research on HTSCs based on silicon and metal oxides. Figure 1 presents the device structure of two Quartz/AZO(ZnO)/Cu₂O sub-cell patterns with copper contacts.

Reactive MSP of metal oxides on a transparent glass (quartz) substrate realizes the ZnO/Cu₂O sub-cell allowing low energy photons to be transmitted through the top AZO (ZnO)/Cu₂O sub-cell for corresponding absorption in the bottom c-Si sub-cell. The ZnO/Cu₂O top sub-cell deposited on the glass encapsulates the c-Si bottom sub-cell (see Figure 2). In Figure 3, a schematic device design of a four-terminal tandem solar cell combines into a stack a conventional Si sub-cell with a ZnO/Cu₂O sub-cell. The four-terminal tandem solar cell compared to the conventional two-terminal solar cell contributes to the increase of current density and conversion efficiency.

A device called the IBSC (Intermediate Band Solar Cell) was proposed for the increasing of maximum theoretical efficiency of solar cells. Nitrogen is a good dopant that could be used to make an IB material from Cu₂O. It should be simple to dope the Cu₂O with nitrogen in a large concentration, and it has been shown to be a good p-type dopant.

Nitrogen-doped cuprous oxide is the selected candidate material with an intermediate band, in conjunction with ZnO, respectively, ZnO/N: Cu₂O. The obtained major challenges would be (1) the production of monocrystalline Cu₂O; (2) low resistivity of Cu₂O; and (3) charge transport and recombination at the AZO/Cu₂O interface. Cu₂O and AZO have to be deposited with high crystalline quality and low resistivity [24]. Cu₂O and AZO thin films are deposited on quartz substrates by (DC/RF) MSS. Cu₂O is deposited by reactive sputtering of a Cu target in O₂/Ar with 400 °C substrate temperature, and fixed power density. To improve the optical and electrical properties, the grown Cu₂O films are annealed at 900 °C in vacuum. AZO is deposited by co-sputtering of pure ZnO ceramic target and Al target in Ar with 400 °C substrate temperature [28].

2.3. Cu₂O Fabrication Techniques

The reported Cu₂O-based structures have employed Cu₂O sheets realized by Cu thermal oxidation [29].

Cu₂O films could be deposited by different methods, respectively: Magnetron Sputtering (MSP) [30], Electro-Chemical Deposition (ECD) [31], Plasma-enhanced Atomic Layer Deposition/Pulsed Laser Deposition (ALD/PLD) [32,33], Photochemical Deposition [34], Metal Organic Chemical Vapor Deposition (MOCVD) [35], sol-gel technique [36], and others. Presented shortly are a few Deposition Methods, including their Advantages and Disadvantages.

• A.. Pulsed Laser Deposition (PLD) [37]

Pulsed Laser Deposition (PLD), also known as Pulsed Laser Ablation (PLA), uses a laser to bombard the surface of the target, raising its surface temperature and further producing high temperature and high pressure plasma (T > 104 K), depositing on different substrates to form a film. Advantages: (a) It is easy to obtain by PLD multi-component film of desired stoichiometric ratio. (b) It has high deposition rate, short test period, and low substrate temperature. (c) The process is simple and flexible with great development potential and great compatibility. (d) The process parameters can be arbitrarily adjusted. Multi-target components are flexible. (e) It is easy to clean and prepare a variety of thin film materials. (f) PLD uses UV pulsed laser of high photon capability and high energy density as energy source for plasma generation, so it is non-polluting and easy to control. (g) PLD is suitable for applications in microelectronics, sensor technology, and new material films. Disadvantages: (a) For several materials, there are molten small particles or target fragments in the deposited film, which are sputtered during the laser-induced explosion and reduce the quality of the film. (b) The feasibility of the laser method for large area deposition has not been proved yet. (c) Average deposition rate of PLD is slow.

• B.. Magnetron Sputtering (MSP) [38]

Magnetron sputtering is the main thin film deposition method for manufacturing semiconductors, disk drives, CDs, and optical devices. Advantages: (a) The deposition speed of MSP is fast, the requirement of substrate temperature rise is low, and the damage to the film is small. (b) For most materials, they can be coated by MSP. (c) The bonding performance between the thin film and the substrate obtained by MSP is good. (d) The thin film obtained by MSP has high purity, good density, and good film formation uniformity. (e) The repeatability of the MSP is good, and a thin film with a uniform thickness can be obtained on a large area substrate. (f) The thickness of the coating and the particle size of the constituent thin film can be controlled by changing parameter conditions. (g) Different metals, alloys, and oxides can be mixed and sputtered on the substrate at the same time. (h) It is easy to realize industrialization.

Disadvantages: (a) The sputtering gas, argon, emits a strong light blue glow forming a halo. The target under the halo is severely bombarded by ions, and a ring-shaped groove is sputtered. (b) The plasma is unstable. (c) Low temperature and high-speed sputtering of ferromagnetic materials cannot be realized. It is not possible to add an external magnetic field near the target.

• C.. Metal Organic Chemical Vapor Deposition (MOCVD) [39]

MOCVD is a coating process that uses metal ions to create thin film oxides. It can be used to create lead-based ferroelectric layers. The deposition source is a complex metal organic ligand; MOCVD allows extremely low-cost production of lead-based ferroelectric layers. Advantages: (a) thin film oxide deposition; (b) design of improved precursors; (c) lead-based ferroelectric layers for uncooled thermal images; (d) preparation of complex ferroelectric oxides. Disadvantages: (a) MOCVD precursors are very hazardous and toxic. (b) They are formed of highly toxic and hybrid gases due to the formation of phosphine.

• D.. Plasma-enhanced Atomic Layer Deposition (ALD) [40]

Atomic Layer Deposition (ALD) [41] is an ultra-thin film deposition technique that has found many applications due to its special abilities, namely: (1) uniform deposition of films with controllable thickness, and (2) improvement of the efficiency of electronic devices. This technology has attracted significant interest, both for new functional materials to be synthesized by ALD, and for several practical applications, such as advanced nano-patterning in microelectronics, energy storage systems, desalination, catalysis, and medical use. Advantages: (a) Experimental approaches that affect the deposition and present simulation, such as molecular dynamics and computational fluid dynamics. It would predict the optimization of ALD processes and would determine the reduction in cost, energy waste, and adverse environmental impact. (b) The copper oxide films are deposited on silicon substrates by reactive r.f. MSP at 400 °C. (c) The film thickness is measured by ellipsometry [29,42]. (d) Potential applications for Cu₂O films include specific devices, such as p-Cu₂O/n-ZnO photodetectors [38] and solar cells [20,39]. (e) After rapid thermal annealing at 900 °C, the electrical properties of Cu₂O film on quartz are improved by Hall effect measurements [40].

2.4. ZnO Fabrication Techniques

ZnO is a naturally abundant material which crystallizes either in zinc blende (fcc) phase or wurtzite packed phase. The measured photovoltaic properties of ZnO/Cu₂O HTSC fabricated with thin films deposited on substrates depend on the target orientation, perpendicularly/parallel to the target [43].

AZO thin films are deposited via spin coating technique onto glass substrates at 3000 rpm. An undoped ZnO precursor solution is prepared by dissolving acetate dehydrate [ZnAc:(Zn(CH3COO)22H2O)] in 2-proponal and diethanolamine (DEA, C₄H₁₁NO₂) [44]. Experimental ZnO thin films are deposited by ALD technique at 200 °C. ZnO thin films are grown on Si and fused quartz (SiO₂) substrates [45]. ZnO as n-type semiconductor is one of the most relevant combinations of II-VI (A^IIB^VI) [46].

The physical properties of ZnO thin films prepared by MSP are significantly affected by growth parameters such as gas pressure, time, target-to-substrate distance, deposition power, type and substrate temperature, and annealing temperature. The films’ temperature and the substrate type on the growth influence the crystal structure, as well as morphological and optical properties of ZnO thin films [46]. ZnO presents essential properties such as high transparency, high electrical conductivity, and high reflectance in IR.

2.5. Fabrication of Cu₂O/ZnO Heterojunction

The challenges associated with Cu₂O/ZnO Tandem Heterojunctions (see Table 1) can be identified as follows: (a) They are made under ambient conditions. (b) The measures to reduce Cu₂O instability result in PCE above 2%. (c) A higher quality interface in the optimized devices improves the open-circuit voltage three-fold.

Patent WO2019058605A1 [66] presents a multi-junction tandem solar cell with improved efficiency and a Cu₂O absorbent layer. It includes: (1) a first electrode, (2) a light absorption layer, (3) an n-type layer, and (4) a second electrode. The light absorption layer is between the first electrode and the n-type layer; the n-type layer is between the light absorption layer and the second electrode.

3. Characterization of Cu₂O and ZnO Layer Structures

3.1. Characterization of Cu₂O Layer Structure

3.1.1. Basic Information

Cu₂O is one of the most efficient metal oxides for PV applications. It is a natural p-type semiconductor with a band gap of 2.1 eV. Nitrogen doping in Cu₂O would reduce resistivity and improve hole concentration [67]. Cu₂O thin films were deposited on quartz and silicon substrates by d. c. MSP system [68].

The layer structure of Cu₂O: N thin film samples is presented in Table 2 [42].

3.1.2. Morphological Characterization of the Cu₂O: N Thin Films

The surface morphology of the Cu₂O: N thin films could be analyzed by SEM with a scanning electron microscope, while the topographic imaging could be performed by AFM with an atomic force microscope.

• A.. Scanning Electron Microscopy (SEM)

The SEM images of four samples (see Table 2) are shown in Figure 4: one undoped Cu₂O film (Sample 0) and three Cu₂O: N thin film samples (Samples 1–3) [42].

• B.. Atomic Force Microscopy (AFM)

The grain size, including surface roughness of Cu₂O: N thin film deposited on quartz substrate, is measured by AFM topographic imaging. The surface morphologies for each of the N-doped thin film samples compared to Sample 0 are shown: (1) in Figure 5a as 2D AFM images, together with their corresponding profile histograms, and (2) in Figure 5b as 3D AFM images. The root-mean-square surface roughness (R_RMS) for each sample is extracted from their AFM images [69,70].

The histograms represent the statistical distribution of the height surface profile of the Cu₂O samples derived from the AFM images. Samples 1, 2, and 3 present the highest frequency at a surface height of 26 nm, 25 nm, and 17 nm, respectively. R_RMS and Height Distribution Standard Deviation are resulted from the histograms based on the 2D AFM images, processed in MATLAB, and presented in Table 3 [42].

The undoped Cu₂O film (Sample 0) presents a greater roughness than the doped Samples 1–3. Sample 1 presents the highest deviation and Sample 3 has the lowest one using the doped samples.

3.1.3. Structural Characterization by XRD of the Cu₂O:N Thin Films

The XRD patterns of the four samples recorded in the range 30–60° were obtained by a diffractometer (see Figure 6); all films are dominated by two reflection peaks. The XRD patterns are not significantly influenced by nitrogen doping [53].

The Cu₂O peaks are determined by comparing experimental XRD peak patterns with the ICDD patterns (standard Powder Diffraction cards) [71,72].

3.1.4. Optical Characterization of the Cu₂O:N Thin Films

Optical characterization is carried out by (1) FTIR spectroscopy analysis using a Perkin–Elmer spectrometer, and (2) spectroscopic ellipsometry (SE) using a spectroscopic ellipsometer. The refractive index and extinction coefficient of Cu₂O: N thin films in the range from 190 to 2100 nm could be determined based on SE.

• A.. FTIR Spectroscopy characterization.

Figure 7 shows the FTIR transmission spectra obtained for Cu₂O: N thin films. Table 4 lists the transmission peaks [42].

The FTIR spectra of all samples deposited on quartz show the peaks corresponding to the vibrational modes of Si-O that belong to the quartz substrate [72,73]. An increasing trend is remarked in the intensity of the Cu₂O:N absorption band from Sample 1 to Sample 3, determining an increased concentration of N₂, in good agreement with the recent predictions [74]. The decrease in resistivity and increase in N-doping concentration is explained by annealing-driven substitution of O atoms with implanted N atoms; N doping may induce any variation in energy band structure of Cu₂O films [71]. The photoluminescence (PL) spectra of Cu₂O films contain two main signals ranging from 450 to 650 nm [75].

• B.. Spectroscopic Ellipsometry (SE) Characterization

The investigated spectroscopic ellipsometry (SE) parameters of Cu₂O:N thin films in the range 1.5–4.1 eV are (1) the band gap, and (2) the surface roughness [76,77], see Table 5.

Using the Tauc–Lorentz oscillator modelling [78], the following parameters can be determined: (1) the band gap, (2) the surface roughness, (3) the refractive index (n), and (4) the extinction coefficient (k) in the range 300–800 nm (from VIS to near IR) for Cu₂O thin films deposited on quartz substrates.

The surface roughness of Cu₂O films increases with the level of N₂ pressure (see Table 5). The presence of N₂ during deposition of Cu₂O films on quartz substrate produces small changes over n and k in the range 300–600 nm for Samples 1–3, see Figure 8.

In Figure 8 for Sample 2 (the highest N-doped sample), the changes in n(λ) (yellow curve) and k(λ) (green curve) associated with a structural change in Cu₂O induced by nitrogen doping could be seen. This could be a promising method for modifying the optical properties of the metal oxide [75,79]. The crystal size decreases with the increasing of the N-doping concentration in the small N-doping range [72,75].

3.2. Characterization of ZnO Layer Structure

3.2.1. The Structural Properties of ZnO Nanostructures

For bulk ZnO, structural characterization by X-ray diffraction (Figure 9a) reveals peaks belonging to Zn [80], up to 500 °C; at 700 °C, small peaks of ZnO would appear [81]. For the non-annealed ZnO thin film, the X-ray diffraction patterns (Figure 9b) show four peaks that belong to Zn and are compatible with the crystal structure [82,83]. Up to 900 °C, the structure of ZnO thin films is hexagonal; at 1100 °C, the defects change the structure to a cubic one and the peaks in the X-ray spectrum shift. X-ray diffraction gives information about the crystalline and structural properties of thin films such as: lattice constants, particle size, displacement density, and microcontroller [84].

The best ways to study ZnO morphology are (1) the size; (2) the shape; and (3) the placement of particles on the body surface [85]. For the thin films, it shows that the synthesized nanoparticles are spherical and uniform in size (Figure 10a); by increasing the temperature, the oxidation of the films and the size of the crystalline grains decrease. The AFM images of the samples (Figure 10b) show that the surface morphology changes as the temperature increases; the surface roughness and average surface height increase. Different properties of bulk samples and thin films, such as roughness and surface morphology, depend on their crystal structure.

3.2.2. Optical Properties of ZnO Thin Films

• A.. UV-VIS Spectroscopy

The effects of annealing temperature on the optical properties of ZnO thin films, namely absorbance and transmittance in VIS and UV, are investigated. The UV absorbance increases due to the increase in the annealing temperature and the spectrum shifting towards shorter wavelengths (Figure 11a); it is obtained by the decrease of the particle size and the increase of the energy bandgap. The transmittance is strongly affected by the annealing temperature and increases sharply in the VIS. Also, in the UV, the transmittance (Figure 11b) decreases to a minimum; a strong interaction is indicated between the incident light and the material electrons; light scattering is caused and particle size increases grain area as well as reduced light transmission.

• B.. Photoluminescence (PL) Spectroscopy

Photoluminescence (PL) and UV–VIS absorption measurements can be performed at room temperature. The PL spectrum shows that the relative intensity of UV and defect bands depends on the length of ZnO nanorods. The peak of PL of UV band around 395 nm is strongly enhanced when the length of ZnO nanorods is reduced. PL spectrum of ZnO nanostructures is defined by emission bands observed in UV and VIS. The UV peak is a characteristic of ZnO emission, and the VIS light emission density is much higher [87]. For PL spectroscopy, the intensity of UV peaks increases by increasing of the annealing temperature (Figure 12); the intensity of peaks in VIS is low and strong exciton emission indicates that ZnO nanoparticles have a minor defect.

• C.. Determination of Optical Constants

High transparency of transmittance over the VIS makes it possible for ZnO to be used in solar cells. It is essential to know the optical parameters of thin films, especially the refractive index and extinction coefficient [86]. Figure 13 proves the following graphs: (1) extinction coefficient, (2) refractive index, and (3) real and imaginary parts of the complex dielectric function of prepared thin films. The extinction coefficient is the lowest for ZnO and the highest for n-anneal in VIS. Refractive index decreases in the transparent region (long wavelengths) and increases in the absorption region (short wavelengths). Real and imaginary parts of the dielectric function feature a decreasing trend in the transparent region. The absorption area expands toward shorter wavelengths. The extinction coefficient, refractive index, and real and imaginary parts of the dielectric function enhance in tandem with the increasing of the annealing temperature, up to 900 °C. The optical conductivity of nanoparticles is presented in terms of the landing photon energy (Figure 14). Higher values of optical conductivity indicate that the grown ZnO thin film has high potential to be used as an optically conducting material [88].

4. Merits and Comparative Analysis of AZO/Cu₂O HTSC

4.1. Merits of AZO/Cu₂O Heterojunction Tandem Solar Cells (HTSC)

The highest experimental efficiency of ZnO/Cu₂O HTSC determined so far is 5.38%, see Minami et al. [52], by depositing firstly a Ga₂O₃ buffer layer and secondly an AZO layer by PLD on Cu₂O layer. This is far from the theoretical conversion efficiencies of Cu₂O and ZnO, which are 20% and 18%, respectively. The most prominent challenges that are identified are tied to the material quality of the Cu₂O layer, namely high resistivity and low crystallinity, as a result of Cu₂O contamination at the surface. The surface defects on the Cu₂O lead to unwanted charge transport and recombination at the heterojunction interface. These challenges can be mitigated by growing crystal Cu₂O, both to decrease interface defects, and to increase conductivity.

4.2. Comparative Analysis of HTSC with Other High Performance Solar Cells

A comparative analysis of efficiencies and device characteristics for solar cells with the highest certified efficiency to date concerning: DSSCs, PSCs, OPVs, and Tandem PSCs (HTSC) is discussed based on the data in Table 6 [89]. Advanced techniques and research trends can be examined from the perspective of (1) novel materials, (2) device modelling, and (3) innovative device structures. The comparative advantages and limitations of these photovoltaic technologies are evaluated in terms of (1) device efficiency, (2) durability, (3) ease of fabrication, and (4) performance–price ratio.

5. Numerical Modelling of Heterojunction Tandem Cu₂O/ZnO Solar Cells

5.1. Multiscale Modelling of PV Technology

The computational modelling approach of PV technology is developed based on the following items: (1) material properties; (2) nanoscale structures defined by dynamical electronic, thermal, and optical properties, and interface processes that determine mesoscale methods; (3) solar PV devices (solar cells); and (4) industrial applications represented by PV systems. The analysis of nanoscale structures based on electronic, thermal, and optical properties together with their influence on solar cells’ characteristics involves a multiscale modelling (defined by: atomic scale, mesoscale, µm and cm to meter scale), and characterization, see Figure 15 [90,91,92]. In the following paragraphs of this section, the analyzed solar cell (µm scale), respectively, the Heterojunction Tandem Cu₂O/ZnO solar device, is discussed based on numerical modelling.

5.2. Diagram of the Cu₂O/ZnO Solar Cell Simulation Model

A diagram of the simulated model for Cu₂O/AZO tandem heterojunction solar cell is represented in Figure 16. This solar cell structure includes (1) a quartz glass superstrate; (2) an AZO n+ emitter layer; (3) a Cu₂O p-type absorber layer; and (4) a bottom Cu₂O: N layer.

5.3. Simulation Methodology

Numerical modelling of the Cu₂O/ZnO(AZO) can be studied based on three simulation software packages, namely Silvaco Atlas, MATLAB, and Quokka 2. The simulated solar cell is analyzed for two sub-cells: (1) Cu₂O/ZnO(AZO) top sub-cell; (2) c-Si bottom sub-cell.

The best simulators used for solar cell design and material performance optimization are Silvaco Atlas and PC1D. Silvaco is an efficient tool for the top sub-cell and absorbs the high solar energy part while PC1D is an optimum tool for the bottom sub-cell and absorbs the low solar energy part. The simulated device with optimized parameters can be compared with the experimental industrial metal oxide solar cell; based on this comparison, the validation can be done.

The large current mismatch between the two sub-cells, caused by the large band gap difference for the two absorbers, allows the optimization of the top and bottom sub-cells and defines the arrangement of a four-terminal configuration. This approach can increase the conversion efficiency of the tandem heterojunction ZnO/Cu₂O silicone solar cell beyond the limit of the conventional c-Si solar cell.

A 4T tandem SC can be connected to two loads such that each sub-cell always operates at its maximum power point (MPPT). This MPPT maximizes energy production and requires additional current collection which would decrease performance. An idealized 4T tandem SC with no resistive or optical losses serves as an upper limit for performance. 4T SC must also be designed to operate such that the top and bottom sub-cells are electrically isolated, which may introduce additional optical losses and series resistances.

The excellent performance of idealized 4T tandem SCs and current-matched 2T tandem SCs is highlighted. Similar trends are seen for both the energy-harvesting efficiency under a set of spectra, and power-conversion efficiency under the AM1.5G spectrum. This analysis can be extended to different locations with different climates, and different sub-cell materials.

5.4. Electrical Numerical Modelling for the Two Sub-Cells of the HTSC

5.4.1. Electrical Modelling of the Top Sub-Cell

This numerical modelling is investigated using the Silvaco Atlas simulation package. The ZnO(AZO) is selected as the buffer layer; a buffer layer is required in a material system to obtain a large enough conduction band offset. The influence of defects [18,48,93,94,95,96] is discussed taking into account that an interface defect layer (IDL) is implemented.

Based on simulations, the following graphs are obtained: (1) the dependence of the AZO thickness on top sub-cell efficiency with an optimum AZO thickness of 0.25 µm, see Figure 17a; (2) the dependence of IDL thickness on top sub-cell efficiency (η), see Figure 17b; (3) the dependences of buffer electron mobility on top sub-cell fill factor (FF) and conversion efficiency (η), see Figure 17c; (4) the dependence of buffer and IDL affinity on top sub-cell efficiency (η), see Figure 17d.

The following is remarked:

• a buffer electron mobility value under 100 cm²/Vs would influence FF and η;

• a comparison of different buffer and IDL materials can be done from the point of view of their affinity. The optimal affinity interval for the buffer layer is 3.4–3.6 eV; it would define the lower conduction band offset with Cu₂O absorber layer. The optimal affinity interval for IDL is 2.95–3.4 eV.

5.4.2. Electrical Modelling of the Bottom Sub-Cell

This electrical modelling is studied based on the Quokka 2 software, version 2.2.5. The experimental results can be compared with the simulated ones. The J-V characteristics, experimental curve and simulated one, respectively, are presented in Figure 18a. At the same time, the experimental and simulated graphs of the external quantum efficiency (EQE) are plotted in Figure 18b.

The essential electrical parameters for the bottom (c-Si) solar sub-cell are obtained using the fitting of the experimental curve with the Quokka 2 simulated one; they can be used for control and prediction. In Table 7 four experimental electrical parameters for the bottom silicone solar sub-cell are presented.

5.5. Optical Numerical Modelling for the Top Sub-Cell of the HTSC

Optical characteristics for the top sub-cell, namely the reflectance, transmittance, and absorbance as function of wavelength for three samples of Cu₂O: N, can be obtained using OPAL 2 software [97,98,99]. The optical numerical modelling is performed in the wavelength range (300–800) nm, see Figure 19. For simulations there are implemented in the model: a 100 nm thick ZnO layer, a 2 µm thick Cu₂O layer, and a 50 nm thick Cu₂O: N layer. The simulated reflectance would be very useful for the evaluation of loss reflectance.

Based on the transmittance data, Tauc plots [100] for the three doped samples are estimated and presented in Figure 20. Tauc plots indicate an optical bandgap around 2.18 eV for all samples, in good agreement with the ellipsometry measurements (see Section 3).

6. Stability and Reliability Approach

6.1. Stability Aspects

The stability is an essential parameter of commercial HTSC and can improve its lifetime. The solar cell stability would require minimizing the influence of humidity, UV, and temperature effects.

The 55% humidity can diminish the solar cell performance by color change [101]. The moisture sensitivity of solar devices can be improved by suitable encapsulation techniques. The thermal stability of HTSC would be increased by use of polymers [102]. The research regarding the rain effect with water of variable pH based on the simulation with lead poisoning participation would allow consideration of safe solar cell use [103].

6.2. Methodological Tools for HTSC Reliability

There are three main accelerated tests to be considered for the reliability of a solar cell:

(a) Qualitative accelerated test: it is used for information regarding the HTSC failure ways;

(b) High Accelerated Life Test (HALT): it is used for information regarding the HTSC failure mechanism and lifetime;

(c) High Accelerated Stress Screening (HASS): it is used for information regarding the HTSC operating time and failure rate within the working temperature range.

A precise reliability analysis of HTSC could be done with the SYNTHESIS simulation package [100]. The following essential tools are used: (1) the Weibull++ tool, which allows the lifetime analysis; (2) the ALTA tool, which allows the analysis of accelerated life tests and degradation degree.

6.3. HTSC Thermal Stability Characteristics

Three main parameters can be discussed using the Weibull statistical repartition approach [104]: (1) the solar cell lifetime in different conditions; (2) the degradation degree influenced by temperature; and (3) the number of defects (failures).

The Weibull statistical repartition can be used for prediction of two essential parameters: solar cell lifetime (Figure 21a) and solar cell degradation degree based on temperature influence [105,106,107] under standard and stress conditions (Figure 21b).

Using the stress results of the HASS test, it would be possible to determine the following based on ALTA tool numerical simulations: (1) the operating time limiting value in normal conditions (Figure 22a); (2) the probable rate of solar cell failure within the operation temperature range of 50–100 °C (Figure 22b). It is seen that the expected failures’ rate dependence increases strongly with temperature.

The simulated results obtained using this reliability analysis consist of (1) identifying the solar cell failure modes; (2) prediction of the solar cell lifetime in normal operation conditions; (3) evaluation of the degradation time and number of defects for the analyzed solar cell.

Based on an experimental approach, it is remarked that the Cu₂O: N layer would be very stable when its annealing for 90 min does not degrade the nitrogen doping [108].

6.4. Reliability of HTSC Based on Si and ZnO

ZnO-based devices improve the reliability of different high performance SCs such as DSSC, Perovskite SC, or OPV SC [109].

The SCs based on ZnO /AZO layers have a good reliability; this feature is very useful for the reliability of HTSC. AZO layers are exposed to specific environmental conditions, namely: (1) high and low levels of temperature such as 100 °C and 20 °C, respectively; (2) high and low levels of humidity, such as 100% and 20%, respectively, or (3) all combinations of temperature and humidity characterized by unchanged microstructure, crystallinity, and optical properties.

7. Conclusions and Prospects

7.1. Conclusions

Based on the present review article, the following conclusions could be highlighted:

• 1.. Different authors published interesting review articles on HTSC based on Si and metal oxides that presented their own conception [110,111,112,113].

• 2.. There were discussed state-of-the-art power conversion efficiencies for HTSC, as well as a comparison analysis with other tandem solar cells such as PSCs.

• 3.. An unified approach of three main essential issues of HTSC was developed, respectively: (a) experimental evaluation based on fabrication and characterization of these solar devices; (b) their modelling and simulation in order to establish optimized solar cells; (c) thermal stability required for industrial applications of HTSC.

• 4.. It was analyzed that the HTSC device architecture stressed on four-terminal tandem configuration combines a conventional crystalline silicon sub-cell with a ZnO/Cu₂O sub-cell in a stack of independently connected cells.

• 5.. Cu₂O and ZnO layers could be deposited by different methods, namely: (a) magnetron sputtering; (b) electrodeposition; (c) pulsed laser deposition; (d) plasma deposition; (e) photochemical deposition; (f) atomic layer deposition a.o.

• 6.. Characterization of Cu₂O layer structure was defined by: (a) morphological and structural evaluation (SEM, AFM and XRD); (b) optical evaluation (FTIR Spectroscopy, Spectroscopic Ellipsometry). It was remarked that N-doped cuprous oxide heterojunction solar cell could be considered as a bright candidate for high-efficiency solar devices.

• 7.. Characterization of ZnO layer structure was determined by: (a) structural characterization (SEM, AFM, XRD); (b) optical characterization (UV-VIS Spectroscopy; Photoluminescence Spectroscopy).

• 8.. Numerical modelling of Cu₂O/ZnO HTSC was studied by: (a) electrical modelling and simulation stressing on J-V characteristics and EQE curve; at the same time, the influence of interface defects on the HTSC efficiency could be put in evidence; (b) optical modelling and simulation would be useful for optical losses’ optimization. The performant simulation tools, namely SILVACO and PC1D, could be of great interest for evaluation of optimized parameters.

• 9.. Stability and reliability approach was discussed. The degradation degree of analyzed solar cells, as well as the solar cell lifetime in normal operation conditions, could be established.

• 10.. Tandem Solar Cells like PSCs would be considered to be the most promising candidates for integrating with other systems to realize new innovative technologies. The next-generation applications of perovskite-based solar cells include tandem PV cells, space applications, PV-integrated energy storage systems, PV cell-driven catalysis, and BIPVs. The good stability of these devices would be the main challenge to be considered for future applications.

7.2. Prospects

The progress of high-efficiency HTSC with Si-based metal oxides and related perovskite tandem solar cells would contribute to remarkable prospects for these advanced solar devices [114,115,116,117,118]

(a) development of multi-terminal solar cells characterized by a control of interface properties that would allow the reduction of the contribution of defects.

(b) development of high-performance carrier-selective passivating contacts based on tunneling oxide layer combined with conductive organic polymer.

In spite of some drawbacks (these special SCs showed a degradation in performance due to an increased contact resistance at 300–400 °C), they are still maturing and have already shown many successful demonstrations with efficiencies higher than the 20% mark.

(c) development of Si-perovskite tandem solar cells with transition metal oxides as carrier selective contacts.

Using optimized tunnelling and carrier transport layers, efficiency can further be improved for integrated tandem solar cells pointing to practical implications of the proposed structure at an industrial level.

(d) development of reliable and efficient perovskite SCs that require a multilevel approach to optimize the performance of individual layers in each cell separately; the cells are linked together with the substrate.

Researchers at the US National Renewable Energy Laboratory have developed a new concept for manufacturing perovskite solar cells with high efficiency and excellent stability.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

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Figure 1. Solar top sub-cell patterns in the tandem structure [18].

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Figure 2. Method for laminating the Quartz/AZO/Cu2O to a c-Si bottom cell in order to form a device with four-terminal contacts [19].

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Figure 3. Schematic device design of a four-terminal tandem heterojunction solar cell combining a conventional crystalline Si as bottom sub-cell with a metal oxide top sub-cell based on ZnO and Cu2O layers [20].

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Figure 4. SEM images of Cu2O thin films deposited on quartz substrate: (a) Sample 0, (b) Sample 1, (c) Sample 2, and (d) Sample 3 [42].

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Figure 5. (a) 2D AFM images of Samples 0–3 and their corresponding histograms [67]; (b) 3D AFM images of Samples 0–3 [42].

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Figure 5. (a) 2D AFM images of Samples 0–3 and their corresponding histograms [67]; (b) 3D AFM images of Samples 0–3 [42].

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Figure 6. XRD patterns of Samples 0–3 in the range 30–60°, where ∆ represents the background peak [42].

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Figure 7. FTIR transmission spectra for Cu2O:N thin film: Sample 1, Sample 2, and Sample 3 [42].

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Figure 8. Graphs of n and k coefficients for Samples 1, 2, and 3 of Cu2O:N thin films; λ is wavelength [67].

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Figure 9. XRD patterns of Zn and ZnO bulk samples: (a) thin films [80]; (b) annealed at different temperatures [82].

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Figure 10. (a) SEM images of Zn and ZnO thin films annealed at the temperatures of 300, 500, 700, 900, and 1100 °C [85]. (b) AFM images of Zn and ZnO thin films annealed at different temperatures [46].

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Figure 11. The absorption (a) and transmittance (b) spectra of the prepared thin films [86].

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Figure 12. PL spectroscopy of Zn and ZnO nanostructured thin films [83].

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Figure 13. The extinction coefficient (a) refractive index (b) and real (c) and imaginary (d) portions of complex dielectric function of the thin films [86].

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Figure 14. Optical conductivity of the prepared nanoparticles in terms of energy of landing photon [88].

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Figure 15. Interesting scales in photovoltaics technology and corresponding quantities [90,91,92].

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Figure 16. Diagram of the simulated Cu2O/AZO solar cell [28].

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Figure 17. (a) AZO (Al: ZnO) thickness vs. top sub-cell efficiency; (b) interface defect layer (IDL) thickness vs. top sub-cell efficiency [93]; (c) buffer electron mobility (cm2/V·s) vs. top sub-cell fill factor and conversion efficiency; (d) buffer and IDL affinity vs. top sub-cell efficiency [93].

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Figure 18. (a) Experimental vs. Quokka 2 simulated J-V curve; (b) experimental vs. Quokka 2 simulated EQE curve [28].

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Figure 19. (a) Reflectance, (b) absorbance, and (c) transmittance as a function of wavelength for the metal oxide structure [100].

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Figure 20. Tauc plots of Samples 1, 2, and 3 deposited on quartz substrate [100].

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Figure 21. (a) Weibull repartition for the studied solar cell lifetime; (b) solar cell degradation degree under standard and stress conditions [105,107].

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Figure 22. (a) Cumulative number of failures as function of time (using ALTA module). (b) Baseline survival of solar cell simulation (using ALTA module) at temperature and stress conditions [105,107].

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