Abstract
Recent achievements in amorphous/crystalline silicon heterojunction (SHJ) solar cells and perovskite/SHJ tandem solar cells place hydrogenated amorphous silicon (a-Si:H) at the forefront of photovoltaics. Due to the extremely low effective doping efficiency of trivalent boron in amorphous tetravalent silicon, light harvesting of aforementioned devices is limited by their fill factors (FFs), a direct metric of the charge carrier transport. It is challenging but crucial to develop highly conductive doped a-Si:H with minimal FF losses. Here we report that light soaking can efficiently boost the dark conductance of boron-doped a-Si:H thin films. Light induces diffusion and hopping of weakly bound hydrogen atoms, which activates boron doping. The effect is reversible and the dark conductivity decreases over time when the solar cell is no longer illuminated. By implementing this effect to SHJ solar cells, we achieved a certified total-area power conversion efficiency of 25.18% with a FF of 85.42% on a 244.63 cm2 wafer.
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Main
Hydrogenated amorphous silicon (a-Si:H) is a technologically important semiconductor for transistors, batteries and solar cells1,2,3,4. It has a long history of use in photovoltaic applications as it offers a low defect density and tunable conduction type5,6,7. These optoelectronic advantages strongly rely on configurations of hydrogen and silicon in the three-dimensional space (described by the radial distribution function8) and thus precise control of its microscopic structure9,10,11 is a critical factor towards achieving good devices. As boron is a trivalent element, it is challenging to establish four-coordinated B−Si4 compounds in the disordered a-Si:H matrix; reported approaches, which are focused on eliminating invalid Six−B−Hy doping configurations (Supplementary Fig. 1), include optimizing the B2H6 flow rate and post-deposition annealing. However, a lack of understanding of the complicated conduction mechanism of boron-doped a-Si:H (p-a-Si:H) has obstructed the full potential of relevant optoelectronic devices.
We find that light soaking is a fast means to improving dark conductance (σdark) of p-a-Si:H thin films. Our results indicate that a portion of hydrogen atoms is captured by tetravalent-coordinated boron atoms in the silicon network to form weak B−H−Si components, which diminishes the efficient B−Si4 doping. We demonstrate that the key function of light soaking is to promote the diffusion and hopping of these weakly bound hydrogen atoms, so that efficient B−Si4 doping is activated. As a consequence of the improved field passivation and conductivity of p-a-Si:H, we achieve a high power conversion efficiency (PCE) of 25.18% with an open-circuit voltage (Voc) and fill factor (FF) of 749 mV and 85.42%, respectively, on a 244.63 cm2 amorphous/crystalline silicon heterojunction (SHJ) solar cell. Moreover, our 60-cell modules exhibit a robust operating stability that successfully passes IEC 60068-2-78 (damp-heat degradation at 85 °C and 85% relative humidity, DH85) and IEC 61215-2:2016 (thermal cycle degradation between −40 °C and 85 °C with applied current at 100% Impp (current at the maximum power point) at the rising edge of temperature) even after threefold-time-long aging standards.
Observation of light-induced dark conductivity increase
Since 1977, light soaking of micrometre-thick a-Si:H films has been widely studied in the research field of a-Si:H thin-film solar cells, but only a small number of works pay attention to its effect on 'thin' a-Si:H films, particularly in the research field of SHJ solar cells12,13. Although a few researchers report that light soaking improves the FF of SHJ solar cells by a magnitude of ~0.7%abs (ref. 14), the fundamental underlying mechanisms are still unclear, which attracts broad interest in the research fields of optoelectronics. We use in situ methods to monitor the time-dependent changes of p-a-Si:H thin films during illuminations. The films are deposited on quartz glasses, followed by evaporating silver strips to form the transfer-length-method structures. The in situ current–voltage data (Fig. 1a) show that σdark of the p-a-Si:H thin film steadily increases during 1 sun illumination, reaching σdark/σdark0 ≈ 4.71 (σdark0 is dark conductance before light soaking) after 30 min. This phenomenon is strikingly in contrast to the light-induced degradation of σdark observed in thick intrinsic, p- and n-type a-Si:H films15,16,17. It supports the perspective that accumulated stress in thick films plays an important role in the Staebler–Wronski effect18, as the maximum stress is roughly proportional to the film thickness. This indicates the effect of light soaking exhibits a scaling behaviour, where the Staebler–Wronski effect gradually transitions to a different effect as the thickness declines. After turning off the illumination, σdark gradually decays (close) to its initial value after more than 1,000 min (Fig. 1b). Such a decay behaviour fits well to a combination of the Debye and Williams–Watts models (Fig. 1c),
The terms ΔσD, ΔσWW and τD, τWW are constant coefficients and characteristic time constants of the Debye and Williams–Watts models, respectively. The term t is the decay time in the dark. Detailed parameters are summarized in Supplementary Table 1. The Debye model with βD = 1 describes free diffusion, whereas the Williams–Watts model with 0 < βWW < 1 describes a continuous-time random walk composed of alternating steps and pauses19. Examples of the Williams–Watts model include the spin-correlation in Cu–Mn and Ag–Mn, spin glass transition in BaFe12O19, dielectric relaxation in K0.3MoO3, spin-lattice relaxation in κ-(ET)2Cu[N(CN)2]Br (here ET represents bis(ethylenedithio)tetrathiafulvalene), specific heat in FexZr1–x and hydrogen relaxation in a-Si (refs. 20,21,22,23,24,25). The good fitting in Fig. 1c suggests an effect that is different to the Staebler–Wronski effect and mediated by two independent mechanisms that control the fast Debye relaxation and the slow Williams–Watts relaxation, respectively.
Mechanism underlying the light-induced changes
To determine the implicit mechanisms of aforementioned Debye and Williams–Watts relaxation, we investigate the hydrogen distributions in p-a-Si:H thin films by time-of-flight secondary ion mass spectrometry (TOF-SIMS). The H− spectra (Fig. 2a) show that 30 min annealing at 180 °C only slightly changes the hydrogen content in intrinsic a-Si:H (i-a-Si:H), by contrast, the same annealing process expels at least ~21.3% of the hydrogen content from p-a-Si:H. As shown in Supplementary Fig. 2, TOF-SIMS spectra also reveal that room-temperature oxidation of an i/p-a-Si:H stack hardly changes the hydrogen content in the i-a-Si:H film, however, the same oxidation process expels ~17.1% of the hydrogen content in p-a-Si:H from the inside to the surface. Based on these findings, we conclude that the boron doping plays a crucial part in the formation of metastable hydrogen configurations in p-a-Si:H.
We next consider the migration barriers of hydrogen atoms to understand the possible binding configurations of aforementioned metastable hydrogen. Structural relaxations observed displacement of four-coordinated silicon atoms by boron atoms shorten the bonds from ~2.35 Å to ~2.07 Å (Supplementary Fig. 3), well consistent with the results of Pandey and colleagues26. Further simulations demonstrate that these B−Si4 sites have a large probability of attracting hydrogen atoms to form metastable B−H−Si configurations when diffusive hydrogen atoms pass by (Supplementary Fig. 4), which is in agreement with the nuclear magnetic resonance signal27 and relevant simulations26,28. As a consequence, conductance of p-a-Si:H is expected to decline due to reduction in the quantity of B−Si4 (ref. 26). Transition-state surveys (Fig. 2b,c) prove that the hopping barriers of hydrogen from B−H−Si and Si−H−Si to adjacent Si−H−Si are 0.88 ± 0.16 eV (A to B in Fig. 2b) and 0.64 ± 0.16 eV (B to C in Fig. 2b), respectively; reversely, the hopping barriers of hydrogen from Si−H−Si to Si−H−Si and B−H−Si are 0.42 ± 0.12 eV (C to B in Fig. 2b) and 0.61 ± 0.15 eV (B to A in Fig. 2b), respectively. Consideration of the barriers (the energy difference between A and C is ~0.46 eV) in Fig. 2c and the binding energy of hydrogen in Si−H−Si (0.5−1.05 eV) concludes29,30 that the binding energy of trapped hydrogen in B−H−Si is about 0.96−1.51 eV, noticeably lower than those (>3 eV) of Si−H bonds, which accounts for why much more metastable hydrogen configurations exist in p-a-Si:H than in i-a-Si:H (inferred from Fig. 2a). When light soaking under 1 sun illumination provides photons with energy over ~0.88 eV, huge amounts of Si3−B−H should be converted to B−Si4 via the hydrogen hopping mechanism (or the tunnelling mechanism31 at temperatures below 60 K) illustrated in Fig. 2b, resulting in improvement of σdark as has been confirmed in Fig. 1a. The microscopic migrations in Fig. 2b are consistent with the light-induced formation of Si−H−Si configurations32.
The mechanistic understanding is also evident in optoelectronic analysis. We prepared symmetric structures of p-a-Si:H/i-a-Si:H/n-c-Si/i-a-Si:H/p-a-Si:H (here n-c-Si represents n-type c-Si) and i-a-Si:H/n-c-Si/i-a-Si:H, whose injection-dependent effective minority carrier lifetimes (τeff) were measured before and after 2 h light soaking under 1 sun illumination, as well as that after 15 min annealing at 180 °C. The right graph in Fig. 2d shows that the τeff of p-a-Si:H/i-a-Si:H/n-c-Si/i-a-Si:H/p-a-Si:H increased substantially after light soaking and then returned to initial values after the annealing. The recombination rate at the a-Si:H/c-Si interface satisfies a closed-form expression in case of high illumination, which can be fitted by the model of Olibet and colleagues30; by modelling the τeff at injection >1.0 × 1015 cm−3, we determined that light soaking increased (decreased) the surface charge density Qs (the interface dangling-bond density Ns) from 3.0 × 1010 cm−2 (2.1 × 109 cm−2) to 3.8 × 1010 cm−2 (1.4 × 109 cm−2), and then annealing decreased (increased) the Qs (Ns) back to 3.0 × 1010 cm−2 (2.0 × 109 cm−2). As a control, the left graph in Fig. 2d shows that the τeff of i-a-Si:H/n-c-Si/i-a-Si:H almost remained constant after either light soaking or annealing, which demonstrates that the variation in τeff in the right graph must originate from p-a-Si:H. According to Sinton and co-workers33, pseudo FFs (PFFs) of silicon solar cells take into account the effect of chemical passivation. We probed the PFF of the device Ag/IWO/p-a-Si:H/i-a-Si:H/n-c-Si/i-a-Si:H/n-a-Si:H/IWO/Ag (where IWO is tungsten-doped indium oxide) before and after 2 h light soaking under 1 sun illumination, as well as that after 15 min annealing at 180 °C. The inset of Fig. 2d finds that the PFF maintains a PFF of ~86.4% regardless of light soaking and annealing. This demonstrates that the decrease in Ns has a negligible impact on chemical passivation, probably due to the small order of magnitude of Ns itself. On the other hand, ultrafast and broadband transient absorption signals (Fig. 2e) indicate that light soaking increases the mobility of photon-generated carriers from 7.10 × 10−3 cm2 V−1 s−1 to 1.81 × 10−2 cm2 V−1 s−1 in p-a-Si:H. This probably results from less scattering of carrier transport in the p-a-Si:H network, thanks to the global decline of strain-induced gap states from B−H−Si configurations26. Consideration of these light-induced enhancements to σdark, Qs and the carrier mobility leads to the conclusion that the light-induced dark conductivity increase stems from activation of boron doping via hydrogen movements. In this regard, we further ascribe the decay of σdark in Fig. 1c to the detrimental reconstruction of B−H−Si configurations, as the binding energy of hydrogen in B−H−Si is ~0.46 eV higher than that in Si−H−Si. In accordance, the fast Debye and slow Williams–Watts relaxations (Fig. 1c) are attributed to incorporation of fast diffusive hydrogen and slow hopping hydrogen into the B−Si bonds, respectively, forming invalid boron doping B−H−Si that has negative effects on the σdark as has been confirmed in Fig. 1b.
We next distinguish the weakly bound hydrogen atoms from the normal Si−H bonds in p-a-Si:H to strengthen the mechanism underlying the light-induced dark conductivity increase. Figure 3a illustrates the preparation of p-a-Si:H films for TOF-SIMS, Fourier-transform infrared spectroscopy (FTIR) and current–voltage characterizations. The capping of an IWO layer on the p-a-Si:H is to mimic the structure of SHJ solar cells, which may have an effect on the redistribution dynamics of hydrogen atoms during the annealing process. TOF-SIMS signals (Fig. 3b) find 2 h annealing at 180 °C reduced >20% of the hydrogen content in the p-a-Si:H film, whereas the content of silicon and boron (almost) remained unchanged. By contrast, Fig. 3c finds that all of the wagging, bending and stretching intensities of the normal Si−H bonds (almost) remain unchanged after the same annealing process. A comparison between the TOF-SIMS signals of hydrogen atoms and the FTIR spectra of Si−H bonds unambiguously demonstrates that relatively low-temperature (180 °C) annealing merely expels weakly bound hydrogen atoms from the p-a-Si:H film while the normal Si−H bonds are hardly affected. The light-induced enhancement of dark conductance of the p-a-Si:H film is plotted as a function of the annealing time at 180 °C in Fig. 3d, evidently, the σdark/σdark0 gradually declined to ~1 due to the exhaustion of weakly bound hydrogen atoms during the prolonged annealing. This definitely proves the light-induced dark conductivity increase and boron doping activation does stem from weakly bound hydrogen atoms rather than normal Si−H bonds in the p-a-Si:H.
According to Pandey and colleagues26, there exist a host of possible configurations of weakly bound hydrogen atoms with respect to boron atoms in the complicated p-a-Si:H network, such as weak hydrogen atoms nearby B−Si4 doping, boron dimers and boron clusters and so on. By changing the flow rate of B2H6 during the film deposition, we fabricated four p-a-Si:H films on quartz glasses, their current–voltage characteristics are shown in Supplementary Fig. 5a. We find that dark conductance (Supplementary Fig. 5b) gradually saturates when the flow rate of B2H6 exceeds ~45 sccm, which suggests that a huge amount of boron atoms are invalidly doped into p-a-Si:H, or do not make contribution to hole concentration. Furthermore, light-induced enhancement of dark conductance substantially decreases when the flow rate of B2H6 exceeds ~20 sccm (Supplementary Fig. 5c). Taking into account the possibility that boron dimers and clusters dominate only in case of high flow rates of B2H6 molecules, we conclude that the light-induced dark conductivity increase and boron doping activation mainly stem from the weak hydrogen atoms nearby the most important B−Si4 doping sites, rather than those nearby boron-superabundant configurations, such as boron dimers and boron clusters and so on.
Application to high-efficient SHJ solar cells
Encouraged by the enhancement of σdark by light soaking, we attempt to develop the full potential of SHJ solar cells by this light-induced effect. Figure 4a showcases the device structure (where the thickness of the p-a-Si:H is ~15 nm; Supplementary Fig. 6) whose initial open-circuit voltage (Voc), short-circuit current density (Jsc), FF and PCE are 744.30 ± 0.68 mV, 38.43 ± 0.07 mA cm–2, 83.70 ± 0.22% and 23.94 ± 0.04% respectively, based on 316 continuous devices from our daily production line. Under 1 sun illumination, as expected, the FF of these cells undergoes a steady increase (standard cell in Fig. 4b). The slope of the current–voltage curve near the low-internal-field region (Voc condition) serves as an indication of charge collection efficiency35, as found in Supplementary Fig. 7, the light soaking continuously increases the slope near this low-internal-field region, indicating more efficient charge extraction due to enhancement of the net field across the depletion region. This strongly supports our perspective that the light soaking activates better boron doping. By contrast, we observe a noticeable drop in the gain of FF for devices annealed for 2 h at 180 °C (180 °C in Fig. 4b), attributed to its less metastable hydrogen configurations (inferred from Figs. 2a and 3b), which leads to less hydrogen movements in Fig. 2b. Intriguingly, we observe that when 13 A current is applied to the cell (Fig. 4b), the FF exhibits a quite similar behaviour to that under 1 sun illumination. This implies the photon energy from light soaking is not the exclusive cause responsible for the dark conductivity increase and boron doping activation, electron-hole recombination caused by current-injected carriers probably also take effect31.
Further increasing the light intensity from 1 to 11, 48 and 60 sun boosted the FF by 0.32 ± 0.18%abs, 0.39 ± 0.14%abs, 1.40 ± 0.26%abs and 1.50 ± 0.37%abs, respectively (Fig. 4c). Here the improvement in FF under 60 sun illumination is close to the ΔFF ≈ 1.8 ± 0.4%abs reported via a multifunctional process36. We also notice that increasing either the light intensity or the forward bias can improve the magnitude of ΔFF (Fig. 4c and Supplementary Fig. 8). This highlights that intensive light soaking or high forward bias activates more efficient boron doping by pumping more metastable hydrogen from B−H−Si to other configurations, in this consideration, we naturally regard SHJ solar cells as the premium choice for concentrator photovoltaic systems. At the mass-production level, 60-sun illumination obtains state-of-the-art industrial FF and PCE of 85.19 ± 0.18% and 24.46 ± 0.05%, respectively (Fig. 4d,e), together with improved Voc by ~2.6 mV (Supplementary Fig. 9), thanks to improvement of the build-in field in c-Si absorber.
Numerical investigation on these improvements is based on a traditional drift-diffusion model of the SHJ solar cell. Procedures and simulated parameters are provided in Supplementary Tables 2 and 3. Comparison of samples A and B in Supplementary Table 4 reveals the decline of Ns from 9.0 × 108 cm−2 to 4.3 × 108 cm−2 only slightly increases the FF by 0.04%abs, much lower than the experimental 1.50 ± 0.37%abs, but in good consistency with the PFF in Fig. 2d. Samples A and C show that the FF increases by 0.66%abs when the efficient doping concentration of boron (Na) increases from 2.0 × 1018 cm−3 to 1.0 × 1019 cm−3. Samples A and D show the FF boosts by 0.77%abs when the series resistance (Rs) declines from 0.4 Ω cm2 to 0.25 Ω cm2 (Supplementary Table 4). The collective refinements to Ns, Na and Rs improves the FF and PCE from 83.79% and 24.0% to 85.25% and 24.5%, respectively, in good agreement with the experimental results from 83.70 ± 0.22% and 23.9 ± 0% to 85.19 ± 0.18% and 24.5 ± 0.1% (samples A and E in Supplementary Table 4). Together with that, the simulated increase of Voc from 744.3 mV to 746.9 mV is also identical to the experimental results from 744.3 ± 0.7 mV to 746.9 ± 0.5 mV. Such excellent consistencies between simulations and experiments confirm the improvements in SHJ solar cells do stem from light-induced efficient doping of boron atoms.
After capping an 80 nm SiOx antireflection layer onto a high-efficiency cell, we submitted it to an independent testing centre and achieved a certificated PCE of 25.18% with a FF of 85.42% on a 244.63 cm2 wafer (Fig. 4f and Supplementary Fig. 10). They are among the highest certificated PCE and FF for total-area two-side contacted silicon solar cells34 (Fig. 4g and Supplementary Fig. 11). The FF reaches 98.30% of its Shockley–Queisser limit, ~86.9% (ref. 37). We also submitted another SHJ solar cell capped with a 110 nm MgF2 antireflection layer to ISFH CalTeC; they reported total- (244.81 ± 0.91 cm2) and designated-area (226.71 ± 0.91 cm2) PCEs of 25.10 ± 0.38% and 25.45 ± 0.38%, respectively (Fig. 4f and Supplementary Fig. 12). The a bit lower FFs of 84.28% ± 0.93% and 84.63 ± 0.93% than that certificated from NPVM probably stem from the degradation between the 70 sun light soaking and the certification.
With regard to stability, FF and PCE of devices retain 98.70% and 97.59% of their initial values after 1,000 h DH85 impact (Fig. 4h), without any encapsulations. At the module level, Figs. 4i and 4j show that the FF and PCE retain 98.1% (96.8%) and 95.5% (95.4%), respectively, after 3,000 h DH85 impact (600 thermal cycles between −40 °C and 85 °C), demonstrating their high stability against extreme climate degradation factors. The DH85 (thermal-cycle) degradation of the module is threefold longer than the IEC 60068-2-78 (IEC 61215-2:2016) standard. These tests exclude the high-density (~1021 cm−3) weakly bound hydrogen atoms in the p-a-Si:H film as the key factor that dominates the damp-heat (thermal-cycle) degradation4.
In addition to the stabilities in DH85 and thermal cycle environments, we finally explored the reversible behaviour of SHJ solar cells caused by the light-induced dark conductivity increase and boron doping activation. As found in Fig. 5a, we alternated between measuring the cells’ FFs under 1 sun illumination for 180 min and the dark for 720 min. Evidently, the FF decays ~0.3−0.35%abs during each sleeping in the dark. From Supplementary Fig. 13, we find that the FF rapidly declined by ~0.15%abs in the first ~20 min, followed by a slow decay in the next ~745 min. This fast decay time of ~20 min is consistent with the characteristic time constant τD ≈ 15.84 ± 1.55 min of the Debye relaxation (Supplementary Table 1), confirming the enhancement of FF does stem from the improvement of conductance of doped a-Si:H film. Figure 5a also reveals that the FF rapidly climbs up after turning on the light soaking; thus, the output of power plants comprising SHJ solar cells undergoes a rapid increase after sunrise on sunny days, which challenges the present IEC testing standards, as the in-house certification underestimates their performance in real operations. The following provides a feasible pathway to freezing the dark decay. We took 198 solar cells from the same batch and divided them into 11 groups. First, the devices in each group undergo a 70 s light soaking under 60 sun illumination, followed by a 25 min sleeping in the dark to finish the fast Debye relaxation. Their FFs were then measured before and after 10 min annealing at different temperatures, as shown in Fig. 5b, the decay magnitude of FF (from Williams–Watts relaxation) dramatically drops when the temperature is decreased from 200 °C to 60 °C, which suggests that the low temperature arrests the unfavourable formation of the B−H−Si configurations. This observation agrees with the perspective that annealing can accelerate annihilation of Si−H−Si configurations38. Using the average ΔFF (Fig. 5b), we derived the temperature-dependent characteristic time constant τWW by the Williams–Watts model,
According to Kakalios and co-workers39, the βWW of a-Si:H is 0.00165T (in Kelvin), independent of the doping type; the τWW, on the other hand, obeys an Arrhenius relationship,
where R is molar gas constant. Figure 5c shows the fitting of equation (3) to the τWW (blue circles) calculated from equation (2), interestingly, the theoretical τWW (red circle) from Supplementary Table 1 is close to the extrapolation of the fitting line, confirming the validation of equation (3). The derived activation energy Ea ≈ 0.399 eV is well agreement with the prediction of migration barrier ~0.417 eV and the 0.385 ± 0.143 eV inferred from the reported data of doped a-Si:H (ref. 40). Figure 5d finds Ea of doped a-Si:H is noticeably smaller than that of the intrinsic counterpart40,41,42,43,44, most likely owing to existence of the exclusive metastable hydrogen configurations in doped materials (as inferred from Figs. 2a and 3b). We notice phosphorus-doped a-Si:H also has smaller Ea, thus it is expected to make similar contributions to the light-induced effect. This speculation is evident from the light soaking behaviour of ‘half’ cells with structure of Ag/IWO/n-a-Si:H/i-a-Si:H/n-c-Si/IWO/Ag, where the p-a-Si:H is totally removed (Supplementary Fig. 14). It is interesting to find the doped a-Si:H thin films exhibit an opposite light-induced behaviour in comparison to p-type c-Si when oxygen atoms exist in the form of Bs−O2i complexes inside the crystalline matrix45. Given doped a-Si:H has small Ea but great τWW at low temperatures, we conclude that the cold climates can effectively prevent the decay of metastable FF.
Conclusion
We observed light-soaking-induced enhancement of dark conductance of boron-doped a-Si:H thin films, which is appealing for realizing outstanding optoelectronic devices. We show that light soaking promotes the diffusion and hopping of the weakly bound hydrogen atoms, which allow the activation of B−Si4 doping. The light-soaking effect noticeably improves the charge carrier transport in SHJ solar cells, yielding an excellent FF of 85.42% (84.63%) and a PCE of 25.18% (25.45%) on a 244.63 cm2 (226.71 cm2) total-area (designated-area) wafer.
Methods
Material characterization
Glow discharge p-a-Si:H films with thicknesses of ~60 nm were deposited onto silica glasses in 40.68 MHz very-high-frequency plasma-enhanced chemical vapour deposition (VHF-PECVD; IE Sunflower, OAK-DU-5) at 200 °C. Then 200-nm-thick 10 mm × 2 mm silver strips were thermally evaporated on the film surface to form transfer-length-method structures46. Current–voltage characteristics between the two strips with interval distance of 200 μm were probed by KEITHLEY 6487. This current–voltage measurement is to qualitatively determine the existence of the light-induced changes. For FTIR (Perkin Elmer, Spectrum 100) measurements, p-a-Si:H thin films were deposited on >3,000 Ω cm float-zone c-Si substrates, their infrared absorptions from Si−H and B−H bonds were characterized using the transmission mode; H− profiles of IWO/i-a-Si:H/c-Si, IWO/p-a-Si:H/c-Si and p-a-Si:H/i-a-Si:H/c-Si were analysed by TOF-SIMS (ION TOF, GmbH-Muenster), during which the chamber pressure, primary ion source and current are 1.0 × 10−9 mbar, 30 keV Bi+ and 1.0 pA, respectively, the depth profiles were acquired using a 500 eV Cs+ sputter beam. Cross-sectional images of p-a-Si:H were probed by high-resolution transmission electron microscope (FEI Titan 80-300ST), operated at 200 kV. Injection-dependent τeff and PFF were measured by the Sinton WCT-120 and Suns-Voc, respectively. The Qs and Ns are fitted from a surface recombination model by Olibet and colleagues, they discussed details about the model and also provided the fitting codes in the appendix A of Olibet’s thesis47.
Ultrafast and broadband transient absorption spectra were measured using a homebuilt pump–probe set-up. The output of a titanium sapphire amplifier (Coherent LEGEND DUO, 4.5 mJ, 3 kHz, 100 fs) splits into three beams (2.0 mJ, 1.0 mJ and 1.5 mJ), two of which separately pump two optical parametric amplifiers (OPA; Light Conversion TOPAS Prime). TOPAS-1 provides tunable pump pulses and TOPAS-2 generates the probe pulses. A 1,300 nm pulse from TOPAS-2 is sent through a CaF2 crystal mounted on a continuously moving stage. This generates a white-light supercontinuum pulses from 350 nm to 1,100 nm. The pump pathway length is varied between 5.12 m and 2.60 m with a broadband retroreflector mounted on an automated mechanical delay stage (Newport linear stage IMS600CCHA controlled by a Newport XPS motion controller), thereby generates delays between pump and probe from −400 ps to 8 ns. Pump and probe beams are overlapped on surface of the p-a-Si:H. By a beam viewer (Coherent, LaserCam-HR II) we regulate the size of pump beam about three times larger than the probe beam. The probe beam is guided to a custom-made prism spectrograph (Entwicklungsbüro Stresing) where it is dispersed by a prism onto a 512 pixel complementary metal–oxide semiconductor linear image sensor (Hamamatsu G11608−512DA). The probe pulse repetition rate is 3 kHz, whereas the excitation pulses are mechanically chopped to 1.5 kHz (100 fs to 8 ns delays), and the detector array is read out at 3 kHz. These characterizations are also summarized in Supplementary Table 5.
The transient absorption signals are fitted by the one-dimension recombination and diffusion model:
The initial condition is \(N(x,0) = N(0,0)\exp ( - \alpha x)\), and the boundary condition at the front/back surface/interface are \(\frac{{\partial N(x,t)}}{{\partial x}} = \frac{{S_{{{\mathrm{f}}}}}}{D}N(0,t)\) at x = 0 and \(\frac{{\partial N(x,t)}}{{\partial x}} = - \frac{{S_{{{\mathrm{b}}}}}}{D}N(d,t)\) at x = d, respectively. N(x, t) is the carrier density, which is a function of the time t and the position x in the film, D is the diffusion coefficient, k1, k2, k3 are the first-, second- and third-order bulk recombination constants, α is the absorption coefficient, and Sf and Sb are the front and back interface/surface recombination velocities. The front surface/interface is exposed to the pump laser beam. The general rate equation consists of the diffusion equation and includes the different recombination rates present in the bulk. N(x, t) is proportional to ΔT/T, \(N(x,t) = \beta \frac{{{\Delta}{{{\mathrm{T}}}}}}{{{{\mathrm{T}}}}}\) with a fitted prefactor β.
Molecular dynamics and ab initio calculations
The simulations were conducted on the platform of Materials Studio 2017R. We used the Tersoff empirical potential to express the atomic interactions for a-Si and a-Si:H, which has been demonstrated for amorphous tetrahedral semiconductors48. Rectangular c-Si supercells of 10.854 Å × 10.854 Å × 21.708 Å composed of 128 silicon atoms were heated up to 3,000 K at a rate of 540 K ps–1 followed by 200 ps equilibrium to fully destroy small crystallinities. The metallized liquid silicon was then quenched to 300 K at a slow rate of 1.0 × 1011 K s–1. The slow cooling efficiently reduces structure defects such as dangling bonds and floating bonds. Two hydrogen atoms were introduced into the silicon network, followed by relaxations at constant volume using the generalized gradient approximations of Perdew–Burke–Ernzerhof. To gain p-type doping, we replaced various tetrahedral silicon sites by one boron atom, followed by geometrical relaxations. To investigate the capture of hydrogen by boron, we placed hydrogen atoms >2.3 Å away (much longer than B−H and Si−H single bonds) from the boron atoms and relaxed to observe the coordinate changes. The functional, ensemble, temperature and simulation time are generalized gradient approximations of Perdew–Burke–Ernzerhof, NVT, 298 K and 0.3 ps, respectively. These Si127BH3 amorphous supercells were used as the starting points for further calculations. The reaction barriers were calculated by transition-state searches between optimized structures using the generalized synchronous transit method49. Each case was statistic by calculating 30 different Si127BH3 amorphous supercells because the fluctuations of bond length and bond angle in the amorphous network may introduce some uncertainty.
Device fabrication
Czochralski n-c-Si wafers were purchased from Sichuan Yongxiang Silicon Material Company. Their initial thickness and electrical resistivity are ~160 μm and 0.3−2.1 Ω cm respectively. The saw damage was etched in 20.0 vol% alkaline solution at 80 °C for 2 min, followed by formation of surface pyramids via immersion in 2.1 vol% alkali solution at 80 °C for 8 min. They then experienced standard RCA cleaning to remove surface organics and metal ions. After that, these wafers underwent 3 min dipping in 2.0% hydrofluoric acid water solution to remove the surface oxide. In the chambers of very-high-frequency plasma-enhanced chemical vapour deposition (VHF-PECVD, 40.68 MHz; Ideal Energy Sunflower), 5 nm i-a-Si:H, 15 nm p-a-Si:H, 4 nm i-a-Si:H and 6 nm n-a-Si:H were sequentially deposited on the two faces of the clean wafers. The process temperatures were 200 ± 10 °C. The i-a-Si:H layer consists of two sublayers, their power density and chamber pressure during deposition are 67/40 mW cm−2 and 50/80 Pa respectively. The first layer was deposited using pure SiH4, while the second layer was deposited using diluted SiH4 in H2 with a ratio of [SiH4]:[H2] = 1:10. 15 s H2 plasma was applied to treat the two i-a-Si:H films for improving the passivation quality at the i-a-Si:H/n-c-Si interfaces. Power density, chamber pressure and gas flow ratio during deposition of the n-a-Si:H were 33 mW cm−2, 80 Pa and [PH3]:[SiH4]:[H2] = 1.5:100:1000. The p-a-Si:H layer also has two sublayers, whose power density, chamber pressure and gas flow ratio during deposition were 20/20 mW·cm−2, 80/80 Pa and [B2H6]:[SiH4]:[H2] = 1:100:100/2:100:400 respectively. About 80 nm IWO was grown on both sides of the devices by the reactive plasma deposition (RPD, DS1-12080-SN-D13; Shenzhen S.C.) at 150 °C, whose target material is 1.0% tungsten-doped in indium oxide. Nine silver busbars and fingers were screen printed on the two faces of the devices using low-temperature paste, followed by annealing at 150 °C for 5 min and 185 °C for 30 min. For the certificate cell, an 80 nm SiOx layer was capped onto the sun-side surface in a 13.56 MHz radio-frequency PECVD (ULVAC CME-400).
Device characterization
Current–voltage characteristics of all solar cells without SiOx antireflection were tested under standard conditions (25 °C, 100 mW cm−2) using a solar simulator (Halm IV, ceitsPV-CTL2). The light intensity was calibrated using a certified National Renewable Energy Laboratory (NREL) reference cell. The submitted cell with SiOx antireflection was independently tested by the NPVM in the Fujian Province, China, one of the designated test centres for the solar cell efficiency tables. The device area was captured by an automatic image test system. Before certification, it was light soaked for 30 min under 1 sun illumination, followed by cooling down to room temperature. The cell with MgF2 antireflection layer was independently tested by ISFH CalTeC, which experienced a 1 sun illumination before the measurement. The conveyor during light soaking was pre-heated to ~200 °C, and the light intensity was adjusted from 1 to 60 sun (ASIA NEO TECH INDUSTRIL Company, NLIDR-S60; red light). These cells were quickly cooled down by cold-air blowing after the light soaking. All devices were measured under standard conditions. These characterizations are also summarized in Supplementary Table 6.
Damp-heat degradation
The devices underwent 1,000 h damp-heat impact at DH85 in the dark, during which they were in open-circuit condition. These devices are six-inch SHJ solar cells without any encapsulations. The 60-cell module underwent 3,000 h damp-heat impact at DH85 in the dark according to the IEC 60068-2-78, during which it was in open-circuit condition. All measurements were conducted under standard conditions (25 °C, 100 mW cm−2), out of the climate test chamber.
Thermal cycle degradation
The thermal cycles were conducted in accordance with the IEC 61215-2:2016. The cycle temperature was between −40 °C and 85 °C. The applied current was 100% Impp at the rising edge of temperature.
Simulation procedures and parameters of SHJ solar cells
The rear-junction SHJ solar cell was modelled using the traditional drift-diffusion models on the AFORS-HET device-simulation platform previously developed for heterojunction solar cells50. General parameters are listed in Supplementary Table 2. The effects of Ns, Na and Rs on the device performances are different. Ns represents chemical passivation, which is dominated by defect density at the a-Si:H/c-Si interfaces. Qs represents the surface charge density at the depletion region of the p–n junction, which cannot be directly used in the simulation. As an alternative option, we use Na to represent the field passivation. Rs represents transport series resistance in the device, here its variation mainly stems from the bulk resistance of p-a-Si:H as has been observed in Fig. 1a. Both Na and Rs are dominated by the doping efficiency of boron in the p-a-Si:H film. Ns is derived from modelling the τeff of IWO/p-a-Si:H/i-a-Si:H/n-c-Si/i-a-Si:H/n-a-Si:H/IWO, measured before and after 70 s light soaking under 60-sun illumination. Rs was measured from the solar simulator under the standard conditions. Na is the only optimized parameter to matching the experimental Voc, Jsc, FF and PCE of SHJ solar cells before and after the 70 s 60-sun illumination. Samples A and E in Supplementary Tables 3 and 4 are control samples, whose performances are very close to those of the as-prepared and light-soaked (60 sun) SHJ solar cells respectively. To distinguish the effects of Ns, Na and Rs on the performance of SHJ solar cells, samples B–D in Supplementary Tables 3 and 4 change Ns, Na and Rs one by one. By this means, we can determine the key factors that dominate the device-level light-induced changes.
Reporting Summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All data generated or analysed during this study are included in the published article, its Supplementary Information and Source Data. Source Data are provided with this paper.
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Acknowledgements
W.L. acknowledges professor Z. Ma and W. Ji for their fruitful discussions. W.L. acknowledges the financial supports from National Natural Science Foundations of China (grant no. 62004208) and Science and Technology Commission of Shanghai Municipality (grant no. 22ZR1473200). L.Z. acknowledges the financial support from National Natural Science Foundations of China (grant no. 62074153). A.H. acknowledges the financial support from Science and Technology Commission of Shanghai Municipality (grant no. 19DZ1207602).
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Contributions
W.L. conceived the idea, proposed the concept of a light-induced dark conductivity increase and boron doping activation, designed the overall experiments and led the project. J.S., L.Z., W.L., A.H., F.M., Y.X. and H.L. performed device optimization. W.L., J.Y. and J.W. performed molecular dynamics and ab initio simulations, and modelled the experimental data. W.L. performed SIMS analysis. A.H. performed current–voltage measurements under 11, 48 and 60 sun. S.H., X.L., J.P., Y.Y., K.J. and Z.M. measured the 1 sun FF evolutions. J.D. performed the RCA cleaning. Q.S. and Y.Yu performed the system calibrations of the solar simulator. Z.Li performed the FTIR measurements. H.Z. and J.S. performed the FF evolutions at different temperatures. Y.Y., K.J. and S.H. performed the Sinton measurements. Y.Y. and W.L. performed the dark current–voltage measurements. X.L. performed the damp-heat measurements. Y.Y., K.J. and X.L. performed the PFF measurements. J.L. performed the modelling of Sinton data. Z.D., J.Y., X.Y., X.S., L.X., J.K., F.X., J.L. W.Z. and S.D.W. discussed Sinton data, molecular dynamics and ab initio simulations. Y.G. and F.L. performed the transient absorption measurements and analysis. W.L. and Z.L. supervised the project. W.L. wrote the paper. All authors contributed to the discussion of the results and revision of the manuscript.
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J.S., L.Z., A.H., J.D., H.Z., H.L., Y.X., F.M. and Z.L. are employees of Zhongwei New Energy (Chengdu) Company. H.Z., H.L., Y.X. and Z.L. are employees of Tongwei Solar Company. J.L. is an employee of UISEE Technologies (Shanghai) Company. All other authors declare no competing interests.
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Liu, W., Shi, J., Zhang, L. et al. Light-induced activation of boron doping in hydrogenated amorphous silicon for over 25% efficiency silicon solar cells. Nat Energy 7, 427–437 (2022). https://doi.org/10.1038/s41560-022-01018-5
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DOI: https://doi.org/10.1038/s41560-022-01018-5
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