Mixed perovskites have achieved substantial successes in boosting solar cell efficiency, but the complicated perovskite crystal formation pathway remains mysterious. Here, the detailed crystallization process of mixed perovskites (FA0.83MA0.17Pb(I0.83Br0.17)3) during spin‐coating is revealed by in situ grazing‐incidence wide‐angle X‐ray scattering measurements, and three phase‐formation stages are identified: I) precursor solution; II) hexagonal δ‐phase (2H); and III) complex phases including hexagonal polytypes (4H, 6H), MAI–PbI2–DMSO intermediate phases, and perovskite α‐phase. The correlated device performance and ex situ characterizations suggest the existence of an “annealing window” covering the duration of stage II. The spin‐coated film should be annealed within the annealing window to avoid the formation of hexagonal polytypes during the perovskite crystallization process, thus achieving a good device performance. Remarkably, the crystallization pathway can be manipulated by incorporating Cs+ ions in mixed perovskites. Combined with density functional theory calculations, the perovskite system with sufficient Cs+ will bypass the formation of secondary phases in stage III by promoting the formation of α‐phase both kinetically and thermodynamically, thereby significantly extending the annealing window. This study provides underlying reasons of the time sensitivity of fabricating mixed‐perovskite devices and insightful guidelines for manipulating the perovskite crystallization pathways toward higher performance.
Thyroid nodules are very common all over the world, and China is no exception. Ultrasound plays an important role in determining the risk stratification of thyroid nodules, which is critical for clinical management of thyroid nodules. For the past few years, many versions of TIRADS (Thyroid Imaging Reporting and Data System) have been put forward by several institutions with the aim to identify whether nodules require fine-needle biopsy or ultrasound follow-up. However, no version of TIRADS has been widely adopted worldwide till date. In China, as many as ten versions of TIRADS have been used in different hospitals nationwide, causing a lot of confusion. With the support of the Superficial Organ and Vascular Ultrasound Group of the Society of Ultrasound in Medicine of the Chinese Medical Association, the Chinese-TIRADS that is in line with China's national conditions and medical status was established based on literature review, expert consensus, and multicenter data provided by the Chinese Artificial Intelligence Alliance for Thyroid and Breast Ultrasound.
Regulation of the crystallization of perovskite films and avoiding the oxidation of Sn2+ during the deposition process are very important for achieving Sn/Pb binary perovskite solar cells (PVSCs) with high power conversion efficiency (PCE) and producibility. In this work, a high‐quality HC(NH2)2Pb0.7Sn0.3I3 (FAPb0.7Sn0.3I3) film deposited from the two‐step solution process by introducing methylammonium thiocyanate (MASCN) as a bifunctional additive into the precursor solution containing PbI2 and SnI2 is reported. MASCN can not only tune the morphology of the perovskite film but also stabilize the precursor solution via retarding the oxidation of Sn2+ through a strong coordination between SCN− and Sn2+. The Sn/Pb binary inverted PVSCs based on FAPb0.7Sn0.3I3 present a high fill factor of 0.79 and the best PCE of 16.26% in the case of 0.25 MASCN addition. The device fabrication producibility is also greatly improved due to the stabilized precursor solution with the aid of MASCN. The PCE of the device is almost independent of the storage time of the precursor solution within 124 d in the N2‐filled glove box. These results indicate that the precursor engineering with multifunctionality additive is an effective approach toward highly efficient and producible PVSCs for future commercialization.
cell (PVSCs) with good reproducibility, beneficial for improving success rate of products. Besides of the uniformity of perovskite layer, the fabrication of highly efficient PVSC with thick perovskite layer and good thickness tolerance is also urgent for future commercializatio n. [1b,2c,e,5] In the past three years, efforts on fabricating high-performance PVSCs with thick active layer were tried by both thermal evaporation and solution methods. [1b,2c,e,5a,6] The researches on the PVSCs based on perovskite film fabricated by thermal evaporation method revealed that there is an optimized film thickness ≈300 nm. Further increase the thickness of the perovskite film leads to the deterioration of open-circuit voltage (V oc ) and fill factor (FF) and the decline of PCE of the device. [6a,b,7] Though Bolink and co-workers [6a] reduce the effect of the unbalanced charge extraction for 900 nm thick PVSCs by increasing the conductivity of the hole transport layer (HTL), and improve the efficiency from 7.2% to 12.0%, which is still lower than the 285 nm thick one (12.7%). It is believed that the reduction of V oc and FF along with the increasing film thickness can be attributed to the roughening of the surface of the perovskite film and the perovskite/carrier transport layer interface as well, which brings more serious charge recombination. [6b,7] Similar phenomenon was also observed in the perovskite film prepared by spin-coating method. Gong and co-workers [6c] found that the PCE first increased with the increasing thickness of the MAPbI 3−x Cl x film, and reached to a maximum value about 12% in the case of 575 nm. Further thickening of the perov skite film was found to deteriorate the device performance because of the increase of surface roughness of the perovskite film and the inferior contact between electron transport layer (ETL) and thick active layer. Owning to the increased difficulty in controlling the morphology of the thick perovskite film and the resulting limited carrier diffusion lengths, poor charge extraction, serious charge recombination, it is rather hard to obtain thick film based high performance PVSCs as compared to those based on thinner junctions. To improve the morphology of the perovskite film with smooth and pinhole free surface, high crystallinity, High-performance perovskite solar cells (PVSCs) with absorber layer thickness insensitive features are important for practical fabrication, however these features are difficult to be realized. There are very few reports of the fabrication of polycrystalline PVSCs with power conversion efficienies (PCE) insensitive to film thickness beyond 600 nm. The main reason lies in more serious recombination of the thick perovskite layer compared to the thin layer. Herein, this challenge is addressed by a simple hot casting method to formulate high-quality perovskite film with enlarged grain size, high carrier mobility, and reduced defects. It is found that increasing the temperature to 70 °C can dramatically increase the film thickness and enlarge the...
Thiocyanate ammonium (NH4SCN) is introduced into the fabrication of formamidinium lead triiodide (FAPbI3) film through one-step spin-coating. The promoted formation of the black trigonal phase α-FAPbI3 with better crystallinity have been observed after the addition of NH4SCN, together with the supression of the formation of the yellow hexagonal phase δ-FAPbI3. The planar perovskite solar cells (PVSCs) based on NH4SCN assisted formed α-FAPbI3 film with high quality present a highest power conversion efficiency of 11.44% when 30 mol% NH4SCN is applied. Notably, the addition of NH4SCN is found to enhance the moisture stability of the perovskite. As a result, the planar PVSCs with 30 mol% NH4SCN additive show improved stability under ambient (RH: 30% ~ 40%) over those based on pristine FAPbI3. NH4SCN simultaneously enhances the efficiency and moisture stability of FAPbI3 base PVSCs through single one-step solution method, facilitating its commercial fabrication and application. Fig. 3 (a) The planar PVSC device structure. (b) The energy level diagram of the perovskite solar cells. (c) J-V curves of perovskite solar cells with FAPbI3 with different content of SCN as the active layer. (d) Statistical distribution of power conversion efficiency (PCE) of the PVSCs based on FAPbI3 and 3S-FAPbI3. Cross sectional SEM images of (e) FAPbI3 and (f) 3S-FAPbI3 on FTO/compact TiO2 substrates.Thiocyanate ammonium additive is found to improve the performance of FAPbI 3 based planar perovskite solar cells through single one-step method.
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