In the field of dye‐sensitized solar cells (DSSCs), although Pt is commonly used as counter electrode materials owing to its great electrocatalytic activity and conductivity, the high price and small reserves of Pt limit its large‐scale application. In this paper, heteromorphic Ni decorated Fe‐containing carbon nanofibers (Ni/NiO@Fe‐CNFs) was prepared by a thermal synthesis method, and applied as composite counter electrode materials for DSSCs. It was found that the as‐synthesized Ni/NiO@Fe‐CNFs shows better electrocatalytic activity than that of Fe‐CNFs and CNFs for the reduction reaction of triiodide to iodide. The improved electrocatalytic activity is not only attributed to the introduction of Fe2O3 to form Fe‐CNFs, but also attributed to the heteromorphic Ni decoration and their synergistic effect. The photoelectric conversion efficiency of DSSCs with Ni/NiO@Fe‐CNFs counter electrode is 4.81 %, much higher than that of CNFs (0.62 %) and Fe‐CNFs counter electrode (3.65 %), and comparable to the value of Pt counter electrode (5.10 %). Accordingly, the Ni/NiO@Fe‐CNFs is expected to be a potential counter electrode material to replace Pt.
In order to obtain inexpensive Pt-free counter electrode materials for dye sensitized solar cells and expand the application elds of low-rank coal, lignite-based Ni/C composite counter electrode materials were prepared by low-medium temperature pyrolysis method using Huolinhe Lignite as raw material. The structure and chemical components of as-synthesized lignite-based Ni/C composite counter electrode materials were characterized by XRD, FT-IR, TG, Raman, SEM, TEM and XPS, and the electrocatalytic activity of lignite-based Ni/C composite counter electrode were investigated by cyclic voltammetric curve, electrochemical impedance spectrum, Tafel polarization curve. It is found that the electrocatalytic activity of the lignite was improved after low-medium temperature pyrolysis and composited with Ni species to form lignite-based Ni/C composites, which helps to catalyze the electrolyte reduction and thus improve the photoelectric conversion e ciency of the cell. The photoelectric conversion e ciency (η) of the lignite-based Ni/C composite counter electrode was 3.42% (J sc = 11.49 mA cm -2 , V oc = 0.75 V, FF = 0.40) signi cantly higher than that of the lignite counter electrode (η = 0.20%, J sc = 3.16 mA cm -2 , V oc = 0.72 V, FF = 0.09). This indicates that low-medium temperature pyrolysis and composition with Ni is an effective method to improve the photovoltaic performance of coal-based counter electrode materials.
In order to obtain inexpensive Pt-free counter electrode materials for dye sensitized solar cells and expand the application fields of low-rank coal, lignite-based Ni/C composite counter electrode materials were prepared by low-medium temperature pyrolysis method using Huolinhe Lignite as raw material. The structure and chemical components of as-synthesized lignite-based Ni/C composite counter electrode materials were characterized by XRD, FT-IR, TG, Raman, SEM, TEM and XPS, and the electrocatalytic activity of lignite-based Ni/C composite counter electrode were investigated by cyclic voltammetric curve, electrochemical impedance spectrum, Tafel polarization curve. It is found that the electrocatalytic activity of the lignite was improved after low-medium temperature pyrolysis and composited with Ni species to form lignite-based Ni/C composites, which helps to catalyze the electrolyte reduction and thus improve the photoelectric conversion efficiency of the cell. The photoelectric conversion efficiency (η) of the lignite-based Ni/C composite counter electrode was 3.42% (Jsc = 11.49 mA cm-2, Voc = 0.75 V, FF = 0.40) significantly higher than that of the lignite counter electrode (η = 0.20%, Jsc = 3.16 mA cm-2, Voc = 0.72 V, FF = 0.09). This indicates that low-medium temperature pyrolysis and composition with Ni is an effective method to improve the photovoltaic performance of coal-based counter electrode materials.
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