Yansong Shen scite author profile

Highly efficient, ultrathin (~400 nm) pure sulfide kesterite Cu 2 ZnSnS 4 (CZTS) solar cells have been realized by interface reaction route controlling and self-organized nano-pattern at the back contact. The Al 2 O 3 intermediate layer introduced at the Mo/CZTS interface can effectively inhibit the detrimental interfacial reaction between CZTS and Mo in the initial stage of sulfurization, and then turns into a self-organized nanopattern yielding a nanoscale opening for electrical contact. With this interface modification, the traditional issues of phase segregation (secondary phases) and voids at the back contact region can be well addressed, which greatly improves uniformity and reduces back contact recombination. As a result, this interface modification not only leads to beyond 8% ultrathin CZTS solar cells but also yields two certificated world record efficiencies: 9.26% for 0.237 cm 2 small area and 7.61% for 1 cm 2 standard kesterite CZTS solar cells (normal thickness).

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Three-dimensional Modelling of Coal Combustion in Blast Furnace

Shen

Guo

et al. 2008

ISIJ Int.

101

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Pulverized coal injection technology is widely used in blast furnace ironmaking due to economic, operational and environmental benefits. High burnout within the tuyere and raceway is required for high coal injection rate operation. In order to analyze the flow and combustion in the tuyere and raceway more accurately and reliably, a three-dimensional model of coal combustion is developed. This model is validated against the measurements from two pilot scale test rigs in terms of gas species composition and coal burnout. The gas-solid flow and coal combustion are simulated and analysed. The results indicate that compared to our previous model, the present model is able to provide more detailed gas species distributions and better describe the evolutions of coal particles. It is more sensitive to various parameters and hence more robust in examining various blast furnace operations.

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Phosphorus-doped silicon quantum dots for all-silicon quantum dot tandem solar cells

Hao

Cho

Scardera

et al. 2009

Solar Energy Materials and Solar Cells

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Synthesis and characterization of boron-doped Si quantum dots for all-Si quantum dot tandem solar cells

Hao

Cho

Flynn

et al. 2009

Solar Energy Materials and Solar Cells

122

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Yansong Shen

Beyond 8% ultrathin kesterite Cu2ZnSnS4 solar cells by interface reaction route controlling and self-organized nanopattern at the back contact

Three-dimensional Modelling of Coal Combustion in Blast Furnace

Phosphorus-doped silicon quantum dots for all-silicon quantum dot tandem solar cells

Synthesis and characterization of boron-doped Si quantum dots for all-Si quantum dot tandem solar cells

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