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15. Different modes of band gap engineering through which an optimum... | Download Scientific Diagram
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Band gap engineering in huge-gap semiconductor SrZrO3 for visible-light photocatalysis - ScienceDirect
Band gap engineering of FeS2 under biaxial strain: a first principles study - Physical Chemistry Chemical Physics (RSC Publishing)
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Bio‐Inspired Band Gap Engineering of Zinc Oxide by Intracrystalline Incorporation of Amino Acids - Brif - 2014 - Advanced Materials - Wiley Online Library
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Band Gap Engineering in MASnBr3 and CsSnBr3 Perovskites: Mechanistic Insights through the Application of Pressure | The Journal of Physical Chemistry Letters
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Band gap engineering design for construction of energy-levels well-matched semiconductor heterojunction with enhanced visible-light-driven photocatalytic activity - RSC Advances (RSC Publishing)
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Effective band gap engineering by the incorporation of Ce, N and S dopant ions into the SrTiO3 lattice: exploration of photocatalytic activity under UV/solar light | SpringerLink
Band-gap engineering in AB(OxS1−x)3 perovskite oxysulfides: a route to strongly polar materials for photocatalytic water splitting - Journal of Materials Chemistry A (RSC Publishing)
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Band Structure Engineering and Optical Properties of Pristine and Doped Monoclinic Zirconia (m-ZrO2): Density Functional Theory Theoretical Prospective | ACS Omega
Band structure engineering of boron–oxygen-based materials for efficient charge separation - Materials Chemistry Frontiers (RSC Publishing)
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