![Low‐dimensional metal halide perovskites and related optoelectronic applications - Zhu - 2020 - InfoMat - Wiley Online Library Low‐dimensional metal halide perovskites and related optoelectronic applications - Zhu - 2020 - InfoMat - Wiley Online Library](https://onlinelibrary.wiley.com/cms/asset/85cc10c5-1cfa-4506-b211-10d91fa390ce/inf212086-toc-0001-m.jpg)
Low‐dimensional metal halide perovskites and related optoelectronic applications - Zhu - 2020 - InfoMat - Wiley Online Library
![Molecules | Free Full-Text | Engineering Plasmonic Environments for 2D Materials and 2D-Based Photodetectors Molecules | Free Full-Text | Engineering Plasmonic Environments for 2D Materials and 2D-Based Photodetectors](https://pub.mdpi-res.com/molecules/molecules-27-02807/article_deploy/html/images/molecules-27-02807-g001.png?1651140429)
Molecules | Free Full-Text | Engineering Plasmonic Environments for 2D Materials and 2D-Based Photodetectors
Graphene and Beyond: Recent Advances in Two-Dimensional Materials Synthesis, Properties, and Devices | ACS Nanoscience Au
![Tellurium as a successor of silicon for extremely scaled nanowires: a first-principles study | npj 2D Materials and Applications Tellurium as a successor of silicon for extremely scaled nanowires: a first-principles study | npj 2D Materials and Applications](https://media.springernature.com/full/springer-static/image/art%3A10.1038%2Fs41699-020-0143-1/MediaObjects/41699_2020_143_Fig1_HTML.png)
Tellurium as a successor of silicon for extremely scaled nanowires: a first-principles study | npj 2D Materials and Applications
![Large Bandgap Shrinkage from Doping and Dielectric Interface in Semiconducting Carbon Nanotubes | Scientific Reports Large Bandgap Shrinkage from Doping and Dielectric Interface in Semiconducting Carbon Nanotubes | Scientific Reports](https://media.springernature.com/m685/springer-static/image/art%3A10.1038%2Fsrep28520/MediaObjects/41598_2016_Article_BFsrep28520_Fig1_HTML.jpg)
Large Bandgap Shrinkage from Doping and Dielectric Interface in Semiconducting Carbon Nanotubes | Scientific Reports
![Catalysts | Free Full-Text | Recent Advances on Small Band Gap Semiconductor Materials (≤2.1 eV) for Solar Water Splitting Catalysts | Free Full-Text | Recent Advances on Small Band Gap Semiconductor Materials (≤2.1 eV) for Solar Water Splitting](https://www.mdpi.com/catalysts/catalysts-13-00728/article_deploy/html/images/catalysts-13-00728-g001.png)
Catalysts | Free Full-Text | Recent Advances on Small Band Gap Semiconductor Materials (≤2.1 eV) for Solar Water Splitting
![One-dimensional confinement and width-dependent bandgap formation in epitaxial graphene nanoribbons | Nature Communications One-dimensional confinement and width-dependent bandgap formation in epitaxial graphene nanoribbons | Nature Communications](https://media.springernature.com/full/springer-static/image/art%3A10.1038%2Fs41467-020-19051-x/MediaObjects/41467_2020_19051_Fig1_HTML.png)
One-dimensional confinement and width-dependent bandgap formation in epitaxial graphene nanoribbons | Nature Communications
Bandgap of 2D materials and their corresponding operation wavelength.... | Download Scientific Diagram
![Adjusting the crystal size of InSb nanowires for optical band gap energy modification - ScienceDirect Adjusting the crystal size of InSb nanowires for optical band gap energy modification - ScienceDirect](https://ars.els-cdn.com/content/image/1-s2.0-S0254058420308634-fx1.jpg)
Adjusting the crystal size of InSb nanowires for optical band gap energy modification - ScienceDirect
![Nanomaterials | Free Full-Text | Two-Dimensional Silicon Carbide: Emerging Direct Band Gap Semiconductor Nanomaterials | Free Full-Text | Two-Dimensional Silicon Carbide: Emerging Direct Band Gap Semiconductor](https://pub.mdpi-res.com/nanomaterials/nanomaterials-10-02226/article_deploy/html/images/nanomaterials-10-02226-g001.png?1604929884)
Nanomaterials | Free Full-Text | Two-Dimensional Silicon Carbide: Emerging Direct Band Gap Semiconductor
![Widely tunable GaAs bandgap via strain engineering in core/shell nanowires with large lattice mismatch | Nature Communications Widely tunable GaAs bandgap via strain engineering in core/shell nanowires with large lattice mismatch | Nature Communications](https://media.springernature.com/m685/springer-static/image/art%3A10.1038%2Fs41467-019-10654-7/MediaObjects/41467_2019_10654_Fig1_HTML.png)
Widely tunable GaAs bandgap via strain engineering in core/shell nanowires with large lattice mismatch | Nature Communications
![Materials | Free Full-Text | Ga2O3 and Related Ultra-Wide Bandgap Power Semiconductor Oxides: New Energy Electronics Solutions for CO2 Emission Mitigation Materials | Free Full-Text | Ga2O3 and Related Ultra-Wide Bandgap Power Semiconductor Oxides: New Energy Electronics Solutions for CO2 Emission Mitigation](https://www.mdpi.com/materials/materials-15-01164/article_deploy/html/images/materials-15-01164-g001.png)
Materials | Free Full-Text | Ga2O3 and Related Ultra-Wide Bandgap Power Semiconductor Oxides: New Energy Electronics Solutions for CO2 Emission Mitigation
![Sensors | Free Full-Text | Ultraviolet Detectors Based on Wide Bandgap Semiconductor Nanowire: A Review Sensors | Free Full-Text | Ultraviolet Detectors Based on Wide Bandgap Semiconductor Nanowire: A Review](https://www.mdpi.com/sensors/sensors-18-02072/article_deploy/html/images/sensors-18-02072-g001.png)
Sensors | Free Full-Text | Ultraviolet Detectors Based on Wide Bandgap Semiconductor Nanowire: A Review
![Wide Band Gap Semiconductor Nanowires for Optical Devices: Low- Dimensionality Related…》(Vincent Consonni)电子书下载、在线阅读、内容简介、评论– 京东电子书频道 Wide Band Gap Semiconductor Nanowires for Optical Devices: Low- Dimensionality Related…》(Vincent Consonni)电子书下载、在线阅读、内容简介、评论– 京东电子书频道](https://img10.360buyimg.com/n11/jfs/t622/354/877906070/151596/89999d3f/5493f708N80993628.jpg)
Wide Band Gap Semiconductor Nanowires for Optical Devices: Low- Dimensionality Related…》(Vincent Consonni)电子书下载、在线阅读、内容简介、评论– 京东电子书频道
![Towards New Low-dimensional Semiconductor Nanostructures and New Possibilities | NTT Technical Review Towards New Low-dimensional Semiconductor Nanostructures and New Possibilities | NTT Technical Review](https://www.ntt-review.jp/archive_html/201008/images/sf5_fig02.gif)
Towards New Low-dimensional Semiconductor Nanostructures and New Possibilities | NTT Technical Review
![One‐dimensional and two‐dimensional synergized nanostructures for high‐performing energy storage and conversion - Li - 2020 - InfoMat - Wiley Online Library One‐dimensional and two‐dimensional synergized nanostructures for high‐performing energy storage and conversion - Li - 2020 - InfoMat - Wiley Online Library](https://onlinelibrary.wiley.com/cms/asset/b4fceab0-08b0-47ba-ad8a-520c5af8915c/inf212040-toc-0001-m.jpg)
One‐dimensional and two‐dimensional synergized nanostructures for high‐performing energy storage and conversion - Li - 2020 - InfoMat - Wiley Online Library
![Wide Band Gap Semiconductor Nanowires 1: Low-Dimensionality Effects and Growth (Electronics Engineering), Consonni, Vincent, Feuillet, Guy, eBook - Amazon.com Wide Band Gap Semiconductor Nanowires 1: Low-Dimensionality Effects and Growth (Electronics Engineering), Consonni, Vincent, Feuillet, Guy, eBook - Amazon.com](https://m.media-amazon.com/images/I/51XB41BCYBL.jpg)
Wide Band Gap Semiconductor Nanowires 1: Low-Dimensionality Effects and Growth (Electronics Engineering), Consonni, Vincent, Feuillet, Guy, eBook - Amazon.com
![Strain engineering of 2D semiconductors and graphene: from strain fields to band-structure tuning and photonic applications | Light: Science & Applications Strain engineering of 2D semiconductors and graphene: from strain fields to band-structure tuning and photonic applications | Light: Science & Applications](https://media.springernature.com/full/springer-static/image/art%3A10.1038%2Fs41377-020-00421-5/MediaObjects/41377_2020_421_Fig1_HTML.png)