CHEN Peng

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191 to 200 of 352 Results

4.jpg Nov 17, 2023 - Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution JPEG Image - 769.9 KB - MD5: c04678520e35e23d0be0225df4f99785
5.jpg Nov 17, 2023 - Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution JPEG Image - 894.8 KB - MD5: 72739b9505e7dd6a438c757c6d6e21ad
Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation Nov 14, 2023 - KONG Lingxuan Kong, Lingxuan; Wen, Hanqi; Luo, Yifei; Chen, Xiaodong; Sheng, Xing; Liu, Yuxin; Chen, Peng, 2023, "Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation", https://doi.org/10.21979/N9/4D5WR2, DR-NTU (Data), V1 The use of conductive microneedles presents a promising solution for achieving high-fidelity electrophysiological recordings with minimal impact on interfaced tissue. However, conventional metal-based microneedle suffers from high electrochemical impedance and mechanical mismatch...
Figure 1. Scheme.png Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation PNG Image - 12.3 MB - MD5: 9809f9167ffdc9834582ce222d7f5e38
Figure 2. Characterization.png Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation PNG Image - 10.2 MB - MD5: e1f2626eb642971fc874411057f4d670
Figure 3. In Planta Biopotential Monitoring.png Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation PNG Image - 9.6 MB - MD5: bd1d9f357edfd8c880c1b0c68b13208c
Figure 4. Cation Fluctuation Monitoring.png Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation PNG Image - 391.5 KB - MD5: 82541471f40264dde726aaa038661f8c
Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER Feb 27, 2022 Gong, Jun; Chen, Peng, 2022, "Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER", https://doi.org/10.21979/N9/UZIK0N, DR-NTU (Data), V2, UNF:6:Cqe4Zh57FSIscgjU/DNOZA== [fileUNF] Atomically-thin 2D materials have changed the landscapes of many fields. Their applications however are limited by lack of methods for readily and scalable production with high quality. Herein, a simple strategy is reported to exfoliate pristine single or few-layered 2D materials...
Manuscript revised Carbon.docx Feb 27, 2022 - Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER MS Word - 4.3 MB - MD5: c86ce79b427de0549782ba9d45c9e7ec
0.0023 - NanoScope Analysis.txt Feb 27, 2022 - Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER Plain Text - 1.4 KB - MD5: b75b8d9a1426b6624f40edb6d0628342

4.jpg

Nov 17, 2023 - Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution

JPEG Image - 769.9 KB -

5.jpg

Nov 17, 2023 - Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution

JPEG Image - 894.8 KB -

Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation

Nov 14, 2023 - KONG Lingxuan

Kong, Lingxuan; Wen, Hanqi; Luo, Yifei; Chen, Xiaodong; Sheng, Xing; Liu, Yuxin; Chen, Peng, 2023, "Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation", https://doi.org/10.21979/N9/4D5WR2, DR-NTU (Data), V1

The use of conductive microneedles presents a promising solution for achieving high-fidelity electrophysiological recordings with minimal impact on interfaced tissue. However, conventional metal-based microneedle suffers from high electrochemical impedance and mechanical mismatch...

Figure 1. Scheme.png

Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation

PNG Image - 12.3 MB -

Figure 2. Characterization.png

Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation

PNG Image - 10.2 MB -

Figure 3. In Planta Biopotential Monitoring.png

Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation

PNG Image - 9.6 MB -

Figure 4. Cation Fluctuation Monitoring.png

Nov 14, 2023 - Dual-Conductive and Stiffness-Morphing Microneedle Patch Enables Continuous in Planta Monitoring of Electrophysiological Signal and Ion Fluctuation

PNG Image - 391.5 KB -

Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER

Feb 27, 2022

Gong, Jun; Chen, Peng, 2022, "Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER", https://doi.org/10.21979/N9/UZIK0N, DR-NTU (Data), V2, UNF:6:Cqe4Zh57FSIscgjU/DNOZA== [fileUNF]

Atomically-thin 2D materials have changed the landscapes of many fields. Their applications however are limited by lack of methods for readily and scalable production with high quality. Herein, a simple strategy is reported to exfoliate pristine single or few-layered 2D materials...

Manuscript revised Carbon.docx

Feb 27, 2022 - Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER

MS Word - 4.3 MB -

0.0023 - NanoScope Analysis.txt

Feb 27, 2022 - Graphene Quantum Dots Assisted Exfoliation of Atomically-thin 2D Materials and As-formed 0D/2D van der Waals Heterojunction for HER

Plain Text - 1.4 KB -

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