夏明岗
- 教授
- Supervisor of Doctorate Candidates
- Supervisor of Master's Candidates
- E-Mail:
- Date of Employment:2002-04-09
- Education Level:With Certificate of Graduation for Doctorate Study
- Professional Title:教授
- Status:Employed
- Alma Mater:西安交通大学
- College:School of Physics
- Discipline:Physics
- Papers
Template-Free Gradient Selective Etching of Porous Carbon Nanospheres: Synergistic Dielectric Loss Optimization and Bifunctional Microwave Absorption-Corrosion Resistance Integration
Release Time:2026-01-30 Hits:
- Date:2026-01-30
- Impact Factor:12.1
- DOI Number:10.1002/smll.202507680
- Title of Paper:Template-Free Gradient Selective Etching of Porous Carbon Nanospheres: Synergistic Dielectric Loss Optimization and Bifunctional Microwave Absorption-Corrosion Resistance Integration
- Journal:Small
- Summary:The development of microwave-absorbing coatings for saline environments confronts dual challenges: dielectric loss optimization and porous carbon corrosion resistance. A solvent-mediated dynamic etching strategy achieving dual structural synergy is proposed. Acetone-regulated pore architecture enables template-free gradient etching, achieving tunable electromagnetic parameters and optimized absorption performance through pore size differentiation in nitrogen-doped 3D networks. In situ surface deoxygenation constructs hierarchical superhydrophobic micropores, decoupling pore topology from moisture adsorption. By bridging atomic-scale defect engineering and macroscopic interface optimization, a microstructure-mediated dielectric regulation paradigm is established. The optimized hollow porous carbon nanoparticles etched by 130 mL of acetone (HPCNs-130) demonstrate exceptional performance with -16.0 dB reflection loss at 2.78 mm thickness and 2.28 GHz bandwidth at 4.61 mm. Crucially, 48 h salt spray tests confirm superior corrosion resistance versus uncoated substrates. The coating significantly reduces the corrosion current from 25.44 to 0.53 mu A cm- 2, achieving a corrosion inhibition efficiency of 97.9%. This work proposes a novel solvent-mediated dynamic etching strategy, enabling template-free and gradient-controlled pore architecture, overcoming template-dependent structural limitations. By bridging atomic-scale defect engineering and macroscopic interface optimization, a structure-function synergy paradigm is demonstrated that concurrently addresses electromagnetic attenuation and electrochemical degradation, providing transformative solutions for marine infrastructure protection.
- First Author:娄琦
- Correspondence Author:夏明岗
- Document Code:001573556600001
- Volume:21
- Issue:44
- ISSN:1613-6810
- Translation or Not:No
- Date of Publication:2025-09-25
- Included Journals:SCI、SCI