Jinlin Chang

ORCID: 0009-0002-8708-662X
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About
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Research Areas
  • Advanced Sensor and Energy Harvesting Materials
  • Solar-Powered Water Purification Methods
  • Electrospun Nanofibers in Biomedical Applications
  • MXene and MAX Phase Materials
  • Electromagnetic wave absorption materials
  • Advanced Chemical Sensor Technologies
  • Surface Modification and Superhydrophobicity
  • Metallurgy and Material Forming
  • Advanced Antenna and Metasurface Technologies
  • Polydiacetylene-based materials and applications
  • Winter Sports Injuries and Performance
  • Gas Sensing Nanomaterials and Sensors
  • Dielectric materials and actuators
  • Adhesion, Friction, and Surface Interactions
  • Laser Material Processing Techniques
  • Metal Forming Simulation Techniques
  • Membrane Separation Technologies
  • Powder Metallurgy Techniques and Materials
  • Sports injuries and prevention
  • Energy Harvesting in Wireless Networks
  • Lower Extremity Biomechanics and Pathologies

Tsinghua University
2023-2024

State Key Laboratory of Tribology
2024

University of Manchester
2022-2023

Electromagnetic (EM) radiation pollution is increasing attention due to the popularization of electronic equipment. In recent years, various nanomaterials have been widely designed and developed for enhancement their EM interference shielding effectiveness (EMI SE). However, large amounts reported reviews focus on carbon materials transition metal carbides (e.g., MXenes), while applications nanocomposites in are still suffering from insufficient systematic analysis. Therefore, this paper...

10.1016/j.compositesb.2022.110269 article EN cc-by-nc-nd Composites Part B Engineering 2022-09-05

10.1016/j.mtchem.2024.101989 article EN Materials Today Chemistry 2024-03-13

Abstract Wearable photothermal materials can capture light energy in nature and convert it into heat energy, which is critical for flexible outdoor sports. However, the conventional membranes with low specific surface area restrict maximum capability, loose structure of electrospun membrane limits durability wearable materials. Here, an ultrathin nanostructure candle soot/multi‐walled carbon nanotubes/poly (L‐lactic acid) (CS/MWCNTs/PLLA) first prepared via solvent‐induced recrystallization....

10.1002/eom2.12454 article EN cc-by EcoMat 2024-05-19

Abstract Low friction ice sliding interfaces were critical for ski performance optimization. Traditional fluorinated waxes have attracted considerable attention enhancing the hydrophobicity, anti-wearing, and oxidation resistance of ski-ice base. However, toxicity complexity waxing process limited batch manufacturing low-cost non-toxic base, what is more, wax covering on base wore failed during skiing due to between ice. Herein, we demonstrated a novel ultra-high molecular weight...

10.1007/s40544-024-0891-6 article EN cc-by Friction 2024-08-15

Wearable photothermal materials can capture light energy in nature and convert it into heat energy, which is critical for flexible outdoor sports. However, the conventional membranes with low specific surface area restrict maximum capability, loose structure of electrospun membrane limits durability wearable materials. Here, an ultrathin nanostructure candle soot/ multi-walled carbon nanotubes / poly (l-lactic acid) (CS/MWCNTs/PLLA) first prepared via solvent-induced recrystallization. The...

10.22541/au.171030290.08546051/v1 preprint EN Authorea (Authorea) 2024-03-13

Wearable photothermal materials can capture light energy in nature and convert it into heat energy, which is critical for flexible outdoor sports. However, the conventional membranes with microstructure considerably restrict maximum capability of materials, dark surface hinders fashionability. Here, an ultrathin bioinspired nanostructure CS/MWCNTs/PLLA membrane first prepared via solvent-induced recrystallization. The white blood cell membrane-like nanowrinkles high specific area are...

10.2139/ssrn.4653646 preprint EN 2023-01-01
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