Waterborne Fluorine-Free Superhydrophobic Surfaces Exhibiting Simultaneous CO2 and Humidity Sorption

Research output: Contribution to journalArticleScientificpeer-review

Researchers

  • Avijit Baidya
  • Anagha Yatheendran
  • Tripti Ahuja
  • Chennu Sudhakar
  • Sarit Kumar Das
  • Robin Ras

  • Thalappil Pradeep

Research units

  • Indian Institute of Technology, Madras

Abstract

Recent progress in the field of superhydrophobic materials has proven their potential to solve many problems of the contemporary society. However, the use of such materials to capture moisture and CO2 from air, to help reduce the impact of global climate change is not explored. In addition, most of the time, fabrication of these materials needs organic solvents and fluorinated molecules involving multiple steps that hinder the use of nonwettable materials in everyday life. Herein, a waterborne, fluorine-free, robust superhydrophobic material synthesized at room temperature through a one-step chemical-modification process is reported, which exhibits moisture and CO2 capturing capability. While covalently grafted low surface energy hydrocarbon molecules control the bulk superhydrophobicity, the incorporated amine functionalities facilitate moisture and CO2 adsorption as these molecules (H2O and CO2) can easily diffuse through hydrocarbon assemblies. Being polar, H2O molecules are observed to readily interact with amine groups and favor the adsorption process. Synthesized material shows an approximate CO2 adsorption of 480 ppm (10.90 mmol L−1) in ambient conditions having 75% humidity. Multifunctionality along with durability of this material will help expand the applications of superhydrophobic materials.

Details

Original languageEnglish
Article number1901013
Pages (from-to)1-8
JournalAdvanced Materials Interfaces
Publication statusPublished - 1 Jan 2019
MoE publication typeA1 Journal article-refereed

    Research areas

  • environment-friendly, moisture sorption and CO capture, robust, superhydrophobicity, waterborne

ID: 36531726