Will the application fields of carbon molecular sieves change with the development of technology?

Deepening and Expansion in Existing Fields

• Gas Separation and Purification
  • Driven by the demand for higher – purity gases: With the development of high – end industries such as semiconductor manufacturing, the demand for ultra – high – purity gases is increasing. In the future, carbon molecular sieves will further improve the adsorption selectivity and separation efficiency for specific gases by improving the preparation process and surface modification techniques. This will meet the requirements for ultra – high – purity nitrogen, hydrogen, etc. in chip manufacturing.
  • Emergence of new gas separation demands: With the development of the new energy industry, there are new applications for carbon molecular sieves. For example, separating and purifying methane from biogas for bio – gas production, and recovering hydrogen from the exhaust gas of fuel cells. The application of carbon molecular sieves in these emerging gas – separation scenarios will continue to expand.
• Air Purification
  • Addressing new pollutants: With industrial development and the use of new materials, more types of new pollutants such as volatile organic compounds (VOCs) and odor – causing substances have emerged in the air. Carbon molecular sieves will enhance their adsorption capacity for these new pollutants by developing new adsorbent formulations and modification methods, further expanding their application scope in the air – purification field.
  • Integration with intelligent air – purification systems: With the development of smart homes and intelligent buildings, carbon molecular sieves will be combined with sensors, intelligent control systems, etc. to achieve intelligent and precise air purification. They can adjust the adsorption and purification strategies in real – time according to air quality.
• Water Treatment
  • Increasing demand for advanced treatment: As the requirements for water quality continue to rise, especially in the fields of advanced drinking – water treatment and high – end industrial water use, carbon molecular sieves will play a greater role. By combining with other water – treatment technologies such as membrane separation and advanced oxidation, they can more efficiently remove trace organic substances, heavy – metal ions, and other pollutants in water.
  • Desalination of seawater and utilization of brackish water: In the fields of seawater desalination and brackish – water utilization, carbon molecular sieves are expected to improve their adsorption performance and salt – resistance. They can be used to remove organic substances and trace pollutants in seawater, reducing the load of subsequent treatment processes and improving the efficiency and economy of seawater desalination and brackish – water utilization.

Exploration of New Application Fields

• Energy Storage: With the rapid development of electric vehicles and distributed energy, the demand for high – performance energy – storage materials is increasing. Carbon molecular sieves have a high specific surface area and porosity, and are expected to be used as electrode materials or auxiliary materials in energy – storage devices such as supercapacitors and lithium – ion batteries. This can improve the charge – discharge performance and cycle stability of the batteries.
• Biomedicine: With the progress of biomedical technology, the demand for the separation, purification, and detection of biomolecules is increasing. Carbon molecular sieves can achieve specific adsorption and separation of biomolecules such as proteins and nucleic acids through surface modification and functionalization, showing potential application prospects in biopharmaceuticals, clinical diagnosis, etc.
• Environmental Remediation: In environmental – remediation fields such as soil – pollution remediation and groundwater – pollution remediation, carbon molecular sieves can be used as adsorption materials to remove organic pollutants and heavy – metal ions from soil and groundwater. Through in – situ injection or surface covering, they can achieve rapid remediation and treatment of contaminated sites.