Multidisciplinary – Chemistry (MLC) - Journal of Engineering Research and Sciences (JENRS)

Multidisciplinary – Chemistry (MLC)

Section Information

Multidisciplinary Chemistry focuses on chemical research that bridges multiple scientific fields, integrates diverse methodologies, or contributes to cross-sector applications. It examines chemical processes, molecular systems, materials, reactions, and analytical techniques that connect chemistry with biology, physics, engineering, environmental science, medicine, and technology.

Modern multidisciplinary chemical research includes materials chemistry, chemical biology, catalysis, environmental chemistry, nanochemistry, computational chemistry, supramolecular systems, renewable energy chemistry, and translational applications in health and industry. Advances in spectroscopy, imaging, molecular design, data-driven chemistry, and synthetic methods continue to expand the reach of chemical science.

This section publishes experimental studies, theoretical analyses, applied research, methodological papers, and reviews addressing chemical innovations, cross-disciplinary concepts, and integrated approaches that advance chemistry and its applications across scientific domains.

Scope

Materials Chemistry and Functional Materials
- Hybrid materials, polymers, composites, and nanostructures
- Electronic, optical, magnetic, and catalytic materials
- Energy materials for batteries, fuel cells, and solar devices
- Design, synthesis, and characterization of multifunctional systems
Chemical Biology and Biochemistry Interfaces
- Biomolecular interactions, enzymatic mechanisms, and metabolic pathways
- Chemical probes, drug design, and bioorthogonal chemistry
- Protein engineering, peptide chemistry, and synthetic biology
- Chemical approaches to studying cellular and physiological processes
Catalysis and Reaction Engineering
- Homogeneous, heterogeneous, and enzymatic catalysis
- Green chemistry, sustainable synthesis, and process optimization
- Reaction kinetics, mechanisms, and reactor design
- Catalytic technologies for energy, environment, and industry
Environmental and Analytical Chemistry
- Chemical processes in air, water, soil, and ecosystems
- Pollutant detection, remediation, and environmental monitoring
- Spectroscopy, chromatography, and mass spectrometry innovations
- Sensor development and chemical imaging technologies
Nanochemistry and Molecular Engineering
- Nanoscale materials, self-assembly, and surface chemistry
- Molecular machines, supramolecular systems, and host–guest chemistry
- Quantum dots, nanocatalysts, and nanoscale design principles
- Interfaces between nanoscience, physics, and chemical engineering
Computational, Theoretical, and Data-Driven Chemistry
- Molecular modeling, quantum chemistry, and multiscale simulations
- Machine learning, cheminformatics, and predictive chemical design
- Reaction prediction, structure–property relationships, and big data tools
- Integration of computational insights with experimental chemistry
Energy, Sustainability, and Industrial Chemistry
- Renewable energy conversion, storage, and catalysis
- CO₂ capture, hydrogen production, and sustainable fuels
- Industrial processes, manufacturing chemistry, and scale-up methods
- Life-cycle assessment and sustainable chemical technologies
Translational, Applied, and Interdisciplinary Chemical Research
- Chemical applications in medicine, agriculture, and biotechnology
- Interfacing chemical methods with engineering and physics
- Cross-domain innovation and technology integration
- Safety, ethics, and regulation of emerging chemical technologies