Aims & Scope

Aims:

Nano-electrochemistry & Nano-photochemistry (NENP) is a pioneering, peer-reviewed journal dedicated to advancing research at the intersection of nanoscale electrochemistry and photochemistry. Our mission is to provide a platform for disseminating cutting-edge discoveries, innovative methodologies, and interdisciplinary insights that address global challenges in energy, environment, healthcare, and technology. The journal emphasizes the synergy between nanoscale materials and electrochemical/photochemical processes, fostering advancements in both fundamental science and practical applications. Researchers, academics, and industry professionals in chemistry, materials science, nanotechnology, energy, and environmental engineering will find the journal indispensable. By fostering collaboration across disciplines, NENP aims to accelerate innovation and address pressing global challenges through nanoscale science. It is initially published quarterly online by Scilight Press.

Scope:

We welcome original research articles, reviews, perspectives, and short communications highlighting novel insights, sustainable solutions, and transformative technologies. The journal prioritizes studies bridging theory and experiment with an emphasis on scalability, societal impact, and green chemistry principles. The scope includes but is not limited to:

Nano-electrochemistry

  • Nanomaterials for energy storage (e.g., batteries and supercapacitors) and conversion (fuel cells, electrocatalysis);
  • Nanoelectrode design, electrochemical sensors, and biosensors;
  • Corrosion science at the nanoscale and electrocatalytic mechanisms;
  • In situ/operando characterization techniques for nanoscale electrochemical processes.

Nano-photochemistry

  • Photocatalytic materials for environmental remediation, CO₂ reduction, and water splitting;
  • Light-driven nanoscale reactions, photochemical synthesis, and optoelectronic devices;
  • Plasmonic and quantum effects in photochemistry, including light-matter interactions;
  • Advanced spectroscopy and imaging of photochemical dynamics at the nanoscale.

Interdisciplinary Frontiers

  • Hybrid systems integrating electrochemical and photochemical processes (e.g., photoelectrocatalysis and solar-fuel technologies);
  • Smart nanomaterials responsive to dual stimuli (light/electricity) for biomedical or environmental applications;
  • Theoretical modeling, machine learning, and AI-driven design of functional nanomaterials.