Call for paper 〔OPEN〕

My submissions

Registration 〔OPEN〕

My tickets

〔CLOSED〕
Introduction

Carbon neutral energy sources that are scalable, deployable, and cost effective will be required at an unprecedented scale to halt irreversible climate change. Expanded utilization of solar energy requires efficient and inexpensive storage of intermittent power for use on demand. Solar fuels from water splitting are one of the most promising methods to store bulk renewable energy because they can provide an energy-dense fuel, with a minimal carbon footprint, and without competing with food stocks.

Photoelectrochemical systems that perform direct reduction of carbon dioxide to solar fuels represent an attractive route towards the production of next generation fuels on demand. However, the availability of (photo)electrocatlytic systems that can efficiently and selectively reduce carbon dioxide is currently limited. In addition, materials system integration poses significant challenges as catalyst//semiconductor and/or protection layer/semiconductor interface formation adds complexity in addressing functionality and performance issues. Therefore, deep understanding of materials property as isolated as well as integrated systems is absolutely vital to promote fast advancements in this field.

This symposium fosters a multidisciplinary and interdisciplinary approach to production of solar fuels. Latest results and advancements in photoelectrochemical systems, with specific focus on CO2 reduction, are presented. Specific focus on catalyst discovery with high activity and selectivity for CO2 reduction, as well as light absorbers, protection layers, and membranes for product sepatation will be address. In addition in situ and in operando measurements, and fundamental understanding to enable new materials discovery will be presented.

Call for paper

Important date

2016-10-13
Abstract submission deadline

Submission Topics

  • Electrocatalysts and photoelectrocatalysts for selective and efficient CO2 reduction

  • Photoelectrochemical integrated systems for solar fuel production (H2 and CO2reduction)

  • Interfacial band-edge energetics and mitigation of loss mechanism

  • In situ and operando characterization of (photo)electrocatalytic systems

  • Novel materials discovery and fundamental understanding of materials property for solar fuel production

  • Novel materials architectures for confined catalysis, improved light harvesting and light management, and excited states photocatalysis

  • Biohybrid approaches for solar fuel formation

  • Cell design and operating conditions for photoelectrocatalytic CO2 reduction

Submit Comment
Verify Code Change Another
All Comments
Important Date
  • Conference Date

    Apr 17

    2017

    to

    Apr 21

    2017

  • Oct 13 2016

    Abstract Submission Deadline

  • Apr 21 2017

    Registration deadline

Contact Information