TY - JOUR
T1 - Interfacial Photoelectrochemical Catalysis
T2 - Solar-Induced Green Synthesis of Organic Molecules
AU - Hardwick, Tomas
AU - Qurashi, Ahsanulhaq
AU - Shirinfar, Bahareh
AU - Ahmed, Nisar
N1 - Funding Information:
Marie Sk?odowska-Curie Actions COFUND Fellowship (Grant 663830) to N.A. is gratefully acknowledged. We thank the School of Chemistry, Cardiff Chemistry and the Welsh Government for their generous funding to COFUND Fellow (N.A). We would especially like to thank Prof. Laurence M. Peter (Department of Chemistry, University of Bath) for valuable discussions and suggestions.
Funding Information:
Nisar Ahmed obtained his Ph.D. in 2012 in organic chemistry, working in the group of Prof. Kwang S. Kim (POSTECH, Korea). Then, he moved to the University of Zurich for a postdoctoral stay under a Novartis Fellowship. In 2015, he became a senior research associate at the University of Bristol. In late 2016, he was awarded a prestigious Marie Curie COFUND Fellowship (Sêr Cymru and Horizon 2020 program) to commence his research career in microflow organic electrosynthesis at the School of Chemistry, Cardiff University. His research interests are the development of green and sustainable technologies in organic synthesis using batch and flow electrochemistry and organic supramolecular chemistry.
Publisher Copyright:
© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim
PY - 2020/4/21
Y1 - 2020/4/21
N2 - Many oxidation and reduction reactions in conventional organic synthesis rely on harsh conditions, toxic or corrosive substances, and environmentally damaging chemicals. In addition, competing reactions may take place, some of which produce hazardous waste products and, therefore, reaction selectivity suffers. To overcome such synthetic drawbacks, an enormous effort is being devoted to find alternative processes that operate much more efficiently, requiring milder conditions to contribute to a greener economy and provide urgently needed new pathways with enhanced selectivity. Fortunately, there is a strategy that has attracted global interest from multiple disciplines that involves the use of sunlight to perform artificial photosynthesis, in which a photoelectrochemical cell splits water into hydrogen fuel, reduces CO2 into “solar” fuels, and more recently, convert organic chemicals into higher value products. Recently, photoanode and photocathode materials have emerged as useful tools to perform organic oxidations and reductions for the synthesis of important molecules, other than just hydrogen or oxygen. Whereas many studies have focused on the degradation of unwanted and dangerous chemicals, solar-induced organic transformations have attracted much less attention. This Minireview summarizes some of latest research efforts in using photoelectrochemical cells to facilitate organic oxidation and reduction reactions to avoid valuable substances while avoiding toxic reagents and expensive precious metal catalysts. Future developments that will enable such technologies to broaden their scope are also considered.
AB - Many oxidation and reduction reactions in conventional organic synthesis rely on harsh conditions, toxic or corrosive substances, and environmentally damaging chemicals. In addition, competing reactions may take place, some of which produce hazardous waste products and, therefore, reaction selectivity suffers. To overcome such synthetic drawbacks, an enormous effort is being devoted to find alternative processes that operate much more efficiently, requiring milder conditions to contribute to a greener economy and provide urgently needed new pathways with enhanced selectivity. Fortunately, there is a strategy that has attracted global interest from multiple disciplines that involves the use of sunlight to perform artificial photosynthesis, in which a photoelectrochemical cell splits water into hydrogen fuel, reduces CO2 into “solar” fuels, and more recently, convert organic chemicals into higher value products. Recently, photoanode and photocathode materials have emerged as useful tools to perform organic oxidations and reductions for the synthesis of important molecules, other than just hydrogen or oxygen. Whereas many studies have focused on the degradation of unwanted and dangerous chemicals, solar-induced organic transformations have attracted much less attention. This Minireview summarizes some of latest research efforts in using photoelectrochemical cells to facilitate organic oxidation and reduction reactions to avoid valuable substances while avoiding toxic reagents and expensive precious metal catalysts. Future developments that will enable such technologies to broaden their scope are also considered.
KW - artificial photosynthesis
KW - interfaces
KW - organic synthesis
KW - photoelectrochemical cells
KW - solar fuels
UR - http://www.scopus.com/inward/record.url?scp=85083393736&partnerID=8YFLogxK
U2 - 10.1002/cssc.202000032
DO - 10.1002/cssc.202000032
M3 - Review article
C2 - 32100961
AN - SCOPUS:85083393736
SN - 1864-5631
VL - 13
SP - 1967
EP - 1973
JO - ChemSusChem
JF - ChemSusChem
IS - 8
ER -