TY - JOUR
AU1 - Latsuzbaia, R.
AU2 - Bisselink, R.
AU3 - Anastasopol, A.
AU4 - Meer, H.
AU5 - Heck, R.
AU6 - Yagüe, M.
AU7 - Zijlstra, M.
AU8 - Roelands, M.
AU9 - Crockatt, M.
AU1 - Goetheer, E.
AU1 - Giling, E.
AB - Keywords Electroorganic synthesis · Continuous production · HMF · FDCA · Nickel oxy-hydroxide electrode and membrane technologies, provide new opportunities for 1 Introduction electrochemical manufacturing. Production of building blocks and fuels derived from bio- Sustainable electricity production, such as wind and solar mass and other renewable resources in a sustainable fashion based, is expected to exhibit an accelerated global growth is critical for a complete independence from fossil fuels. rate of 2.9% annually until 2040, according to the U.S. This creates a great opportunity for the transformation of Energy Information Administration (EIA) [1]. However, this the chemical industry towards more sustainable operation, energy is produced intermittently and requires large storage especially in the light of new policies imposed by the “Paris systems to compensate for times of shortfall [2]. Electrosyn- Climate Agreement”. thesis can utilize this energy for production of chemicals Recently, electrochemical conversion has been also and fuels. Especially with the growing global shift towards applied in biomass processing [3, 4]. Among various sus- more sustainable technologies in science and industry, the tainable material resources, lignocellulosic biomass is abun- electrochemical production of chemicals is more relevant dant, cheap, and many platform sugars can be derived from than ever. It has the potential 
TI - Continuous electrochemical oxidation of biomass derived 5-(hydroxymethyl)furfural into 2,5-furandicarboxylic acid
JF - Journal of Applied Electrochemistry
DO - 10.1007/s10800-018-1157-7
DA - 2018-02-28
UR - https://www.deepdyve.com/lp/springer-journals/continuous-electrochemical-oxidation-of-biomass-derived-5-tArwX2XsYC
SP - 611
EP - 626
VL - 48
IS - 6
DP - DeepDyve
ER -