A sustainable solar-driven electrochemical process for reforming lignocellulosic biomass effluent into high value-added products: green hydrogen, carboxylic and vanillic acids

Izaías Campos da Paixão; Jussara Câmara Cardozo; Mayra Kerolly Sales Monteiro; Amanda Duarte Gondim; Lívia Nunes Cavalcanti; Domingos Fabiano de Santana Souza; Carlos A Martínez-Huitle; Elisama Vieira Dos Santos

doi:10.1039/d3ra05772k

A sustainable solar-driven electrochemical process for reforming lignocellulosic biomass effluent into high value-added products: green hydrogen, carboxylic and vanillic acids

RSC Adv. 2023 Dec 11;13(50):35755-35765. doi: 10.1039/d3ra05772k. eCollection 2023 Nov 30.

Authors

Izaías Campos da Paixão¹, Jussara Câmara Cardozo¹, Mayra Kerolly Sales Monteiro^{1

2}, Amanda Duarte Gondim¹, Lívia Nunes Cavalcanti¹, Domingos Fabiano de Santana Souza³, Carlos A Martínez-Huitle^{1

4}, Elisama Vieira Dos Santos^{1

4}

Affiliations

¹ Renewable Energies and Environmental Sustainability Research Group, Institute of Chemistry, Federal University of Rio Grande do Norte, Campus Universitário Av. Salgado Filho 3000 Lagoa Nova CEP 59078-970 Natal Rio Grande do Norte Brazil carlosmh@quimica.ufrn.br elisama.vieira@ufrn.br.
² Human Resources Program of the National Agency for Petroleum, Natural Gas and Biofuels - PRH-26-ANP, Graduate Program in Chemical Engineering - PPGEQ Lagoa Nova Natal RN 59078-970 Brazil.
³ Chemical Engineering Department, Universidade Federal do Rio Grande do Norte Senador Salgado Filho Avenue S/N - Lagoa Nova Natal 59078-970 RN Brazil.
⁴ National Institute for Alternative Technologies of Detection, Toxicological Evaluation and Removal of Micropollutants and Radioactives (INCT-DATREM), Institute of Chemistry, UNESP P.O. Box 355 14800 900 Araraquara SP Brazil.

Abstract

There is a growing concern with waste minimization and the promotion of the circular economy. Within this framework, using membrane-equipped electrochemical systems, the electrochemical oxidation (EO) of organic compounds and simultaneous hydrogen (H₂) production can considerably improve the sustainability and economic viability of this process. Here, we propose an innovative-integrate electrochemical treatment strategy to maximize the economic benefits and sustainability of selectively producing organic acids and energy-saving H₂ production from biomass platform compounds. The results clearly demonstrated that, on the one hand, more than 80 mg L^-1 of oxalic acid was obtained in the anodic reservoir (using a boron-doped diamond electrode) with an alkaline medium (0.5 mol L^-1 NaOH) by applying 100 mA cm^-2 as well as vanillic acid production of 0.6795 mg L^-1 under the same conditions. On the other hand, simultaneously green H₂ production greater than 2.6 L was produced, in the cathodic compartment with a Ni-Fe-based mesh as cathode, with a 90% faradaic efficiency during the process. Thus, the electrochemical conversion of lignocellulosic biomass effluent into high-value-added products and an energy vector was sustainably accomplished, suggesting that it is a promising energy-saving and cost-effective integrated approach for biomass valorization using solar energy.