Breakthrough technology: Carbon nanotube membranes with Pd-Cu modification …

The adverse effects of excess nitrate in water on human productivity and lives have received increasing attention due to the discharge of industrial wastewater and the overuse of farmland fertilizers. An international team of researchers has conducted an in-depth study of the significant need and challenge of efficient nitrate removal.

Several techniques have been used to eliminate nitrate from water, such as biological denitrification is technologically mature, cost-effective, and widely used. However, biological processes are often sluggish and easily affected by variable environmental conditions, such as temperature and the availability of carbon supplies. The researchers suggested that electrocatalytic technology is a promising method for nitrate removal because no chemicals are needed, no sludge is produced, and the implementation of the methodology is convenient.

Most of the electrodes currently used for electrocatalytic nitrate reduction are conventional plate cathodes implemented in parallel plate reactors where the mass transfer is strongly limited. Consequently, the overall electrocatalytic nitrate reduction rate decreases. Novel reactive electrochemical membranes (REMs) for nitrate reduction had previously been reported, but the synthetic processes for these proposed materials are complicated and the high cost of preparation has hindered the practical application of REMs.

To address these barriers, researchers from Minzu University of China and Wuhan University prepared a Pd-Cu modified carbon nanotube membrane that was fabricated with an electrodeposition method and used to reduce nitrate in a flowthrough electrochemical reactor. Their study reveals that the membrane obtained with a Pd : Cu ratio of 1:1 exhibited a relatively high nitrate removal efficiency and N₂ selectivity. This study entitled “Electrocatalytic reduction of nitrate using Pd-Cu modified carbon nanotube membranes” is published online in Frontiers of Environmental Science & Engineering in 2023.

In this study, the research team fabricated a novel Pd-Cu modified carbon nanotube membrane cathode on a polyvinylidene fluoride (PVDF) substrate to overcome the mass transfer problem during nitrate reduction. Initially, to determine the optimal potential for electrocatalytic nitrate reduction in flow-through mode, nitrate reduction was conducted with Pd-Cu-modified CNT membranes with different potentials ranging from −2.0 to −0.4 V. The team noted that the optimal potential and duration for code position of Pd and Cu were −0.7 V and 5 min, respectively, according to linear scan voltammetry results for CNT membranes in different solutions.

The second question the team examined was the effect of the Pd-Cu molar ratio and electrode potential on nitrate removal. The team noted that the membrane obtained with a Pd: Cu ratio of 1:1 exhibited a relatively high nitrate removal efficiency and N₂ selectivity. Nitrate was almost completely reduced (~99 %) by the membrane at potentials lower than −1.2 V. However, −0.8 V was the optimal potential for nitrate reduction in terms of both nitrate removal efficiency and product selectivity. The nitrate removal efficiency was 56.2 %, and the N₂ selectivity was 23.8 % for the Pd: Cu=1:1 membrane operated at −0.8 V.

The third question the team investigated was the effect of solution conditions. They noted that nitrate removal was enhanced under acidic conditions, while N₂ selectivity was decreased. The concentrations of Cl⁻ ions and dissolved oxygen showed little effect on nitrate reduction.

In addition, to illustrate the effect of the flow-through operation on mass transfer, the team evaluated the effect of membrane flux on nitrate reduction and calculated the mass transfer rate constants at different membrane fluxes. They note that the mass transfer rate constant was greatly improved by 6.6 times from 1.14 × 10⁻³ m/h at a membrane flux of 1 L/(m²·h) to 8.71 × 10⁻³ m/h at a membrane flux of 15 L/(m²·h), which resulted in a significant increase in the nitrate removal rate from 13.6 to 133.5 mg/(m²·h).

Pd-Cu-modified CNT membranes were successfully prepared via the electrodeposition method, and a flow-through electrocatalytic system was constructed to reduce nitrate in this study. This technology has broad application prospects for effective nitrate reduction and is worthy of further modification in practice.

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About Higher Education Press

Founded in May 1954, Higher Education Press Limited Company (HEP), affiliated with the Ministry of Education, is one of the earliest institutions committed to educational publishing after the establishment of P. R. China in 1949. After striving for six decades, HEP has developed into a major comprehensive publisher, with products in various forms and at different levels. Both for import and export, HEP has been striving to fill in the gap between domestic and foreign markets and meet the demand of global customers by collaborating with more than 200 partners throughout the world and selling products and services in 32 languages globally. Now, HEP ranks among China’s top publishers in terms of copyright export volume and the world’s top 50 largest publishing enterprises in terms of comprehensive strength.

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About Frontiers of Environmental Science & Engineering

Frontiers of Environmental Science & Engineering (FESE) is the leading-edge forum for peer-reviewed original submissions in English on all main branches of environmental disciplines. FESE welcomes original research papers, review articles, short communications, and views & comments. All the papers will be published within 6 months since they are submitted. The Editors-in-Chief are Prof. Jiuhui Qu from Tsinghua University, and Prof. John C. Crittenden from Georgia Institute of Technology, USA. The journal has been indexed by almost all the authoritative databases such as SCI, Ei, INSPEC, SCOPUS, CSCD, etc.

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