A new strategy for the electrochemical reduction of nitrate to ammonia

Proposed structure of Cu-incorporated PTCDA and schematic diagram illustrating its advantage of selectively reducing NO3− into NH3 via direct 8-eletron transfer. Red, white, gray, brilliant-blue, and green spheres represent the O, H, C, Cu, and N atoms, respectively. Credit: Chen et al.

Ammonia (NH3) is a colorless, gaseous and water-soluble compound used in several sectors, including agriculture, the energy sector, and a variety of industries. For over a century, the main way of producing large quantities of ammonia has been via the Haber-Bosch process, which entails the use of high pressure to produce a chemical reaction that enables the direct synthesis of ammonia from hydrogen and nitrogen.


While the Haber-Bosch process enables the mass production of ammonia, it is known to be harmful for both humans and the environment, as it involves the consumption of fossil fuels and thus aggravates the greenhouse effect. Due to these undesirable effects, researchers have sought alternative methods for producing ammonia via N2−H2O chemical reactions under ambient conditions, some of which utilize renewable energy sources.

Some of these new techniques for the production of ammonia have been found to be effective and relatively inexpensive. Nonetheless, they typically only allowed researchers to produce limited quantities of ammonia and exhibited a poor selectivity, due to the inert N≡N bond and the ultralow solubility of N2 in water.

Researchers at South China University of Technology and Argonne National Laboratory have recently devised a new electrochemical strategy to produce ammonia through the reduction of nitrate. Their method, introduced in a paper published in Nature Energy, is based on the use of a copper-molecular solid catalyst.

“Obtaining NH3 directly from non−N2 sources is considered a revolutionary strategy to address the concerns associated with previous ammonia production processes,” Haihui Wang, one of the researchers who carried out the study, told Phys.org. “In the search for nitrogen-containing alternatives other than N2 to synthesize NH3, the nitrate anion (NO3) stands out due to the fact that the lower dissociation energy of N=O bond (204 kJ mol-1) compared with N-N triple bond (941 kJ mol-1), and the enrichment of NO3 in water resources caused environmental pollution and threatens human health.”

Selectively converting NO3 to NH3under ambient conditions and in a H2O-based system could be a greener alternative for the mass production of NH3. This alternative conversion would alleviate the environmental problems associated with current methods for producing ammonia on a large scale, while also decreasing energy consumption.

A new strategy for the electrochemical reduction of nitrate to ammonia
Screening of the element with the highest activity. a, The Faradaic efficiency of NH3 (blue) and NO2− (mauve) of various elements incorporated in PTCDA under a potential of −0.4 V versus RHE. b, The EDD of NO3– on 1Cu–PTCDA(¬103) (left), 1Ni–PTCDA(¬103) (centre) and 1Ti–PTCDA(¬103) (right). Blue, dark-blue, purple, sky-blue and green spheres represent the Cu, Ni, Ti, N and O atoms, respectively. The blue electronic cloud indicates charge accumulation and the red electronic cloud indicates charge depletion. c, The projected density of states (PDOS) of *NO3 on 1Cu–PTCDA (¬103) (left), 1Ni–PTCDA(¬103) (centre) and 1Ti–PTCDA(¬103) (right). Credit: Chen et al.

“Converting NO3 into NH3 is far from an easy task, as it requires an eight-electron transfer reaction as well as a slightly lower reaction potential (i.e., 1.20 V versus the reversible hydrogen electrode or RHE) than that of the five−electron conversion of NO3 to N2 (1.25 V versus RHE),” Wang explained. “Various electrocatalytic systems with different heterogeneous catalysts (such as Cu, Ag, Au, and so on) have been proposed in the past, but most of them tend to produce N2 via five-electron reduction of NO3 rather than the desired eight-electron reduction.”

The practical potential of converting NO3 to NH3 is below what is known as the hydrogen evolution reaction (HER) potential, which leads to the generation of H2. This can reduce the overall efficiency of the production of NH3.

In their study, Wang and his colleagues were able to achieve the direct eight-electron reduction of NO3 to NH3, catalyzed by Cu-incorporated crystalline 3,4,9,10-perylenetetracarboxylic dianhydride (PTCDA) with a low energy barrier way. The catalyst they used exhibited a high yield rate and outstanding selectivity, effectively suppressing HER.

“We screened catalysts with the preparation of a series of metals incorporated in PTCDA, such as Cu, Ag, Au, Ru, Rh, Ir, Pd, Pt, Bi, Ti, Cr, Mn, Fe, Co, Ni, Y, Zr, Mo, La and Ce,” Wang explained. “We found that the high performance of our catalyst can be attributed to the unique electron configuration of Cu 3d orbital showing increased overlap with nitrate O 2p orbitals to enhance charge transfer, as well as the structure of PTCDA, which helps to regulate the transfer of protons and electrons to the active Cu centers and then to inhibit HER and promote H-N binding.”

The electrochemical method introduced by Wang and his colleagues could address the challenges currently associated with mass NH3 production. In initial tests, this method achieved Faradaic efficiencies between 60% and 86% and NH3 production rates between approximately 400 and 900 μg h–1 cm–2 at applied potentials of −0.4 to −0.6 V versus RHE.

The results are significantly better than those achieved using other methods for the electrochemical reduction of N2 to NH3. For example, lithium-mediated methods, which are the most known for achieving relatively high yield rates in the electroreduction of N2-to-NH3, achieved a production rate of less than 36 μg h-1 cm.

A new strategy for the electrochemical reduction of nitrate to ammonia
Electrocatalytic performances of O-Cu–PTCDA. a, Linear sweep voltammetry curves of O-Cu–PTCDA tested in 0.1 M PBS (black), 0.1 M PBS thatcontained NO2− (red) and 0.1 M PBS that contained NO3− (blue). b, NH3 yield rate at different potentials at the second hour. c, NH3 Faradaic efficiency at different potentials at the second hour. d, NH3 yield rate at different times at −0.4 V versus RHE up to 4 h. e, NH3 (blue) and NO2− (mauve) Faradaic efficiencies at different times at −0.4 V versus RHE up to 4 h. f, The overall NH3 yield rate (blue) and total Faradaic efficiency (mauve) detected by 1H NMR spectroscopy and an indophenol blue method after the 4-h experiment. Credit: Chen et al.

The recent study by Wang and his colleagues also opens up new possibilities for the recycling of nitrogen (NO3) in wastewater. For several years, NO3 was considered to be a toxic water contaminant and was usually transferred into gaseous nitrogen and returned to the air. Recent studies, however, suggest that the high amount of nitrogen in wastewater could in fact be recycled for fertilization.

“The total nitrogen discharged into the water per year is 14.5 ± 3.1 million tons in China, which is about 50% of the annual consumption of synthetic nitrogen (300.5 million tons in 2016),” Wang said. “In 2016, the United States planted 94 million acres of corn, using about 8.9 billion kilograms of nitrogen annually, which accounts for 40% of the annual nitrogen use in the United States. However, it is worth noting that 2.4 billion kilograms of nitrogen is available in wastewater each year.The statistics prove that nitrogen in wastewaters could be a valuable resource.”

In addition to allowing the large-scale production of ammonia in ways that are more environmentally friendly, the recent work by Wang and his colleagues could pave the way toward the development of wastewater management systems with nitrogen conversion capabilities. These systems would enable the recycling of large quantities of nitrogen, ultimately optimizing the use of global resources and protecting the environment.

While the results are promising, the researchers still need to overcome two technical challenges before their method can be applied in real-world settings. These challenges will be the main focus of their next set of studies.

“On the one hand, our future studies will be aimed at enhancing the catalyst’s structure to further improve its long-term stability,” Wang said. “In this work, the NH3 yield rate decreased from 337.8 μg h-1 cm-2 to 140.3 μg h-1 cm-2 after 15 hours, after which it was substantially stable and maintained an NH3 yield rate of 130.8 μg h-1 cm-2 after 40 hours. On the other hand, we will work on the large-scale application of NH3 electrosynthesis, developing an electric-driving flow device for the direct and continuous mass production of high-purity liquid ammonia or ammonium salt. We plan to devise a simple method for the direct purification and collection of the products, which removes the need for additional purification, transportation and other procedures.”


Achieving highly efficient ammonia synthesis by altering the rate-determining step


More information:
Electrochemical reduction of nitrate to ammonia via direct eight-electron transfer using a copper-molecular solid catalyst. Nature Energy (2020). DOI: 10.1038/s41560-020-0654-1.

Managing nitrogen to restore water quality in China. Nature (2020). DOI: 10.1038/s41586-019-1001-1

Recycling fertilizer. Nature (2020). DOI: 10.1038/s41560-020-0670-1

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A new strategy for the electrochemical reduction of nitrate to ammonia (2020, August 31)
retrieved 31 August 2020
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