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3D printed SrNbO2N photocatalyst for degradation of organic pollutants in water

3D printed SrNbO2N photocatalyst for degradation of organic pollutants in water
3D printed SrNbO2N photocatalyst for degradation of organic pollutants in water
Organic pollutants in water are a major concern for the environment and human health, and require urgent attention. Here, we developed for the first time monolithic structures by 3D printing of perovskite metal oxynitride, SrNbO2N, for photocatalytic degradation of organic pollutant in water. Advanced, synchrotron-based XRD-CT measurements were employed to gain structural insight into photocatalyst formulation and assess the fidelity of design in terms of both the chemical and physical form of the photocatalysts to be imaged. Our 3D printed material showed excellent photocatalytic activity, degrading 100% of methylene blue (MB) as well as good stability for three cycle operations. This is due to high adsorption of the 3D printed oxynitride towards MB which enhanced its photoredox reactivity. It is also evident from the excellent charge transfer demonstrating a charge transfer rate of (1.5 ± 0.2) × 108 s−1. We performed Time-Dependent Density Functional Theory (TD-DFT) calculations to understand the photocatalyst structure and degradation pathways. Our calculated band gap (at Γ) of 1.88 eV is in good agreement with the experimental values. We found that the highest valence bands were contributed by N p orbitals and the lowest conduction bands corresponded to Nb d orbitals offering avenues for fine-tuning the band gap. Hence, the ability to tailor photocatalyst monoliths by 3D printing renders their water treatment application more facile compared to their powder suspension counterparts.
2633-5409
3461-3472
Iborra Torres, Antonio
231fb0fc-78fd-40ea-9ebd-0bb0c6131e71
Huš, Matej
af54ab30-fd85-4b9e-b923-b85138acc300
Nguyen, Kiem
1ad3ce14-31cd-4d70-825a-5a6b206a0095
Vamvakeros, Antonis
dd787de2-c073-4101-b645-afc8b0ce2168
Tariq Sajjad, Muhammad
f38e6e5a-406c-4cd3-82da-5c769be9efe1
Dunn, Steven
f1362c73-8216-4266-a40d-b25aa3f55880
Mertens, Myrjam
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Jacques, Simon D. M.
048e1cdc-70be-412d-852a-5e91ec212121
Beale, Andrew M.
a6013448-9364-4b91-9448-576e40b252ca
Likozar, Blaž
9ccc6dba-9ec3-44e9-a9e9-47224296e2fd
Hyett, Geoffrey
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Kellici, Suela
f11dc1cd-d6eb-46e4-9d3d-a26033f1d92c
Middelkoop, Vesna
abb3e158-f13b-4f26-ba62-1e52b26e7a19
Iborra Torres, Antonio
231fb0fc-78fd-40ea-9ebd-0bb0c6131e71
Huš, Matej
af54ab30-fd85-4b9e-b923-b85138acc300
Nguyen, Kiem
1ad3ce14-31cd-4d70-825a-5a6b206a0095
Vamvakeros, Antonis
dd787de2-c073-4101-b645-afc8b0ce2168
Tariq Sajjad, Muhammad
f38e6e5a-406c-4cd3-82da-5c769be9efe1
Dunn, Steven
f1362c73-8216-4266-a40d-b25aa3f55880
Mertens, Myrjam
91689879-2614-4b06-ae2e-49312150065f
Jacques, Simon D. M.
048e1cdc-70be-412d-852a-5e91ec212121
Beale, Andrew M.
a6013448-9364-4b91-9448-576e40b252ca
Likozar, Blaž
9ccc6dba-9ec3-44e9-a9e9-47224296e2fd
Hyett, Geoffrey
4f292fc9-2198-4b18-99b9-3c74e7dfed8d
Kellici, Suela
f11dc1cd-d6eb-46e4-9d3d-a26033f1d92c
Middelkoop, Vesna
abb3e158-f13b-4f26-ba62-1e52b26e7a19

Iborra Torres, Antonio, Huš, Matej, Nguyen, Kiem, Vamvakeros, Antonis, Tariq Sajjad, Muhammad, Dunn, Steven, Mertens, Myrjam, Jacques, Simon D. M., Beale, Andrew M., Likozar, Blaž, Hyett, Geoffrey, Kellici, Suela and Middelkoop, Vesna (2023) 3D printed SrNbO2N photocatalyst for degradation of organic pollutants in water. Materials Advances, 4 (16), 3461-3472. (doi:10.1039/D2MA01076C).

Record type: Article

Abstract

Organic pollutants in water are a major concern for the environment and human health, and require urgent attention. Here, we developed for the first time monolithic structures by 3D printing of perovskite metal oxynitride, SrNbO2N, for photocatalytic degradation of organic pollutant in water. Advanced, synchrotron-based XRD-CT measurements were employed to gain structural insight into photocatalyst formulation and assess the fidelity of design in terms of both the chemical and physical form of the photocatalysts to be imaged. Our 3D printed material showed excellent photocatalytic activity, degrading 100% of methylene blue (MB) as well as good stability for three cycle operations. This is due to high adsorption of the 3D printed oxynitride towards MB which enhanced its photoredox reactivity. It is also evident from the excellent charge transfer demonstrating a charge transfer rate of (1.5 ± 0.2) × 108 s−1. We performed Time-Dependent Density Functional Theory (TD-DFT) calculations to understand the photocatalyst structure and degradation pathways. Our calculated band gap (at Γ) of 1.88 eV is in good agreement with the experimental values. We found that the highest valence bands were contributed by N p orbitals and the lowest conduction bands corresponded to Nb d orbitals offering avenues for fine-tuning the band gap. Hence, the ability to tailor photocatalyst monoliths by 3D printing renders their water treatment application more facile compared to their powder suspension counterparts.

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More information

Accepted/In Press date: 28 February 2023
e-pub ahead of print date: 13 March 2023
Published date: 14 August 2023
Additional Information: Funding Information: Antonio Iborra-Torres thanks the EPSRC for provision of funding for his doctorate. Kiem Nguyen thanks LSBU for the PhD scholarship. Muhammad Tariq Sajjad thanks LSBU and Edinburgh Instrument for financial support. Matej Huš and Blaž Likozar were funded by the Slovenian Research Agency (M. H.: project J1-3020, core funding P2-0421, infrastructure funding I0-0039; B. L.: project N2-0135, core funding P2-0152). We would like to thank ESRF for beamtime and Marco di Michiel (ID15A, ESRF) for preparing beamline instrumentation and setup and for his help with the experimental XRD-CT data acquisition. We particularly thank Raymond Kemps for his assistance with electron microscopy. The authors appreciate the financial and research support provided by their respective institutions. Publisher Copyright: © 2023 RSC.
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Identifiers

Local EPrints ID: 476310
URI: http://eprints.soton.ac.uk/id/eprint/476310
DOI: doi:10.1039/D2MA01076C
ISSN: 2633-5409
PURE UUID: aaf244e4-9d25-4477-9937-bd4281ab6f9f
ORCID for Geoffrey Hyett: ORCID iD orcid.org/0000-0001-9302-9723

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Date deposited: 19 Apr 2023 16:35
Last modified: 17 Mar 2024 03:31

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Contributors

Author: Antonio Iborra Torres
Author: Matej Huš
Author: Kiem Nguyen
Author: Antonis Vamvakeros
Author: Muhammad Tariq Sajjad
Author: Steven Dunn
Author: Myrjam Mertens
Author: Simon D. M. Jacques
Author: Andrew M. Beale
Author: Blaž Likozar
Author: Geoffrey Hyett ORCID iD
Author: Suela Kellici
Author: Vesna Middelkoop

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