A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applications
This paper reports the first-time synthesis of Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass were synthesized via solution combustion using glycine as fuel (1:1 fuel-to-oxidizer ratio). X-ray diffraction confirmed the desired crystalline phase, while Scherrer analysis indicated an average particle size of a...
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| Format: | Article |
| Language: | English |
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Engineering Society for Corrosion, Belgrade
2024-06-01
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| Series: | Zaštita Materijala |
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| Online Access: | https://www.zastita-materijala.org/index.php/home/article/view/1133 |
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| author | Natarajan Thiruveni Muthammal Ramu Dhanapal Prakash Babu Sadasivam Ponkumar Ramasamy Jayavell |
| author_facet | Natarajan Thiruveni Muthammal Ramu Dhanapal Prakash Babu Sadasivam Ponkumar Ramasamy Jayavell |
| author_sort | Natarajan Thiruveni |
| collection | DOAJ |
| description | This paper reports the first-time synthesis of Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass were synthesized via solution combustion using glycine as fuel (1:1 fuel-to-oxidizer ratio). X-ray diffraction confirmed the desired crystalline phase, while Scherrer analysis indicated an average particle size of approximately 60 nm. This was further supported by scanning electron microscopy, which revealed a particle size around 75 nm. Notably, the material exhibited a characteristic mesoporous structure, a signature feature of the solution combustion technique. Dielectric studies revealed a double exponential decay profile, signifying the presence of voids within the material. Importantly, the significantly smaller time constant (t2) compared to t1 highlights the material's suitability for long-term energy storage applications. |
| format | Article |
| id | doaj-art-61d5d57f87ce46fa823056f783a2cd2c |
| institution | OA Journals |
| issn | 0351-9465 2466-2585 |
| language | English |
| publishDate | 2024-06-01 |
| publisher | Engineering Society for Corrosion, Belgrade |
| record_format | Article |
| series | Zaštita Materijala |
| spelling | doaj-art-61d5d57f87ce46fa823056f783a2cd2c2025-08-20T02:24:00ZengEngineering Society for Corrosion, BelgradeZaštita Materijala0351-94652466-25852024-06-0165227928410.62638/ZasMat11331132A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applicationsNatarajan Thiruveni0Muthammal Ramu1Dhanapal Prakash Babu2Sadasivam Ponkumar3Ramasamy Jayavell4Department of Physics, Government Arts College for Women, Salem, IndiaDepartment of Physics, Sri Sarada college for women (Autonomous), Salem, IndiaSchool of Applied Sciences, Department of Physics, REVA University, Bangalore, IndiaDepartment of Physics, Thiruvalluvar Government Arts College, Namakkal, IndiaCrystal Growth Centre, Anna University, Chennai -600 025This paper reports the first-time synthesis of Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass were synthesized via solution combustion using glycine as fuel (1:1 fuel-to-oxidizer ratio). X-ray diffraction confirmed the desired crystalline phase, while Scherrer analysis indicated an average particle size of approximately 60 nm. This was further supported by scanning electron microscopy, which revealed a particle size around 75 nm. Notably, the material exhibited a characteristic mesoporous structure, a signature feature of the solution combustion technique. Dielectric studies revealed a double exponential decay profile, signifying the presence of voids within the material. Importantly, the significantly smaller time constant (t2) compared to t1 highlights the material's suitability for long-term energy storage applications.https://www.zastita-materijala.org/index.php/home/article/view/1133szo nanoceramics, solution combustion synthesis, energy storage, dielectric properties |
| spellingShingle | Natarajan Thiruveni Muthammal Ramu Dhanapal Prakash Babu Sadasivam Ponkumar Ramasamy Jayavell A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applications Zaštita Materijala szo nanoceramics, solution combustion synthesis, energy storage, dielectric properties |
| title | A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applications |
| title_full | A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applications |
| title_fullStr | A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applications |
| title_full_unstemmed | A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applications |
| title_short | A novel Sr0.99Zr(PO4)2:0.01Eu3+ ceramic glass viable for long term energy storage applications |
| title_sort | novel sr0 99zr po4 2 0 01eu3 ceramic glass viable for long term energy storage applications |
| topic | szo nanoceramics, solution combustion synthesis, energy storage, dielectric properties |
| url | https://www.zastita-materijala.org/index.php/home/article/view/1133 |
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