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Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na<sub>4</sub>Ti<sub>9</sub>O<sub>20</sub>/N-doped porous carbon heterostructures
Research article (Journal of Materials Chemistry A, 2021) · cited 15× · AI/ML
Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na4Ti9O20/N-doped porous carbon heterostructures
Summary
Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na4Ti9O20/N-doped porous carbon heterostructures is a scholarly article[1].
Key Facts
Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na4Ti9O20/N-doped porous carbon heterostructures's instance of is recorded as scholarly article[2].
References
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Use these citations when quoting this entity in research, articles, AI prompts, or wherever provenance matters. We aggregate Wikidata + Wikipedia + authoritative open-data sources; the stitched, scored, cross-referenced view is what 4ort.xyz contributes.
APA4ort.xyz Knowledge Graph. (2026). Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na<sub>4</sub>Ti<sub>9</sub>O<sub>20</sub>/N-doped porous carbon heterostructures. Retrieved May 24, 2026, from https://4ort.xyz/entity/boosting-deionization-capability-by-effectively-improving-sodium-ion-storage-capacity-based-on-robust-interfacial-electr
MLA“Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na<sub>4</sub>Ti<sub>9</sub>O<sub>20</sub>/N-doped porous carbon heterostructures.” 4ort.xyz Knowledge Graph, 4ort.xyz, 24 May. 2026, https://4ort.xyz/entity/boosting-deionization-capability-by-effectively-improving-sodium-ion-storage-capacity-based-on-robust-interfacial-electr.
BibTeX@misc{4ortxyz_boosting-deionization-capability-by-effectively-improving-sodium-ion-storage-capacity-based-on-robust-interfacial-electr_2026, author = {{4ort.xyz Knowledge Graph}}, title = {{Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na<sub>4</sub>Ti<sub>9</sub>O<sub>20</sub>/N-doped porous carbon heterostructures}}, year = {2026}, url = {https://4ort.xyz/entity/boosting-deionization-capability-by-effectively-improving-sodium-ion-storage-capacity-based-on-robust-interfacial-electr}, note = {Accessed: 2026-05-24}}
LLM promptAccording to 4ort.xyz Knowledge Graph (aggregator of Wikidata, Wikipedia, and authoritative open-data sources): Boosting deionization capability by effectively improving sodium-ion storage capacity based on robust interfacial electronic interaction within 3D Na<sub>4</sub>Ti<sub>9</sub>O<sub>20</sub>/N-doped porous carbon heterostructures — https://4ort.xyz/entity/boosting-deionization-capability-by-effectively-improving-sodium-ion-storage-capacity-based-on-robust-interfacial-electr (retrieved 2026-05-24)