# Sol–Gel Synthesis and Multi-Technique Characterization of Graphene-Modified Ca2.95Eu0.05Co4Ox Nanomaterials

**Authors:** Serhat Koçyiğit

PMC · DOI: 10.3390/polym17202767 · Polymers · 2025-10-16

## TL;DR

This study explores how adding graphene affects the structure and properties of a specific nanomaterial made using a sol–gel method.

## Contribution

The paper introduces a multi-technique analysis of graphene-modified Ca2.95Eu0.05Co4Ox nanomaterials, revealing how graphene influences phase formation and microstructure.

## Key findings

- Graphene incorporation preserves primary phases and introduces a distinct graphene reflection in XRD.
- Graphene loading increases grain refinement and denser textures at low–moderate contents but causes agglomeration at higher loadings.
- Graphene affects lattice strain, crystallite size, and grain-boundary architecture, offering a basis for optimizing functional performance.

## Abstract

This study employs a multi-technique approach to elucidate how graphene incorporation affects phase formation, microstructure, and thermal behavior in PVA-assisted sol–gel synthesized Ca2.95Eu0.05Co4Ox nanomaterials. XRD confirms the preservation of the primary phases (hexagonal CaCO3 and cubic CoO) alongside a distinct graphene (002) reflection; a systematic low-angle shift of the calcite (104) peak evidences partial relaxation of residual lattice strain with increasing graphene content, while Scherrer analysis indicates tunable crystallite size. Raman spectroscopy corroborates graphene incorporation through pronounced D (~1300 cm−1) and G (~1580 cm−1) bands and supports the XRD-identified phase coexistence via cobalt-oxide and calcite vibrations in the 200–700 cm−1 region, also indicating increased defect/disorder with graphene loading. SEM shows grain refinement, denser/bridged lamellar textures, and reduced porosity at low–moderate graphene contents (1–3 wt.%), contrasted by agglomeration-driven heterogeneity at higher loadings (5–7 wt.%). EDX reveals increasing carbon with Ca/Co redistribution at accessible surfaces, and TG–DSC corroborates the removal of oxygen-containing groups and oxidative combustion of graphene at mid temperatures. Collectively, Raman–XRD-consistent evidence demonstrates that graphene provides a tunable handle over lattice strain, crystallite size, and grain-boundary architecture, establishing a processing–composition basis for optimizing functional (e.g., electrical/thermoelectric) performance.

## Linked entities

- **Chemicals:** PVA (PubChem CID 11199), CaCO3 (PubChem CID 10112), CoO (PubChem CID 14786)

## Full-text entities

- **Chemicals:** Ca (MESH:D002118), Co (MESH:D003035), Graphene (MESH:D006108), CoO (MESH:C041069), cobalt-oxide (MESH:C060728), Ca2.95Eu0.05Co4Ox (-), CaCO3 (MESH:D002119), carbon (MESH:D002244), oxygen (MESH:D010100), PVA (MESH:C063253)

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12567225/full.md

## References

37 references — full list in the complete paper: https://tomesphere.com/paper/PMC12567225/full.md

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Source: https://tomesphere.com/paper/PMC12567225