Table 1.
Overview of research studies applying a mechanochemical approach for the treatment of eggshell waste published recently: experimental techniques, the most important result and application field of the final product.
| Milling input | Experimental techniques | Most important results | Final product/application | References |
|---|---|---|---|---|
| Eggshell | SEM | Statistical approach; milling speed is the most important factor | Hydroxyapatite/bioceramics | (van Hoten et al., 2018) |
| Eggshell + ethanol/water | XRD, SEM, TEM, TA, optical microscopy, mechanical properties evaluation, biocompatibility | 5 wt% nanohydroxyapatite was the ebst, cells grow on the fibers | PLA-nanohydroxyapatite fibers/bioengineering | (Apalangya et al., 2019) |
| Eggshell + window parapet made of PVC | XRD, FTIR, titration | Comparison of planetary and vibratory milling, scalability | Calcium chloride + harmless organic matrix/dechlorination | (Baláž et al., 2019a) |
| Eggshell + TiO2/+ Mg | XRD, TA, SEM | Comparison of conventional and high-energy ball milling | CaTiO3 ceramics/electronics | (Cherdchom et al., 2019) |
| Eggshell/cuttlefish bone+ phosphoric acid | SEM, XRD, Raman, TEM | No sintering, comparison of eggshell and cuttlefish bone as Ca sources | Hydroxyapatite/bioceramics | (Ferro and Guedes, 2019) |
| Eggshell + rice straw | XRD, SEM, adsorption kinetics and thermodynamics and influence of various factors | Maximum sorption capacity of 231 mg/g was evidenced for balanced eggshell:rice straw ratio | Phosphate ions adsorbent/wastewater treatment | (Liu et al., 2019) |
| Eggshell + acetone | XRD, SEM | Sintering enriched Ca content and did not result in a significant increase in crystallite size | Nanoization | (Puspitasari et al., 2019) |
| CaO from eggshell | XRD, FTIR, SEM, fluorescent microscopy, biocompatibility evaluation | Comparison of ball milling, mortar and pestle and Food and Drug Administration (FDA)-approved methodology, post-milling reaction with H3PO4 | β-tricalcium phosphate scaffolds/bioceramics | (Roopavath et al., 2019) |
| CaO from eggshell | XRD, SEM, chemical oxygen demand, biogas and methane production | Size reduction into nano-range resulted in a significant improvement in biogas production | Biogas production from palm oil mill effluent: cow manure mixture | (Sari et al., 2020) |
| Eggshell + ethanol | XRD, FTIR, SEM, WCA, SPM | Stearic acid favors the transformation into aragonite | Superhydrophobic eggshell/filtration | (Seeharaj et al., 2019) |
| Eggshell + Li-Ni0.8Co0.1Mn0.1O2 | TA, XRD, FTIR, SEM/EDS, XPS, electrochemical measurements | CaO prevents electrolyte dissolution and electrode corrosion | CaO-coated Li-Ni0.8Co0.1Mn0.1O2 electrode/electrochemistry | (Senthil et al., 2019) |
| Eggshell + acetone | XRD, SEM, FTIR | Comparison of calcined (CaO) and non/calcined (CaCO3) material | Nanoization | (Supriyanto et al., 2019) |
| Eggshell + stearic acid/water | XRD, TA, TEM | Stearic acid reduces the crystallite size and thermal degradation temperature | Nanoization | (Villarreal-Lucio et al., 2019) |
| Eggshell + aqueous solution of phosphate precursor | XRD, FTIR, SEM, TA | Pure HA produced from different precursors using three different CaCO3 sources using wet milling and low-temperature treatment | Hydroxyapatite/bioceramics | (Cestari et al., 2020) |
| Eggshell + ethanol | SBET, particle size distribution, zeta potential, SEM, TEM, EDS, FTIR, Ca2+ concentration determination, XRD | Zeta potential was decreased during treatment | Nanoization | (Huang et al., 2020) |
| Eggshell membrane + Li2FeSiO4 | XRD, TA, SBET, Raman, XPS, TEM | ESM served as a carbon source for improving electrical properties of the LFS ESM composite | LFS-C composite/electrochemistry | (Karuppiah et al., 2020) |
| Eggshell + Al2O3 | SEM, mechanical properties, corrosion, thermal expansion | Toughness and ductility reduced, but tensile strength, hardness, corrosion resistance, thermal stability improved upon addition of CaO derived from eggshell | Al/eggshell/Al2O3 composite | (Kumar, S., Dwivedi, S. P., and Dwivedi et al., 2020) |
| Eggshell | Particle size distribution, SEM, EDX, XRD | The authors report graphite in the eggshell | Micronization | (Ononiwu and Akinlabi, 2020) |
| Eggshell/eggshell + TiO2 | FTIR, TEM, XRD, acid-resistant and buffering properties | The buffering performance was evaluated against that of four available toothpastes | Eggshell-TiO2 composite/dentistry | (Onwubu et al., 2019a) |
| Eggshell/eggshell + TiO2 | The same as above, but also SEM | The tooth surface is less destroyed when using Colgate toothpaste and the prepared composite in comparison with other toothpastes | Eggshell-TiO2 composite/dentistry | (Onwubu et al., 2019b) |
| Eggshell | XRD, SEM, TEM, FTIR, mechanical properties, microhardness, erosion resistance | Different amounts of eggshell (from 1-4%) in the composites were beneficial for different mechanical properties | Eggshell-epoxy composite/composites | (Panchal et al., 2020) |
| Eggshell + acetone | XRD, FTIR, Raman, SEM | Effect of various post-milling sintering temperatures (900–1,200°C) on CaCO3-CaO transformation was investigated | Nanoization | (Puspitasari et al., 2020) |
| Eggshell | Particle size, SEM, XRD, AFM, mechanical properties, chloride ion permeability | Improvement of mechanical properties of oil well cement and accelerate hydration process | Oil well cement-eggshell composite | (Salman et al., 2020) |