Complex dielectric function and opto-electronic characterization using VEELS for the lead-free BCZT electro-ceramic perovskite

“…By and large, the 5-fold contribution of this work and the associated highlights are summarized as follows: donor-π−A architecture yielding a charge transfer emission at ∼700 nm. v. Futuristic scope and opportunities: From the fluorescence enhancements presented here, in the presence of BCZT NPs on both SPCE and PCCE platform (with and without GO layer), we conclude that BCZT NPs functions as a promising plasmonic material 32,33 by replacing the lossy metal NPs-based surface plasmonsensing platforms. BCZT NPs do not catalyze the breakdown of RhB or other dyes, and when doped with ions, they show dielectric enhanced fluorescence in cavity nanointerface configuration.…”

“…Figure 2a shows that the BCZT sample exhibits broad absorption below 400 nm due to the transition of the carriers from the valence band to the conduction band. 32 The band gap energy of the indirect transition between valence and conduction bands of the BCZT sample was calculated using the Tauc relation:…”

“…Thanks to Herrera-Peŕez and co-workers for the elucidation of the complex dielectric function of the BCZT NP (henceforth abbreviated as nano-BCZT) through valence electron energy loss spectroscopy, in transmission electron microscopy (VEELS−TEM), which assists in technically and theoretically comprehending its utility as a good plasmonic material. 32 Interestingly, nano-BCZT is reported to possess bulk plasmons and surface plasmons at ∼27 and ∼12 eV, respectively, with high real part of refractive index (n = 2.4) and negligible imaginary component. 32 Consequently, these properties make nano-BCZT an ideal ferroelectric material for plasmonic applications as it makes an avenue for successfully exciting the surface plasmon bands under appropriate conditions.…”

“…32 Interestingly, nano-BCZT is reported to possess bulk plasmons and surface plasmons at ∼27 and ∼12 eV, respectively, with high real part of refractive index (n = 2.4) and negligible imaginary component. 32 Consequently, these properties make nano-BCZT an ideal ferroelectric material for plasmonic applications as it makes an avenue for successfully exciting the surface plasmon bands under appropriate conditions. With this as a fundamental motivation, we explored the utility of nano-BCZT for enhancing the fluorescent signal of the molecules situated on metallic thin film (in SPCE) and on 1DPhC (in PCCE), and intriguing observations are documented.…”

Plasmon-Rich BCZT Nanoparticles in the Photonic Crystal-Coupled Emission Platform for Cavity Hotspot-Driven Attomolar Sensing

“…By and large, the 5-fold contribution of this work and the associated highlights are summarized as follows: donor-π−A architecture yielding a charge transfer emission at ∼700 nm. v. Futuristic scope and opportunities: From the fluorescence enhancements presented here, in the presence of BCZT NPs on both SPCE and PCCE platform (with and without GO layer), we conclude that BCZT NPs functions as a promising plasmonic material 32,33 by replacing the lossy metal NPs-based surface plasmonsensing platforms. BCZT NPs do not catalyze the breakdown of RhB or other dyes, and when doped with ions, they show dielectric enhanced fluorescence in cavity nanointerface configuration.…”

“…Figure 2a shows that the BCZT sample exhibits broad absorption below 400 nm due to the transition of the carriers from the valence band to the conduction band. 32 The band gap energy of the indirect transition between valence and conduction bands of the BCZT sample was calculated using the Tauc relation:…”

“…Thanks to Herrera-Peŕez and co-workers for the elucidation of the complex dielectric function of the BCZT NP (henceforth abbreviated as nano-BCZT) through valence electron energy loss spectroscopy, in transmission electron microscopy (VEELS−TEM), which assists in technically and theoretically comprehending its utility as a good plasmonic material. 32 Interestingly, nano-BCZT is reported to possess bulk plasmons and surface plasmons at ∼27 and ∼12 eV, respectively, with high real part of refractive index (n = 2.4) and negligible imaginary component. 32 Consequently, these properties make nano-BCZT an ideal ferroelectric material for plasmonic applications as it makes an avenue for successfully exciting the surface plasmon bands under appropriate conditions.…”

“…32 Interestingly, nano-BCZT is reported to possess bulk plasmons and surface plasmons at ∼27 and ∼12 eV, respectively, with high real part of refractive index (n = 2.4) and negligible imaginary component. 32 Consequently, these properties make nano-BCZT an ideal ferroelectric material for plasmonic applications as it makes an avenue for successfully exciting the surface plasmon bands under appropriate conditions. With this as a fundamental motivation, we explored the utility of nano-BCZT for enhancing the fluorescent signal of the molecules situated on metallic thin film (in SPCE) and on 1DPhC (in PCCE), and intriguing observations are documented.…”

Plasmon-Rich BCZT Nanoparticles in the Photonic Crystal-Coupled Emission Platform for Cavity Hotspot-Driven Attomolar Sensing

“…The energy range of ~10-30 eV is dominated by the plasmon peaks. More structures could be observed above 30 eV, and they are attributed to the elemental composition (threes vertical dashed lines) [3]. Panel (b) reveals the core loss EELS structure, identifying also the elemental analysis.…”

Multiplet Structure for the Perovskite Vanadium-doped BCZT using EELS

Complex dielectric function, Cole-Cole, and optical properties evaluation in BiMnO3 thin-films by Valence Electron Energy Loss Spectrometry (VEELS) analysis