Surface-Ligand-Controlled Enhancement of Carrier Density in Plasmonic Tungsten Oxide Nanocrystals: Spectroscopic Observation of Trap-State Passivation via Multidentate Metal Phosphonate Bonding

Abstract: The localized surface plasmon resonance (LSPR) properties of nanocrystals (NCs) allow manipulation of optical responses by controlling their morphology, free carrier density, and local dielectric environment. In this context, semiconductor NCs, in which plasmonic properties arise due to various types of doping, provide unique opportunities in tailoring LSPR properties for a wide range of applications as viable alternatives to expensive noble metal NCs. Although extensive works have been done to control the LSP… Show more

“…32,33 We showed that TD-PA is a unique surface passivating ligand that not only increased the passivation sites per ligand compared to alkylcarboxylate ligands allowing greater passivation of undercoordinated near-neighbor tungsten atoms in highly deficient WO 3−x NPLs but also substantially improved the LSPR properties of colloidal WO 3−x NPLs. 30 Our selected ligands, Ethyl-PA, Phenyl-PA, and NO 2 -BA provide a wide variety of structural diversity such as length of the alkyl chain, conjugation, and electron-withdrawing substitution. Colloidal synthesis and ligand exchange of WO ) and carboxylate (−CO 2 − ) binding head groups (i.e., TD-PA and MA); (2) ligands with different backbones but an identical, −PO 3 2− binding head group (i.e., TD-PA, Phenyl-PA, and Ethyl-PA); and (3) ligands with aromatic πconjugation but two different binding head groups (i.e., NO 2 -BA and Phenyl-PA).…”

“…The lateral dimensions of NPLs are determined to be ∼14 and 4.7 nm in length and width, respectively (Figure 1B,C). Based on our recent work, 30 we do not anticipate any morphological changes in the NPL during the ligand treatment. We used purified samples to prepare thin films.…”

“…) binding head group containing ligands compared to bidentate binding carboxylate (−CO 2 − ) ligands. 30 Therefore, tridentate phosphonate-tungsten bonding provides stronger interactions than bidentate carboxylate-tungsten bonding. The increased surface passivation and stronger electronic interactions of phosphonate ligands stabilize surface W and prevent the transfer of the conduction band electrons to trap sites, thus increasing the free carrier density.…”

“…Furthermore, appropriate surface-ligand engineering provided additional means to increase free electron concentration (8.4 × 10 22 cm −3 ) and thus pushed the LSPR wavelength toward the visible region. 30 Together, ligand-induced alteration of free electrons in WO 3−x NCs is controlled by the interfacial chemical interaction between inorganic NC and organic ligands. In this context, the polarizability of the metal−ligand bond should govern the optoelectronic and dielectric properties of ligand-passivated WO 3−x NCs.…”

“…The LSPR wavelength of these NPLs can be tuned between 1200 and 1600 nm by controlling the oxygen deficiency, where a free electron concentration of 4.13 × 10 22 cm –3 provided an LSPR peak position of ∼1200 nm. Furthermore, appropriate surface-ligand engineering provided additional means to increase free electron concentration (8.4 × 10 22 cm –3 ) and thus pushed the LSPR wavelength toward the visible region . Together, ligand-induced alteration of free electrons in WO 3– x NCs is controlled by the interfacial chemical interaction between inorganic NC and organic ligands.…”

Inorganic–Organic Interfacial Electronic Effects in Ligand-Passivated WO_3–x Nanoplatelets Induce Tunable Plasmonic Properties for Smart Windows

“…32,33 We showed that TD-PA is a unique surface passivating ligand that not only increased the passivation sites per ligand compared to alkylcarboxylate ligands allowing greater passivation of undercoordinated near-neighbor tungsten atoms in highly deficient WO 3−x NPLs but also substantially improved the LSPR properties of colloidal WO 3−x NPLs. 30 Our selected ligands, Ethyl-PA, Phenyl-PA, and NO 2 -BA provide a wide variety of structural diversity such as length of the alkyl chain, conjugation, and electron-withdrawing substitution. Colloidal synthesis and ligand exchange of WO ) and carboxylate (−CO 2 − ) binding head groups (i.e., TD-PA and MA); (2) ligands with different backbones but an identical, −PO 3 2− binding head group (i.e., TD-PA, Phenyl-PA, and Ethyl-PA); and (3) ligands with aromatic πconjugation but two different binding head groups (i.e., NO 2 -BA and Phenyl-PA).…”

“…The lateral dimensions of NPLs are determined to be ∼14 and 4.7 nm in length and width, respectively (Figure 1B,C). Based on our recent work, 30 we do not anticipate any morphological changes in the NPL during the ligand treatment. We used purified samples to prepare thin films.…”

“…) binding head group containing ligands compared to bidentate binding carboxylate (−CO 2 − ) ligands. 30 Therefore, tridentate phosphonate-tungsten bonding provides stronger interactions than bidentate carboxylate-tungsten bonding. The increased surface passivation and stronger electronic interactions of phosphonate ligands stabilize surface W and prevent the transfer of the conduction band electrons to trap sites, thus increasing the free carrier density.…”

“…Furthermore, appropriate surface-ligand engineering provided additional means to increase free electron concentration (8.4 × 10 22 cm −3 ) and thus pushed the LSPR wavelength toward the visible region. 30 Together, ligand-induced alteration of free electrons in WO 3−x NCs is controlled by the interfacial chemical interaction between inorganic NC and organic ligands. In this context, the polarizability of the metal−ligand bond should govern the optoelectronic and dielectric properties of ligand-passivated WO 3−x NCs.…”

“…The LSPR wavelength of these NPLs can be tuned between 1200 and 1600 nm by controlling the oxygen deficiency, where a free electron concentration of 4.13 × 10 22 cm –3 provided an LSPR peak position of ∼1200 nm. Furthermore, appropriate surface-ligand engineering provided additional means to increase free electron concentration (8.4 × 10 22 cm –3 ) and thus pushed the LSPR wavelength toward the visible region . Together, ligand-induced alteration of free electrons in WO 3– x NCs is controlled by the interfacial chemical interaction between inorganic NC and organic ligands.…”

Inorganic–Organic Interfacial Electronic Effects in Ligand-Passivated WO_3–x Nanoplatelets Induce Tunable Plasmonic Properties for Smart Windows

Observing Metallic Carriers in Highly Faceted Plasmonic Cd₂SnO₄ Inverse Spinel Nanocrystals

Controllable synthesis of Sn0.33WO3 tungsten bronze nanocrystals and its application for upconversion luminescence enhancement