Stabilization of Nickel-Doped Iron-oxy-hydroxide Core in Water by Heptamolybdate Ions to Improve the Electrochemical Oxygen Evolution Reaction

Abstract: Heterometal-doped nickel-oxy-hydroxides or high-entropy multimetallic oxides show notable electrocatalytic activity. Herein, a readily available Anderson-type polyoxometalate (POM) anion, heptamolybdate ([Mo 7 O 24 ] 6− ), is taken as an inorganic ligand to stabilize the nickel(II)-doped iron-oxy-hydroxide nanocore. [Mo 7 O 24 ] 6−ligated Ni x Fe 1−x O(OH) nanomaterials with different ratios of Ni(II) and Fe(III) in the core (1−3) are prepared via a hydrothermal route. ICP−MS and the subsequent PXRD study of t… Show more

“…The binding energy values and the spin–orbit coupling constant (Δ3d) of 8.4 eV confirmed the Sn IV valence state, consistent for SnO 2 . The core-level Mo 3d envelop was broad but could be deconvoluted into two binding energy maxima at 235.22 and 232.2 eV corroborating the Mo 3d 3/2 and Mo 3d 5/2 spin–orbit components (Figure g), which supports the Mo VI of the Mo x cluster present in the material. , The core-level O 1s XP spectrum depicted that the envelope with a dominant maximum at 530.8 eV corresponds to the O 2– of SnO 2 core and POMs (Figure S11b). However, a small, albeit broad hump observed at 531.3 eV can be interpreted as the dominant O-vacancy sites of the SnO 2 core , that was further proved by X-ray absorption, electron paramagnetic resonance, and Raman spectroscopic studies.…”

“…Under a similar electrochemical condition, free [Mo 7 O 24 ] 6– exhibits the irreversible Mo VI/V redox response at −0.74 V (vs Ag/AgCl) (Figure S15c). , Approximately 140 mV anodic shift of the Mo VI/V redox peak for Mo x @SnO 2 , compared to the free POM, inferred coordination of POM to the SnO 2 core through [MoO] terminals, which makes the Mo centers more electropositive. The ESI-MS study with the material, after treating with TBABr followed by dispersing in CH 3 CN, confirmed identified ion peaks at m / z = 1378.56, 1498.59, 1877.89, 2178.67, and 2400.50 amu, which are well attributed to the molecular ions [(TBA)­(H) 5 (K)­(Mo 7 O 24 )] + , [(TBA)­(Mo 7 O 24 )] + , [(TBA) 5 (H)­(K) 3 (Na) 2 (Mo 7 O 24 )­(K)­2] + , [(TBA) 4 (H)­(K)­(Na)­(Mo 7 O 24 )] + , and [(TBA) 3 (H) 4 (Mo 7 O 24 )] + , respectively (Figure S16), confirming the presence of [Mo 7 O 24 ] 6– Mo x @SnO 2 .…”

“…In this context, the covalent linkage of the stabilizing ligand to the nanoparticle’s surface without affecting the reactivity would be desirable . Anderson-type polyoxomolybdate (NH 4 ) 6 [Mo 7 O 24 ] (POM) has recently been shown as an effective inorganic ligand to stabilize γ-FeO­(OH) and Ni x Fe 1– x O­(OH) quantum dot-sized nanoparticles, highly dispersed in water , The molybdenum POM clusters were covalently linked to the surface of the oxy-hydroxide nanocore to preserve its quantum confinement, and POMs did not block the activity of the nanocore during electrocatalytic oxygen evolution reaction (OER). , …”

Vacancy-Rich SnO₂ Quantum Dot Stabilized by Polyoxomolybdate as Electrocatalyst for Selective NH₃ Production

“…The binding energy values and the spin–orbit coupling constant (Δ3d) of 8.4 eV confirmed the Sn IV valence state, consistent for SnO 2 . The core-level Mo 3d envelop was broad but could be deconvoluted into two binding energy maxima at 235.22 and 232.2 eV corroborating the Mo 3d 3/2 and Mo 3d 5/2 spin–orbit components (Figure g), which supports the Mo VI of the Mo x cluster present in the material. , The core-level O 1s XP spectrum depicted that the envelope with a dominant maximum at 530.8 eV corresponds to the O 2– of SnO 2 core and POMs (Figure S11b). However, a small, albeit broad hump observed at 531.3 eV can be interpreted as the dominant O-vacancy sites of the SnO 2 core , that was further proved by X-ray absorption, electron paramagnetic resonance, and Raman spectroscopic studies.…”

“…Under a similar electrochemical condition, free [Mo 7 O 24 ] 6– exhibits the irreversible Mo VI/V redox response at −0.74 V (vs Ag/AgCl) (Figure S15c). , Approximately 140 mV anodic shift of the Mo VI/V redox peak for Mo x @SnO 2 , compared to the free POM, inferred coordination of POM to the SnO 2 core through [MoO] terminals, which makes the Mo centers more electropositive. The ESI-MS study with the material, after treating with TBABr followed by dispersing in CH 3 CN, confirmed identified ion peaks at m / z = 1378.56, 1498.59, 1877.89, 2178.67, and 2400.50 amu, which are well attributed to the molecular ions [(TBA)­(H) 5 (K)­(Mo 7 O 24 )] + , [(TBA)­(Mo 7 O 24 )] + , [(TBA) 5 (H)­(K) 3 (Na) 2 (Mo 7 O 24 )­(K)­2] + , [(TBA) 4 (H)­(K)­(Na)­(Mo 7 O 24 )] + , and [(TBA) 3 (H) 4 (Mo 7 O 24 )] + , respectively (Figure S16), confirming the presence of [Mo 7 O 24 ] 6– Mo x @SnO 2 .…”

“…In this context, the covalent linkage of the stabilizing ligand to the nanoparticle’s surface without affecting the reactivity would be desirable . Anderson-type polyoxomolybdate (NH 4 ) 6 [Mo 7 O 24 ] (POM) has recently been shown as an effective inorganic ligand to stabilize γ-FeO­(OH) and Ni x Fe 1– x O­(OH) quantum dot-sized nanoparticles, highly dispersed in water , The molybdenum POM clusters were covalently linked to the surface of the oxy-hydroxide nanocore to preserve its quantum confinement, and POMs did not block the activity of the nanocore during electrocatalytic oxygen evolution reaction (OER). , …”

Vacancy-Rich SnO₂ Quantum Dot Stabilized by Polyoxomolybdate as Electrocatalyst for Selective NH₃ Production

“…A higher Mn percentage indicates that during the synthesis all the Bi(NO 3 ) 3 precursor was present in the reaction in excess and Mn II was doped in the Bi 3 O 4 Br bulk lattice. 49…”

Evolution of Mn–Bi₂O₃ from the Mn-doped Bi₃O₄Br electro(pre)catalyst during the oxygen evolution reaction

“…A fantastic display of enhanced chemical as well as physical property (viz., activity) is observed for double perovskites where B-sites are tuned with alternate B and B′ cations owing to the coupling effect by intervening oxygen bridging in every B- and B′-sites. In addition, for metal-based catalysts, metal oxo-hydroxides (formed in situ from metal hydroxides or oxides) − are regarded as the active species, the formation of which gets impeded due to the formation of several M–M bonds . Thus, for the promotional effect in the OER activity of double perovskites, a strategy to accelerate the formation of active species (suppressing the M–M bonds) and optimize the e g electronic state, at the same time, is highly anticipated.…”

Enhancing Trifunctional Electrocatalytic Activities via Lanthanide Modulation in Fe–Co-Based Double Perovskite Oxides