Ni-Doped SnO₂ Nanoparticles for Sensing and Photocatalysis

Abstract: Ni-doped SnO2 nanoparticles were synthesized by a coprecipitation route and showed superior properties for a series of different applications. The 1 atom % Ni-doped SnO2 NPs exhibited excellent electrochemical performance as supercapacitors to deliver a specific capacitance of 793 F g–1 at an applied current density of 2.5 A g–1 in a KOH electrolyte while retaining its capacitance over 1250 cycles. The energy-dependent (100, 150, and 200 μJ) nonlinear absorption behavior of the Ni-doped SnO2 NPs was investigat… Show more

“…Additionally, the two peaks at 660 and 535 cm −1 can be ascribed to the stretching vibrations of Sn–O bonds. 58 All these results are in good consistent with the above results and analyses.…”

Experimental and theoretical investigation of the tuning of electronic structure in SnO₂viaCo doping for enhanced styrene epoxidation catalysis

“…Additionally, the two peaks at 660 and 535 cm −1 can be ascribed to the stretching vibrations of Sn–O bonds. 58 All these results are in good consistent with the above results and analyses.…”

Experimental and theoretical investigation of the tuning of electronic structure in SnO₂viaCo doping for enhanced styrene epoxidation catalysis

“…The high-resolution O 1s spectra of all four nanomaterials can be deconvoluted into three peaks with binding energies of 530.2, 530.7, and 531.7 eV for SnO; 529.3, 530.4, and 531.6 eV for SnNi; 531.3, 531.8, and 532.6 eV for SnCn; and 529.4, 531, and 533 eV for SnNiCn. 21 The C 1s spectra of the prepared SnCn and SnNiCn samples could be deconvoluted into different peaks, i.e. , 284.7, 285.1, and 286.4 eV; and 282.6, 283.7, 284.9, and 286.2 eV, respectively.…”

“…For the undoped SnO 2 sample (pristine SnO 2 ), typical modes positioned at A 1g ¼ 626 cm À1 and B 2g ¼ 774 cm À1 were detected, which indicate the expansion and contraction of the Sn-O bond. 21 In the case of Ni-doped SnO 2 , the A 1g peak shied to 635 cm À1 and the B 2g peak shied to 884 cm À1 with a decrease in the peak intensity due to Ni 2+ doping. The above phenomena provide powerful evidence of the incorporation of nickel into the SnO 2 cassiterite lattice.…”

“…20 The 3d transition metals (Cu, Ni, Co, and Mn) can enable highly reversible conversion reactions when added to SnO 2 nanomaterials. 16,21,22 The added TM can be useful for inducing oxygen vacancies in SnO 2 in the lithiated electrode, resulting in an increased coulombic efficiency of more than 83%. Previous results have demonstrated the advantage of incorporating transition metals into SnO 2 to overcome reversibility problems.…”

A nanostructured SnO₂/Ni/CNT composite as an anode for Li ion batteries

“…Moreover, Figure S2 , Supporting Information shows the increase in the relative intensity peaks of nickel-doped samples, implying the incorporation of Ni + into the SnO 2 lattice. 28 , 29 …”

Ni-Doped SnO₂ as an Electron Transport Layer by a Low-Temperature Process in Planar Perovskite Solar Cells