Abstract
Achieving nanostructures with high surface area is one of the most challenging tasks as this metric usually plays a key role in technological applications, such as energy storage, gas sensing or photocatalysis, fields in which NiO is gaining increasing attention recently. Furthermore, the advent of modern NiO-based devices can take advantage of a deeper knowledge of the doping process in NiO, and the fabrication of p-n heterojunctions. By controlling experimental conditions such as dopant concentration, reaction time, temperature or pH, NiO morphology and doping mechanisms can be modulated. In this work, undoped and Sn doped nanoparticles and NiO/SnO2 nanostructures with high surface areas were obtained as a result of Sn incorporation. We demonstrate that Sn incorporation leads to the formation of nanosticks morphology, not previously observed for undoped NiO, promoting p-n heterostructures. Consequently, a surface area value around 340 m2/g was obtained for NiO nanoparticles with 4.7 at.% of Sn, which is nearly nine times higher than that of undoped NiO. The presence of Sn with different oxidation states and variable Ni3+/Ni2+ ratio as a function of the Sn content were also verified by XPS, suggesting a combination of two charge compensation mechanisms (electronic and ionic) for the substitution of Ni2+ by Sn4+. These results make Sn doped NiO nanostructures a potential candidate for a high number of technological applications, in which implementations can be achieved in the form of NiO–SnO2 p-n heterostructures.
Highlights
In the last few years, nickel oxide (NiO) has been extensively studied due to its interesting optoelectronic and magnetic properties, and its high thermal and chemical stability [1], which make it a promising candidate for numerous technological applications such as electrochromic devices [2], supercapacitors [3], photocatalyst [4,5] or gas sensors [6,7], among others
Several publications related to Sn doped NiO nanostructures can be found in the literature, less has been done in the study of the fundamental properties of this oxide
Most of the works related to Sn doped NiO are focused on the effect of Sn incorporation in technological applications, such as gas sensors or photocatalyst, assuming that Sn is mainly incorporated as Sn4+
Summary
In the last few years, nickel oxide (NiO) has been extensively studied due to its interesting optoelectronic and magnetic properties, and its high thermal and chemical stability [1], which make it a promising candidate for numerous technological applications such as electrochromic devices [2], supercapacitors [3], photocatalyst [4,5] or gas sensors [6,7], among others. Recent works reported on high surface area values for diverse Sn doped NiO nanostructures synthesized following different routes. Most of the works related to Sn doped NiO are focused on the effect of Sn incorporation in technological applications, such as gas sensors or photocatalyst, assuming that Sn is mainly incorporated as Sn4+. In those works, the Sn concentration never exceeds values around 10 at.%, not exploring the solubility limit of Sn in NiO, one aspect that motivates this study. Diverse complementary characterization techniques were used in the investigation of all the samples, such as X-ray diffraction (XRD), scanning and transmission electron microscopy (SEM and TEM), Raman spectroscopy, cathodoluminescence (CL), N2 adsorption–desorption isotherms and Brunauer–Emmett–Teller (BET) surface, and X-ray photoelectron spectroscopy (XPS)
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