Nanosilver-loaded PMMA bone cement (BC-AgNp) is a novel cement developed as a replacement for conventional cements. Despite favorable properties and antibacterial activity, BC-AgNp still lacks biodegradability and bioactivity. Hence, we...
Ammonium metavanadate, NH4VO3, plays an important role in the preparation of vanadium oxides and other ammonium compounds, such as NH4V3O8, (NH4)2V3O8, and NH4V4O10, which were found to possess interesting electrochemical properties. In this work, a new route for the synthesis of NH4VO3 is proposed by mixing an organic ammonium salt and V2O5 in a suitable solvent. The one-step procedure is carried out at room temperature. Additionally, the need for pH control and use of oxidants necessary in known methods is eliminated. The mechanism of the NH4VO3 formation is explained. It is presented that it is possible to tailor the morphology and size of the obtained NH4VO3 crystals, depending on the combination of reagents. Nano- and microcrystals of NH4VO3 are obtained and used as precursors in the hydrothermal synthesis of higher ammonium vanadates. It is proven that the size of the precursor particles can significantly affect the physical and chemical properties of the resulting products.
Novel carbon nanomaterials such as
reduced graphene oxide (rGO)
and graphene oxide (GO) can be easily incorporated into the undergraduate
curriculum to discuss basic chemistry and nanotechnology concepts.
This paper describes a laboratory experiment designed to study the
differences between GO and rGO regarding their physicochemical properties
(e.g., color, hydrophobicity, type of functional groups, electrical
conductivity, etc.). In this course, students carry out the chemical
reduction of GO using ascorbic acid, a mild and environmentally friendly
reducing agent. The differences between GO and rGO can be spotted
by the naked eye and can be further evaluated by spectroscopic methods,
as Fourier transform infrared and UV–vis spectroscopy and X-ray
diffraction. Simple and applicable in all laboratories, use of the
multimeter to measure resistance was proposed to reveal the different
electrical properties of GO and rGO. Moreover, the proposed laboratory
experiment is an ideal pretext to discuss the definition of graphene
in the context of the overuse of this term in the literature.
Potassium hexavanadate (K2V6O16·nH2O) nanobelts have been synthesized by the LPE-IonEx method, which is dedicated to synthesis of transition metal oxide bronzes with controlled morphology and structure. The electrochemical performance of K2V6O16·nH2O as a cathode material for lithium-ion batteries has been evaluated. The KVO nanobelts demonstrated a high discharge capacity of 260 mAh g−1, and long-term cyclic stability up to 100 cycles at 1 A g−1. The effect of the vanadium valence state and unusual construction of the nanobelts, composed of crystalline and amorphous domains arranged alternately were also discussed in this work. The ex-situ measurements of discharged electrode materials by XRD, MP-AES, XAS and XPS show that during the subsequent charge/discharge cycle the potassium in the K2V6O16·nH2O structure are replacing by lithium. The structural stability of the potassium hexavandate during cycling depends on the initial vanadium valence state on the sample surface and the presence of the “fringe free” domains in the K2V6O16·nH2O nanobelts.
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