Controlled inter-state switching between quantized conductance states in resistive devices for multilevel memory

A detailed understanding of quantization conductance (QC), their correlation with resistive switching phenomena and controlled manipulation of quantized states is crucial for realizing atomic-scale multilevel memory elements. Here, we demonstrate highly stable and reproducible quantized conductance states (QC-states) in Al/Niobium oxide/Pt resistive switching devices. Three levels of control over the QC-states, required for multilevel quantized state memories, like, switching ON to different quantized states, switching OFF from quantized states, and controlled inter-state switching among one QC states to another has been demonstrated by imposing limiting conditions of stop-voltage and current compliance. The well defined multiple QC-states along with a working principle for switching among various states show promise for implementation of multilevel memory devices

Controlled inter-state switching between quantized conductance states in resistive devices for multilevel memory

A detailed understanding of quantization conductance (QC), the correlation with resistive switching phenomena and controlled manipulation of quantized states is crucial for realizing atomic-scale multilevel memory elements. Here, we demonstrate highly stable and reproducible quantized conductance states (QC-states) in Al/niobium oxide/Pt resistive switching devices. Three levels of control over the QC-states, required for multilevel quantized state memories, like, switching ON to different quantized states, switching OFF from quantized states, and controlled inter-state switching among one QC state to another has been demonstrated by imposing limiting conditions of stop-voltage and current compliance. The well-defined multiple QC states along with a working principle for switching among various states show promise for implementation of multilevel memory devices

Sustainable approaches for the synthesis of biogenic platinum nanoparticles

Abstract Background The era of nanotechnology become widespread for research and human resource development due to its functionalized tuning with economical, eco-friendly, effective and sustainable end-products. Hence, the present review illustrates the biogenic fabrication of platinum nanoparticles (PtNPs) through the different sustainable and cheaper approaches. Main body of the abstract Over the physicochemical-based nanotechnology, the biogenic active substances-based synthesis displayed the more promising candidature due to its non-toxic, Broad-spectrum applicability and defendable type character. The biogenic synthesis method is capable with and without capping and highly motif of reducing agents. The morphology and stability of synthesized PtNPs are mostly mediated by various experimental conditions such as pH, temperature, incubation time, concentrations of biomaterials and salts or enzymes used. Hence, the review is aiming to discuss the methodology of biogenic synthesis of PtNPs by plant stem, root, leaf, flower, fruit, extracts, algae, fungi and egg yolk. Also, we have illustrated the pharmaceutical drug model application and its adverse effect. Short conclusion Synthesized PtNPs are open a new trend in catalyst, drug and its carrier and in cancer treatment. PtNPs are utilized as a new therapeutic agent for inhibiting the microbial pathogens with non-toxic behavior. The characterization of PtNPs could estimate the bio-sensitized properties which leads the commercial applications