Exploiting the photosensitive property of BiFeO 3 thin films, we demonstrated a resistive switching memory cell having low V set voltage (þ2.0 V), an ultrahigh ON/OFF ratio of $10 7 and a good retention time of more than 10 6 s. Synthesis conditions were optimized during a sol-gel-assisted spin-coating method to get phase-pure BiFeO 3 films on Al substrate, at room temperature. Current-voltage analysis revealed that during optical illumination, photon-induced charge carriers migrate towards their respective electrodes along grain boundaries under an externally applied field, which initiate a substantial shift in the normal V set of þ10.4 V to a lower voltage (þ2.0 V). The Poole-Frenkel emission at the metal/BiFeO 3 interface is proposed and the role of electronic reconstruction at the interface is further investigated. Thus the write process in BiFeO 3 -based resistive-switching devices can be modulated in a controlled manner, which has the potential for integrating current resistive switching (memristive) memory device technology towards exciting optomemristive device technology. 1 Introduction The concept of altering the resistance of metal oxide thin film under external electrical stress opened a new remarkable research area attractive for nextgeneration nonvolatile memories with scenarios including very high-density integration and multistate logic implementation [1][2][3][4]. Among the nonvolatile memories considered till now, the resistive random access memory (ReRAM), employ reversible resistive switching (RS) behavior, is increasingly important due to its simple structure, long retention time, small size, and fast switching speed [5,6]. The simplicity of the geometrical structures (metal/meal oxide/metal) makes the resistance switching extremely attractive and promising.Many transition-metal oxide (TMO) materials possess the RS behavior and among them perovskite materials also show excellent RS [5,7]. Recently, this phenomenon has also been found in BiFeO 3 (BFO) films [8][9][10]. Usually, BFO is an extensively studied multiferroic material, which exhibits ferroelectric and ferromagnetic behaviors simultaneously [11]. As to this, BFO has been widely studied since it exhibits a high Curie temperature (T c % 1100 K), a high N eel temperature (T N % 643 K) and a large remnant polarization over 90 mC cm
The advent of nano‐biotechnology has inspired the interface interaction study between engineered nanoparticles (NPs) and biomolecules. The interaction between Fe content titanium dioxide (TiO2) NPs and adenosine triphosphate (ATP) biomolecules has been envisioned. The effect of Fe content in TiO2 matrix was studied using X‐ray diffraction (XRD) and transmission electron microscopy (TEM). The increase in Fe content caused a decrease in particle size with change in morphology from spherical to one‐dimensional rod structure. The Fe incorporation in the TiO2 matrix reduced the transition temperature from anatase to rutile (A‐R) phase along with formation of haematite phase of iron oxide at 400°C. The interaction of Fe content TiO2 NPs with ATP molecule has been studied using spectroscopic method of Raman scattering and infrared vibration spectrum along with TEM. Fe content in TiO2 has enhanced the interaction efficiency of the NPs with ATP biomolecules. Raman spectroscopy confirms that the NPs interact strongly with nitrogen (N7) site in the adenine ring of ATP biomolecule. Engineering of Fe content TiO2 NP could successfully tune the coordination between metal oxide NPs with biomolecules, which could help in designing devices for biomedical applications.
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