Low-dimensional lead chromate-based hybrid system for capacitance and polarization performances: a flexible device for pressure-induced voltage generator
Sarit K. Ghosh, Harishchandra Singh, Kaushik Mallick
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引用次数: 0
Abstract
Abstract Organic molecule–functionalized lead chromate nanoparticle was synthesized using a complexation strategy route. The structural characterization revealed the single-phase lead chromate system belongs to monazite-type monoclinic structure with the space group of P2 1 /n. The unit cell consists of an alternating chain of polyhedra (PbO 9 ) and tetrahedra (CrO 4 ) units, connected via edge and corner-sharing arrangement. A flexible device of lead chromate was fabricated and investigated dielectric capacitance, electrical impedance, conductivity, and field dependent polarization performances under different frequency and temperature environments. The device displayed a maximum dielectric constant ( ε ʹ) value ~ 2400 at 120°C under 100 Hz frequency condition. High dielectric constant value is originated from the orientation polarization of CrO 4 unit and space charge contribution in the system. AC conductivity of the device suggested the polaronic charge carriers control the overall conduction process via localized hopping mechanism. A fatigue-free polarization behavior was observed in the device under the applied field of 4.0 kV/mm, for 10 3 cycles and retained the polarization value ~ 0.26 μC/cm 2 over the switching cycles. Lead chromate–based device also showed pressure-induced voltage generation under different pressure conditions and could have the potential application as a voltage generator.
期刊介绍:
Emergent Materials is a multidisciplinary peer-reviewed journal, which publishes reviews, mini reviews, communications, progress reports, research news and original research articles at the forefront of physics, chemistry, biology, and engineering of advanced materials. Submissions will cover a wide range of articles, reviews and communications from the design and preparation of emerging materials to cutting edge applications.Emergent Materials aims to publish a series of high quality and high impact research articles that reflect and bring the best Research, at the forefront of physics, chemistry, biology, and engineering of advanced materials to the international research community. All manuscripts will be subjected to a preliminary review prior to the full reviewing process in order to evaluate their suitability for publication.Emergent Materials publishes articles that focus on but are not limited to, a variety of topics such as:• Design, synthesis, and characterization of advanced materials• Hierarchical materials• Self-assembly of materials• Polymers and composites• Coatings and membranes• Green and sustainable materials• Micro, meso and nanoporous materials• Nanostructures, nanocomposites and thin film• Carbon-based materials and applications• Renewable energy/Environment materials• Novel optical materials• Biomaterials• Catalysis• Surface Science and Engineering• Functional materials• Alloys design, synthesis, and applications• Nano-devices