Bridging Materials Science, Technology, and Sustainability

My research integrates Physics, Materials Engineering, and Artificial Intelligence to design advanced materials and technologies that address critical challenges in healthcare, energy, and environmental sustainability. Below is an overview of my core research themes and methodologies:

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Core Research Areas

1. Advanced Materials Development

   • Multifunctional Ceramics & Oxides: Synthesis and characterization of ferroelectric, magnetic, and multiferroic materials for microelectronics, energy harvesting, and sensor technologies.

   • Magnetic Nanoparticles: Engineering nanoparticles for biomedical applications, including targeted cancer therapies (e.g., magnetic hyperthermia) and advanced diagnostic tools.

   • Sustainable Energy Solutions: Designing zero-carbon smart energy systems through innovative materials for energy storage, conversion, and environmental remediation.

2. Interdisciplinary Applications

   • Biomedical Innovations: Developing magnetic nanoparticle-based platforms for cancer treatment, drug delivery, and non-invasive diagnostics.

   • Environmental Technologies: Creating materials for pollution control, water purification, and sustainable resource management.

1. • AI-Driven Materials Discovery: Leveraging machine learning (ML), artificial neural networks (ANNs), and artificial intelligence (AI) to predict material properties, optimize synthesis processes, and accelerate device design.

2. Foundational Science

   • Exploring structure-property relationships in complex oxides and ceramics to unlock novel functionalities.

   • Investigating magnetoelectric and magnetodielectric coupling in multiferroics for next-generation microelectronic and spintronic devices.

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Experimental & Computational Techniques

My work combines cutting-edge experimental methods with computational modeling to achieve precision and innovation:

Synthesis & Fabrication

• High-energy ball milling for nanostructured material production.

• Sol-gel and hydrothermal synthesis of ceramics, oxides, and nanoparticles.

Advanced Characterization

• Structural Analysis: X-ray diffraction (XRD), neutron diffraction, and Rietveld refinement for atomic-level structural resolution.

• Microscopy & Spectroscopy: Scanning/transmission electron microscopy (SEM/TEM), energy-dispersive X-ray spectroscopy (EDS), and spectroscopic techniques.

• Functional Properties:

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  • Dielectric, ferroelectric, and piezoelectric measurements.

  • Magnetic characterization (VSM, SQUID) and magnetoelectric coupling studies.

  • Hyperthermia experiments for evaluating nanoparticle heating efficiency.

Computational Tools

• Machine learning models for property prediction and materials optimization.

• Artificial neural networks to simulate complex material behaviors and device performance.

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Collaborations & Impact

My research thrives on interdisciplinary collaboration, partnering with institutions worldwide to translate scientific discovery into real-world solutions. Recent projects include:

• Designing multiferroic devices for low-energy microelectronics.

• Developing magnetic hyperthermia platforms for non-invasive cancer therapy.

• Pioneering AI-driven workflows to reduce experimental trial-and-error in materials development.

By merging fundamental science with applied innovation, I aim to create sustainable technologies that benefit society while advancing the frontiers of materials research.

Let’s collaborate! Explore opportunities to partner on projects in materials science, biomedical engineering, or AI-driven research by [contacting me here].

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