Research & Projects

In the realm of modern chemistry, I've embarked on a journey into the realm of automated chemical synthesis. This cutting-edge approach redefines molecular creation, where precision meets innovation. Automation eliminates errors and accelerates discovery, revolutionizing how we craft molecules. I want to harness automation to design intricate molecular structures, pushing the boundaries of what's achievable. As the future pioneers in this domain, we want to shape a future where automation and chemistry converge, unlocking limitless possibilities. This journey signifies the fusion of creativity with precision, where the canvas of automation paints a new landscape of scientific exploration. 

In the realm of Chemistry, the fusion of science and technology has yielded remarkable outcomes. Guided by the expertise of Dr. Upakarasamy Lourderaj, I delved into the dynamic world of Artificial Neural Networks (ANNs). These intelligent systems emulate human thought processes, offering a unique lens to decipher complex chemical phenomena. By harnessing ANNs, I've navigated intricate data landscapes, extracting patterns and insights that traditional methods may miss. This synergy of Chemistry and machine learning has ignited a new era of discovery, where algorithms unravel secrets hidden within molecular interactions, enriching our understanding of the chemical universe. 

In the captivating realm of Chemistry, my passion converges with technology under the guidance of luminaries like Sir Richard Catlow and Dr. Upakarasamy Lourderaj. Immerse yourself in the world of theoretical and computational chemistry, where equations unveil the secrets of molecular behavior. My journey involves the intricate dance of Density Functional Theory (DFT) calculations and molecular modeling. These tools, honed by Sir Richard Catlow's insights, decipher the quantum intricacies that govern molecular interactions. Guided by Dr. Lourderaj, I navigate virtual landscapes, unraveling molecular mysteries, and shaping the future of chemical discovery at the intersection of theory and computation.

My voyage began with terphenyl-embedded carbaporphyrins—compounds blending porphyrin characteristics with a twist. Guided by Prof. Dr. Srinivasan, I've delved into their synthesis, unveiling unique optical and chemical traits. This project hones my analytical skills while igniting my curiosity for their intricate behavior. Building on this foundation, I delved into N-fused compounds, uncovering structures with distinct optical and electrochemical properties. I am also Intrigued by calixpyrroles, I've focused on understanding their unique binding capacities. These compounds, characterized by sp3 hybridized meso bridges, offer intriguing possibilities in anion sensing and separation. 

In this digital age, chemical sensors have emerged as indispensable tools, seamlessly bridging the gap between innovation and real-world application. Here I delve into the fascinating realm of chemical sensors and their multifaceted applications. As someone deeply passionate about calixarene synthesis and proficient in molecular modeling computational techniques, I aim to explore the intricate world of sensors. This journey will highlight the pivotal role these sensors play in laboratory research, environmental toxin detection, and military warfare for explosives identification. Join me as I unravel the science behind these tiny yet powerful devices that shape the future of detection and analysis.

In the dynamic domains of "Innovations in Chemical Synthesis, Catalysis, Coordination and Conjugated Chemistry," my commitment to pushing boundaries and fostering innovation shines through. Building on my expertise in designing novel macrocycle systems, I pioneer innovative synthetic methodologies for tailored molecules. Complementing this, I employ cutting-edge computational techniques to optimize catalytic mechanism. Leveraging cutting-edge techniques, I aspire to unravel the intricacies of molecular coordination, foster mechanistic understanding, and contribute to the ongoing evolution of coordination, conjugation and catalytic chemistry.