Project Abstract

Abstract
The demand for sustainable and clean energy sources has driven research in the field of hydrogen production. Steam methane reforming (SMR) is a widely used method for hydrogen production, but the process is energy-intensive and produces greenhouse gases. The aim of this research is to evaluate novel catalysts for SMR to enhance hydrogen production efficiency and minimize environmental impact. The study will focus on the development and characterization of catalysts that promote the reforming reactions while reducing carbon formation and improving catalyst stability. Chapter One provides an introduction to the research topic, including the background, problem statement, objectives, limitations, scope, significance, structure of the research, and definition of key terms. Chapter Two presents an extensive literature review covering various catalysts used in SMR, their mechanisms, and recent advancements in the field. Chapter Three outlines the research methodology, including catalyst synthesis, characterization techniques, reactor design, and experimental procedures. In Chapter Four, the research findings are discussed in detail, analyzing the performance of the novel catalysts in terms of hydrogen production efficiency, carbon formation, stability, and selectivity. The results are compared with conventional catalysts to evaluate the effectiveness of the novel catalysts in improving SMR process parameters. Various factors influencing catalyst activity and selectivity are also explored. Finally, Chapter Five presents the conclusion and summary of the research, highlighting the key findings, implications, and recommendations for future studies. The research contributes to the advancement of sustainable hydrogen production technologies by proposing novel catalysts that can enhance the performance of the SMR process. Overall, this study aims to address the challenges associated with hydrogen production via SMR and pave the way for more efficient and environmentally friendly hydrogen production methods.

Project Overview

The research project titled "Evaluation of Novel Catalysts for Sustainable Hydrogen Production via Steam Methane Reforming" aims to investigate and analyze the effectiveness of innovative catalysts in the process of sustainable hydrogen production through steam methane reforming (SMR). Hydrogen is considered a promising clean energy carrier that can contribute significantly to reducing greenhouse gas emissions and transitioning towards a more sustainable energy future. One of the most common methods for large-scale hydrogen production is SMR, which involves reacting methane with steam over a catalyst to produce hydrogen and carbon monoxide. The focus of this research is on evaluating novel catalyst materials that can enhance the efficiency, selectivity, and durability of the SMR process. The selection and design of suitable catalysts play a crucial role in improving the overall performance of hydrogen production, including enhancing conversion rates, minimizing by-product formation, and extending catalyst lifespan. By exploring and comparing different catalyst formulations, compositions, and structures, this study aims to identify catalysts that exhibit superior performance characteristics for sustainable hydrogen production. The research will involve comprehensive literature reviews to gather relevant information on the principles of SMR, catalyst types used in the process, and recent advancements in catalyst development for hydrogen production. By synthesizing existing knowledge and research findings, the study will establish a solid foundation for the subsequent experimental investigation of novel catalysts. Experimental work will include the preparation, characterization, and testing of various catalyst samples under controlled conditions mimicking SMR reaction environments. The performance of each catalyst will be assessed based on key parameters such as hydrogen yield, carbon monoxide formation, catalyst activity, stability, and resistance to deactivation mechanisms. Advanced analytical techniques, such as X-ray diffraction, scanning electron microscopy, and surface area analysis, will be employed to study the physicochemical properties of the catalysts and gain insights into their structure-activity relationships. The research methodology will also involve optimization studies to fine-tune the operating conditions of the SMR process and catalyst formulations for improved hydrogen production efficiency. By systematically evaluating and comparing the performance of different catalysts, this study aims to identify promising candidates that exhibit superior catalytic activity and stability for sustainable hydrogen production. The findings of this research project are expected to contribute to the development of advanced catalyst materials tailored for efficient and environmentally friendly hydrogen production via SMR. By enhancing the understanding of catalyst design and performance in the context of sustainable energy applications, this study seeks to provide valuable insights that can potentially drive innovation and progress in the field of hydrogen production technologies. Ultimately, the research outcomes aim to support the transition towards a greener and more sustainable energy landscape by facilitating the adoption of cleaner hydrogen as a key energy carrier.