Project Abstract

Abstract
Enhanced oil recovery (EOR) techniques play a crucial role in maximizing oil production from mature oil fields. With the declining reserves of conventional oil fields, the implementation of innovative technologies such as nanotechnology has gained significant attention in the petroleum industry. This research focuses on exploring the applications of nanotechnology in enhancing oil recovery from mature oil fields. The primary objective is to investigate the effectiveness of nanotechnology-based methods in improving oil production rates and extending the lifespan of mature oil fields. The research begins with an introduction providing insights into the challenges faced by the oil and gas industry, particularly in mature oil fields. A comprehensive background study is conducted to understand the fundamentals of enhanced oil recovery techniques and the role of nanotechnology in this context. The problem statement highlights the limitations of conventional EOR methods and the need for advanced technologies to optimize oil recovery rates. The objectives of the study include evaluating different nanotechnology applications such as nanoparticles, nanofluids, and nanosensors for enhanced oil recovery. The limitations and challenges associated with the implementation of nanotechnology in mature oil fields are also discussed. The scope of the study encompasses a detailed analysis of case studies and field trials to assess the practical implications of nanotechnology-based EOR techniques. The significance of the research lies in its potential to revolutionize the oil and gas industry by unlocking new opportunities for maximizing oil recovery from mature reservoirs. The structure of the research is organized into five chapters, including an introduction, literature review, research methodology, discussion of findings, and conclusion. In the literature review chapter, ten key aspects of nanotechnology applications in EOR are examined, including nanofluid properties, reservoir characterization, well stimulation techniques, and environmental considerations. The research methodology chapter outlines the experimental approach, data collection methods, and analytical techniques used to evaluate the efficiency of nanotechnology-based EOR methods. The discussion of findings chapter presents in-depth analysis and interpretation of the results obtained from field trials and case studies. Eight key findings related to the effectiveness, feasibility, and challenges of using nanotechnology in mature oil fields are discussed, providing valuable insights for industry practitioners and researchers. In conclusion, this research highlights the promising potential of nanotechnology in enhancing oil recovery from mature oil fields. By leveraging advanced nanotechnology applications, the oil and gas industry can overcome the limitations of conventional EOR methods and improve reservoir performance. The findings of this study contribute to the growing body of knowledge on innovative EOR techniques and pave the way for sustainable oil production in mature oil fields.

Project Overview

Enhanced Oil Recovery (EOR) techniques play a crucial role in the oil and gas industry, particularly in mature oil fields where conventional methods have reached their limits. With the increasing global energy demand and the depletion of easily accessible oil reserves, the development of advanced technologies such as nanotechnology has become essential to maximize oil production from existing reservoirs. This research project focuses on investigating the application of nanotechnology in enhancing oil recovery from mature oil fields. Nanotechnology involves the manipulation of materials at the nanoscale level, offering unique properties and capabilities that can be leveraged to improve oil displacement efficiency and recovery rates. By utilizing nanoparticles, nanofluids, and other nano-enabled solutions, it is possible to overcome the challenges associated with low oil mobility, reservoir heterogeneity, and fluid-rock interactions that hinder traditional EOR methods. The research aims to address the following key objectives: 1. Evaluate the effectiveness of different nanotechnology-based EOR techniques in mature oil fields. 2. Investigate the mechanisms by which nanoparticles interact with oil and reservoir rock surfaces to improve oil recovery. 3. Assess the economic feasibility and environmental impact of implementing nanotechnology in EOR operations. 4. Compare the performance of nanotechnology-enhanced EOR methods with conventional techniques in terms of oil production and reservoir management. The study will involve a comprehensive literature review to establish the current state-of-the-art in nanotechnology applications for EOR and identify gaps in existing research. Subsequently, experimental studies and numerical simulations will be conducted to explore the performance of various nanomaterials and formulations in enhancing oil recovery under realistic reservoir conditions. The research methodology will encompass laboratory experiments, core flooding tests, reservoir modeling, and cost-benefit analysis to provide a holistic understanding of the potential benefits and challenges associated with implementing nanotechnology in mature oil fields. Data analysis and interpretation will be conducted to derive actionable insights and recommendations for industry stakeholders and policymakers. By shedding light on the opportunities and limitations of nanotechnology-based EOR techniques, this research aims to contribute to the advancement of sustainable energy practices and the optimization of oil production from mature reservoirs. The findings of this study are expected to have significant implications for the oil and gas sector, paving the way for innovative approaches to maximize reservoir recovery and extend the lifespan of mature oil fields in a cost-effective and environmentally responsible manner.