EFFECT OF TITANIUM DIOXIDE NANOPARTICLE ON MICROBIAL BIOMETHANE POTENTIAL
Table Of Contents
- <p> </p><p>Title page — – – – – – – – – – – i </p><p>Declaration — – – – – – – – – – -ii</p><p>Approval page — – – – – – – – – – -iii</p><p>Dedication — – – – – – – – – – -iv</p><p>Acknowledgement — – – – – – – – – -v </p><p>Table of content — – – – – – – – – -vi Abstract — – – – – – – – – – – -vi</p> <br><p></p>
Project Abstract
The utilization of renewable energy sources has gained significant attention due to the increasing energy demand and environmental concerns associated with fossil fuels. Biomethane, a clean and sustainable energy source, is produced through anaerobic digestion of organic matter by microbial communities. However, the efficiency of biomethane production can be limited by the slow degradation rates of complex organic compounds. In recent years, nanotechnology has emerged as a promising avenue for enhancing various processes, including bioenergy production. This study investigates the effect of titanium dioxide (TiO2) nanoparticles on microbial biomethane potential during anaerobic digestion. TiO2 nanoparticles are known for their photocatalytic properties and have been shown to improve the degradation of organic matter in wastewater treatment processes. In the context of biomethane production, TiO2 nanoparticles have the potential to enhance the breakdown of complex organic compounds into simpler molecules that can be more readily metabolized by methanogenic microorganisms. The experimental setup involved batch anaerobic digestion tests using mixed microbial consortia obtained from anaerobic sludge. Different concentrations of TiO2 nanoparticles were introduced to the digestion reactors to assess their impact on biomethane production. Methane production rates, biogas composition, and microbial community dynamics were monitored throughout the experiments to evaluate the effects of TiO2 nanoparticles. The results indicate that the addition of TiO2 nanoparticles significantly enhanced biomethane production compared to the control group without nanoparticles. The presence of TiO2 nanoparticles promoted the degradation of complex organic compounds, leading to increased methane yields. Moreover, the nanoparticles influenced the microbial community structure, favoring the growth of methanogenic bacteria responsible for methane production. Overall, this study demonstrates the potential of TiO2 nanoparticles as a novel approach to enhance microbial biomethane potential during anaerobic digestion. The findings suggest that nanotechnology can be effectively applied to improve the efficiency of biomethane production processes, offering a sustainable solution for renewable energy generation. Further research is warranted to optimize the nanoparticle concentration and assess the long-term effects on microbial communities and biomethane production in full-scale anaerobic digestion systems.
Project Overview
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</p><p><strong>1.0 Introduction </strong></p><p>Much attention has been given to nanotechnology and nanoscience over the last decade. These studies involve a wide spectrum of research areas and industrial activities from fundamental sciences (that is physics, chemistry and biology) to applied science (that is electronics and materials) on the nanoscale (1nm=10-9m) (Liu, 2006).One of the major developments in nanotechnology and nanoscience is the production and application of nanoparticles. In general, nanoparticles are chemicals smaller than 100nanometers, contain 20-15000 of atoms, and exist in a realm that straddles the quantum and Newton scales (Shan <em>et al</em>., 2005). Nanoparticles can be produced from different materials in different shapes such as spheres, rods, wires and tubes (Chang <em>et al</em>., 2005), they occur naturally in aquatic and terrestrial environments in finer fractions of colloidal clays, mineral precipitates and dissolved organic matter (Batley <em>et al</em>., 2006). The uses of nanoparticles are widely reported in a wide variety of areas including advanced materials, electronics, magnetics and optoelectronics, biomedicine, pharmaceuticals, cosmetics, energy, and catalytic and environmental detection and monitoring. The use of nanoparticles over the last decade has been more frequent in applications of industrial nature and in consumer and medical products (Batley <em>et al</em>., 2011), the use of nanosized materials offers exciting and new options in these fields and the applications of nanoparticles will likely continue to increase (Frohlich, 2011).</p><p>Due to its wide applicability, nanoparticles are easily released into the environment when the goods in which they are contained in are disposed. Nanoparticles can be added to soils directly through fertilizers or plant protection products or indirectly through application to land or wastewater treatment products such as sludges or biosolids (Franklin <em>et al</em>., 2007). Nanoparticles may enter aquatic systems directly through industrial discharges or from disposal of wastewater effluents or indirectly through surface runoff from soils. However, researchers found that once released into the environment, nanoparticles might pose as potential risks to human health, microorganisms and other life forms (Zheng<em>et al</em>., 2011). In addition to physiochemical parameters such as contamination with toxic elements, fibrous structure and high surface charge, the formation of radical species was identified as key mechanism for the cytotoxic action of nanoparticles. Toxic effects of nanoparticles dubbed as “nanotoxicity” are increasingly evidenced, the extent of nanotoxicity depends on the charge, size and nature of the nanoparticle.</p><p>In the environment, nanoparticles can undergo a number of potential transformations that depend on the properties of both the nanoparticle and the receiving medium (Rogers <em>et al</em>., 2010). These transformations largely involve chemical and physical processes which may change the fate of the nanoparticle in the environment. Risk assessment for nanoparticle releases into the environment is still in their infancy, and reliable measurements of nanoparticles at environmental concentrations remain challenging. Predicted environmental concentrations based on current usage are low but are expected to increase as use increases.</p><p> </p><p><strong>1.2 Aims and Objectives</strong></p><ul><li>Understand the influence of TiOâ‚‚ on microbial activity during anaerobic digestion of food waste</li><li>Assess the effect of TiOâ‚‚ on the volatile fatty acid production and biomethane potential</li><li>Determine TiOâ‚‚ effect on the diversity and population changes in the methanogenic microbial community.</li></ul>
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