Innovations in Engineered Mesoporous Material for Energy Conversion and Storage Applications
Received: 03-Oct-2017 / Accepted Date: 04-Oct-2017 / Published Date: 11-Oct-2017
Keywords
Energy; Porous material; Storage; Conversion; Applications
Introduction
Today, Earth’s population stands at more than seven billions [1]. Along with a constantly growing human population, the living standards are also increasing. Energy is the initial driving force for achieving advancement in human living [2]. As a result of that, the worldwide energy consumption is expected to double within the next 35 years [3]. Fossil fuels such as coal, oil and natural gas have generated most of the energy consumed globally for over a century [4]. But fossil fuels are responsible for a significant amount of land, water and air pollution beyond their carbon dioxide production [5]. Due to large production of carbon dioxide from energy generation, along with emission from vehicles, the earth temperature rises by approximately 2-3°C and it is expected that the same will go up further [1]. This may result into geographical as well as environmental imbalance. To solve these problems, there has been recently a trend towards the increase in the utilization of various renewable energy resources [4]. In this respect, wind power, solar energy, hydrogen geothermal energy, biomass and bio-fuels are extensively investigated for a few decades both from the scientific/academic and industrial/societal viewpoints [6,7].
Among all the renewable energy resources (Figure 1), wind and solar energy received great attention, as they essentially not required water to operate and thus do not pollute water resources [9]. Solar energy has the most potential, as sun provides the earth with approximately 1,00,000 TW which is almost 10,000 times more than the current energy consumption [10]. Thus abundance of energy makes sun energy very popular for electricity production and hence enhanced their commercialization. Direct utilization of solar radiation to produce electricity is not only way to utilize the nature’s renewable energy flow via photovoltaic cells but also power can be generated at the users place. Mesoporous materials have attracted great interest in current years because of the unusual mechanical, electrical and optical properties endowed by confining the dimensions of such materials and because of the combination of bulk and surface properties to the overall behaviour. One needs only the consideration of the staggering developments in microelectronics to appreciate the potential of materials with reduced dimensions. Mesoporous materials are becoming increasingly important for electrochemical energy storage and generation [10,11].
Figure 1: Renewable energy outlook [8].
Mesoporous materials are used in many energy applications, because of their owning ability to interact and absorb with guest species on their surfaces, and in the pore spaces [12,13]. The porous materials are classified into three categories according to their pore sizes: mesoporous (2-50 nm), microporous (<2 nm) and macroporous (>50 nm). Since the first report of meso-porous silica [14], many mesoporous materials synthesized under a wide range of pore size PHs from highly basic to strongly acidic conditions, various of shape using non-ionic, cationic, neutral and anionic surfactants [15,16]. These materials have good characteristics such as high surface area, narrow pore size, uniform pore structure etc. The mesoporous materials having large pore volumes, shown promise in the loading of guest species and in the accommodation of the expansion and strain relaxation during repeated electrochemical energy storage processes (Figure 2).
Moreover, it has high surface areas should provide a large number of reaction or interaction sites for surface processes such as catalysis, adsorption, energy storage and separation. These above features are particularly advantageous for applications in energy conversion and storage [17-19]. The ordered mesoporous materials developed using various templating materials to have attracted increasing interest from the electrochemists community due to their plenty of unique properties and functionalities that can be effectively exploited in optoelectronic devices. Mesoporous materials are excellent opportunities in energy storage and energy conversion applications having to their extraordinarily high surface areas and large pore size. These properties may enhance the performance of porous materials in terms of lifetime and stability, energy and power density.
References
- Scarlett L (2015) Carbon falling economies rising: Expectations for the Paris climate.
- Wua Y, Zhu W (2013) Organic sensitizers from D–π–A to D–A–π–A: Effect of the internal electron-withdrawing units on molecular absorption, energy levels and photovoltaic performances. Chem Soc Rev 42: 2039-2058.
- Gratzel M (2009) Recent advances in sensitized mesoscopic solar cells. Acc Chem Res 42: 1788-1798.
- Liang M, Chen J (2012) Arylamine organic dyes for dye-sensitized solar cells. Chem Soc Rev 42: 3453-3488.
- Jebaselvi GDA, Paramasivam S (2013) Analysis on renewable energy systems. Renew Sustainable Energ Rev 28: 625-634.
- Bella F, Gerbaldi C, Barolo C, Gratzel M (2015) Aqueous dye-sensitized solar cells. Chem Soc Rev 44: 3431-3473.
- International Energy Outlook (2016) U.S. energy information administration. Annual Energy Outlook 2016.
- Nazar LF, Goward G, Leroux F, Duncan M, Huang H, et al. (2001) Nanostructured materials for energy storage. Int J Inorg Mater 3: 191-200.
- Hirscher M (2004) Nanoscale materials for energy storage. Mater Sci Eng B 108: 1.
- Davis ME (2002) Ordered porous materials for emerging applications. Nature 417: 813-821.
- Slater AG, Cooper AI (2015) Porous materials function-led design of new porous materials. Science 348.
- Kresge CT, Leonowicz ME, Roth WJ, Vartuli JC, Beck JS (1992) Ordered mesoporous molecular sieves synthesized by a liquid-crystal template mechanism. Nature 359: 710-712.
- Beck JS, Vartuli JC, Roth WJ, Leonowicz ME, Kresge CT, et al. (1992) A new family of mesoporous molecular sieves prepared with liquid crystal templates. J Am Chem Soc 114: 10834-10843.
- Zhao D, Huo Q, Feng J, Chmelka BF, Stucky GD (1998) Nonionic triblock and star diblock copolymer and oligomeric surfactant syntheses of highly ordered, hydrothermally stable, mesoporous silica structures. J Am Chem Soc 120: 6024-6036.
- Walcarius A (2013) Mesoporous materials and electrochemistry. Chem Soc Rev 42: 4098-4140.
- Linares N, Silvestre-Albero AM, Serrano E, Silvestre-Albero J, GarcÃa-MartÃnez J (2014) Mesoporous materials for clean energy technologies. Chem Soc Rev 43: 7681-7717.
- Ye Y, Jo C, Jeong I, Lee J (2013) Functional mesoporous materials for energy applications: Solar cells, fuel cells and batteries. Nanoscale 5: 4584-4605.
Citation: Vaghasiya JV (2017) Innovations in Engineered Mesoporous Material for Energy Conversion and Storage Applications. J Mater Sci Nanomater 1: e105.
Copyright: © 2017 Vaghasiya JV. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Share This Article
Recommended Journals
Open Access Journals
Article Usage
- Total views: 5142
- [From(publication date): 0-2017 - Nov 21, 2024]
- Breakdown by view type
- HTML page views: 4399
- PDF downloads: 743