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Journal articles on the topic 'Green Energy Storage'

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Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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1

Kausar, Ayesha. "Green Nanocomposites for Energy Storage." Journal of Composites Science 5, no. 8 (August 2, 2021): 202. http://dx.doi.org/10.3390/jcs5080202.

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The green nanocomposites have elite features of sustainable polymers and eco-friendly nanofillers. The green or eco-friendly nanomaterials are low cost, lightweight, eco-friendly, and highly competent for the range of energy applications. This article initially expresses the notions of eco-polymers, eco-nanofillers, and green nanocomposites. Afterward, the energy-related applications of the green nanocomposites have been specified. The green nanocomposites have been used in various energy devices such as solar cells, batteries, light-emitting diodes, etc. The main focus of this artifact is the energy storage application of green nanocomposites. The capacitors have been recognized as corporate devices for energy storage, particularly electrical energy. In this regard, high-performance supercapacitors have been proposed based on sustainable nanocomposites. Consequently, this article presents various approaches providing key knowledge for the design and development of multi-functional energy storage materials. In addition, the future prospects of the green nanocomposites towards energy storage have been discussed.
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Żygadło, Monika, Jerzy Kotowski, and Jacek Oko. "Green computing and energy storage systems." E3S Web of Conferences 44 (2018): 00202. http://dx.doi.org/10.1051/e3sconf/20184400202.

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Because of growing amount of the data(known as „big data”) needed to be store and process there is a rapid growth of usage electricity and emission. In this paper we present the IT solution of this problem: green computing, solutions to storage and manage the energy and IT support needed to manage and control those systems. The article presents the main idea and already implemented solutions.
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3

Yang, Zhenguo, Jianlu Zhang, Michael C. W. Kintner-Meyer, Xiaochuan Lu, Daiwon Choi, John P. Lemmon, and Jun Liu. "Electrochemical Energy Storage for Green Grid." Chemical Reviews 111, no. 5 (May 11, 2011): 3577–613. http://dx.doi.org/10.1021/cr100290v.

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4

Margeta, Jure. "Water storage as energy storage in green power system." Sustainable Energy Technologies and Assessments 5 (March 2014): 75–83. http://dx.doi.org/10.1016/j.seta.2013.12.002.

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5

OTAKA, Toshio. "F102 STUDY OF A GREEN ROOF BUILDING AIR-CONDITIONING SYSTEM WITH THERMAL ENERGY STORAGE UNITS USING LIGHT WEIGHT SOIL : PERFORMANCES OF THERMAL ENERGY STORAGE UNITS(Energy Storage and Load Leveling)." Proceedings of the International Conference on Power Engineering (ICOPE) 2009.1 (2009): _1–299_—_1–303_. http://dx.doi.org/10.1299/jsmeicope.2009.1._1-299_.

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6

Giaccherini, Andrea, Ivan Colantoni, Francesco D'Acapito, Antonio De Luca, Ferdinando Capolupo, Giordano Montegrossi, Maurizio Romanelli, Massimo Innocenti, and Francesco Di Benedetto. "Green synthesis of pyrite nanoparticles for energy conversion and storage: a spectroscopic investigation." European Journal of Mineralogy 28, no. 3 (September 23, 2016): 611–18. http://dx.doi.org/10.1127/ejm/2016/0028-2534.

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7

Ibrahim, Abdelrahman M., Ahmed A. Zewail, and Aylin Yener. "Green Distributed Storage Using Energy Harvesting Nodes." IEEE Journal on Selected Areas in Communications 34, no. 5 (May 2016): 1590–603. http://dx.doi.org/10.1109/jsac.2016.2545538.

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8

Filote, Constantin, Raluca-Andreea Felseghi, Filip Cârlea, Mihai Raţă, Claudia Steluţa Martiş, Alexandru Lavric, Daniel Fodorean, and Maria Simona Răboacă. "Green Hybrid Energy for Office Building." E3S Web of Conferences 111 (2019): 04026. http://dx.doi.org/10.1051/e3sconf/201911104026.

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This contribution presents a comparative study of operating a green energy hybrid system to sustain the power production mix of an office building. For this purpose, two scenarios of a hydrogen storage system (S1) and battery energy storage (S2) to sustain solar and wind energy inlets were compared from a technical, environmental and financial perspectives. S1 - hydrogen technology system was found to be more performing than S2 - battery technology in terms of energy efficiency, as well as CO2 emissions and initial costs.
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9

Chen, Bin. "Nanomaterials for Green Energy: Next-Generation Energy Conversion and Storage." IEEE Nanotechnology Magazine 6, no. 3 (September 2012): 4–7. http://dx.doi.org/10.1109/mnano.2012.2203875.

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10

TUDORACHE, V., M. MINESCU, N. ILIAS, and I. OFFENBERG. "FROM NATURAL GAS TO GREEN HYDROGEN." Neft i gaz, no. 4 (August 30, 2021): 125. http://dx.doi.org/10.37878/2708-0080/2021-4.09.

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Since hydrogen usually exists on Earth as part of a compound, it has to be synthesized in specific processes in order to be used as a product or energy source. This can be achieved by different technical methods, and various primary energy sources, – both fossil and renewable fuels, in solid, liquid or gaseous form, – can be used in these technical production processes. Hydrogen has only a very low volumetric energy density, which means that it has to be compressed for storage and transportation purposes. The most important commercial storage method, – especially for end users, – is the storage of hydrogen as a compressed gas. A higher storage density can be achieved by hydrogen liquefaction. Novel materials-based storage media (metal hydrides, liquids or sorbents) are still at the research and development stage. The storage of hydrogen (for example, to compression or liquefaction) requires energy; work is, in present, on more efficient storage methods. Unlike electricity, hydrogen can be successfully stored in large amounts for extended periods of time. For example, in long-term underground storage facilities hydrogen can play an important role as a buffer store for electricity from surplus provided by renewable energies. At present, pure hydrogen is generally transported by lorry in pressurize gas containers, and in some cases also in cryogenic liquid tanks. Moreover, local/regional hydrogen pipeline networks are available in some locations. Another solution for storage and transportation are Liquid Organic Hydrogen Carriers (LOHC) that can use long pipe networks and ships. In the near future, the natural gas supply infrastructure or oil (transportation pipelines and underground storage facilities) could also be used, in specific conditions, for the storage and transportation of pure or blended hydrogen with methane. This could be essential for transition because most important primary energy source for hydrogen production currently is natural gas, at 71%, followed by oil, coal and electricity (as a secondary energy resource). Steam reforming (from natural gas) is the most commonly used method for hydrogen production. In this new light, the article explores the trend and prospects for hydrogen, presented in the literature, as a source of energy competing with gas and oil resources in the global energy system of the future.
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11

Zhang, Qian, Lakshmi Suresh, Qijie Liang, Yaoxin Zhang, Lin Yang, Nikita Paul, and Swee Ching Tan. "Emerging Technologies for Green Energy Conversion and Storage." Advanced Sustainable Systems 5, no. 3 (February 15, 2021): 2000152. http://dx.doi.org/10.1002/adsu.202000152.

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12

Zhang, Xinruo, Mohammad Reza Nakhai, and Wan Nur Suryani Firuz Wan Ariffin. "Adaptive Energy Storage Management in Green Wireless Networks." IEEE Signal Processing Letters 24, no. 7 (July 2017): 1044–48. http://dx.doi.org/10.1109/lsp.2017.2707059.

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13

Wei, Jiayuan, Shiyu Geng, Olli Pitkänen, Topias Järvinen, Krisztian Kordas, and Kristiina Oksman. "Green Carbon Nanofiber Networks for Advanced Energy Storage." ACS Applied Energy Materials 3, no. 4 (April 2, 2020): 3530–40. http://dx.doi.org/10.1021/acsaem.0c00065.

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14

Kausar, Ayesha, Ishaq Ahmad, Malik Maaza, M. H. Eisa, and Patrizia Bocchetta. "Cutting-Edge Green Polymer/Nanocarbon Nanocomposite for Supercapacitor—State-of-the-Art." Journal of Composites Science 6, no. 12 (December 6, 2022): 376. http://dx.doi.org/10.3390/jcs6120376.

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Supercapacitors have attained a special stance among energy storage devices such as capacitors, batteries, fuel cell, and so forth. In this state-of-the-art overview on green synthesis approaches and green materials for supercapacitors, the cutting-edge green polymer/nanocarbon nanocomposite systems were explored by focusing on the design and related essential features. In this regard, various polymers were reconnoitered including conjugated polymers, thermosetting matrices, and green-cellulose-based matrices. Nanocarbon nanomaterials have also expanded research thoughtfulness for green-technology-based energy storage devices. Consequently, green polymer/nanocarbon nanocomposites have publicized fine electron conduction pathways to promote the charge storage, specific capacitance, energy density, and other essential features of supercapacitors. Future research directions must focus on the design of novel high performance green nanocomposites for energy storage applications.
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Mensah-Darkwa, Kwadwo, Camila Zequine, Pawan Kahol, and Ram Gupta. "Supercapacitor Energy Storage Device Using Biowastes: A Sustainable Approach to Green Energy." Sustainability 11, no. 2 (January 15, 2019): 414. http://dx.doi.org/10.3390/su11020414.

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The demand for renewable energy sources worldwide has gained tremendous research attention over the past decades. Technologies such as wind and solar have been widely researched and reported in the literature. However, economical use of these technologies has not been widespread due partly to cost and the inability for service during of-source periods. To make these technologies more competitive, research into energy storage systems has intensified over the last few decades. The idea is to devise an energy storage system that allows for storage of electricity during lean hours at a relatively cheaper value and delivery later. Energy storage and delivery technologies such as supercapacitors can store and deliver energy at a very fast rate, offering high current in a short duration. The past decade has witnessed a rapid growth in research and development in supercapacitor technology. Several electrochemical properties of the electrode material and electrolyte have been reported in the literature. Supercapacitor electrode materials such as carbon and carbon-based materials have received increasing attention because of their high specific surface area, good electrical conductivity and excellent stability in harsh environments etc. In recent years, there has been an increasing interest in biomass-derived activated carbons as an electrode material for supercapacitor applications. The development of an alternative supercapacitor electrode material from biowaste serves two main purposes: (1) It helps with waste disposal; converting waste to a useful product, and (2) it provides an economic argument for the substantiality of supercapacitor technology. This article reviews recent developments in carbon and carbon-based materials derived from biowaste for supercapacitor technology. A comparison between the various storage mechanisms and electrochemical performance of electrodes derived from biowaste is presented.
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16

Bonnici, Maximilian, Henry Greene, and Isabelle Bonnici. "Barriers for Clean Energy Projects." Journal of Clean Energy Technologies 9, no. 2 (April 2021): 24–27. http://dx.doi.org/10.18178/jocet.2021.9.2.256.

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Clean energy may offer a more environmentally friendly outcome than fossil fuels. However, clean energy is beset by uncertainties when the sun does not shine through and the wind does not blow. Worse still, science has not yet overcome scalability issues that are compounded by lack of technological knowhow on how to store solar and wind energy. The electrical “green-outs” of August 2020 in California are a reminder that without storage facilities for clean energy, utilities are driven to spot markets for electricity rendered from traditional sources of energy as economic setbacks occur due to compromised supplies of electricity. Without means of energy storage, new technology cannot fully replace the old. One can only hope that the dream to build a future based on renewable energy will lead to discoveries that will overcome scalability and storage issues.
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17

Xu, Ying. "Application of Nanocomposite Energy Storage Materials in Green Building Design." International Journal of Analytical Chemistry 2022 (September 27, 2022): 1–6. http://dx.doi.org/10.1155/2022/7739734.

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In order to solve the problem of the application of composite phase change heat storage materials in building energy conservation, the author proposes the application of nanocomposite energy storage materials in green building design. Modified carbon nanotubes were prepared by mixed acid oxidation and ball milling, and composited with stearic acid to prepare phase change heat storage materials. Modified carbon nanotubes were prepared by mixed acid oxidation and ball milling and composited with stearic acid to prepare phase change heat storage materials. Experimental results show that acidified carbon nanotubes have a hindering effect on the thermal diffusion of stearic acid molecular segments so that the thermal conductivity of carbon nanotubes added with a mass fraction of 1% is only 1.3 times higher than that of pure stearic acid. Conclusion. Nanocomposite energy storage materials have excellent application prospects in green building design.
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18

Ma, Chao-Tsung, and Chin-Lung Hsieh. "Investigation on Hybrid Energy Storage Systems and Their Application in Green Energy Systems." Electronics 9, no. 11 (November 13, 2020): 1907. http://dx.doi.org/10.3390/electronics9111907.

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Power systems all over the world have been under development towards microgrids integrated with renewable energy-based distributed generation. Due to the intrinsic nature of output power fluctuations in renewable energy-based power generation, the use of proper energy storage systems and integrated real-time power and energy control schemes is an important basis of sustainable development of renewable energy-based distributed systems and microgrids. The aim of this paper is to investigate the characteristics and application features of an integrated compound energy storage system via simulation and a small-scale hardware system implementation. This paper first discusses the main components, working principles and operating modes of the proposed compound energy storage system. Then, a detailed design example composed of supercapacitors, batteries, and various controllers used in two typical application scenarios, peak demand shaving and power generation smoothing, of a grid-connected microgrid is systematically presented. Finally, an experimental setup with proper power converters and control schemes are implemented for the verification of the proposed control scheme. Both simulation and implementation results prove that the proposed scheme can effectively realize desired control objectives with the proposed coordinated control of the two energy storage devices.
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19

Thakur, Vijay Kumar, Meng-Fang Lin, Eu Jin Tan, and Pooi See Lee. "Green aqueous modification of fluoropolymers for energy storage applications." Journal of Materials Chemistry 22, no. 13 (2012): 5951. http://dx.doi.org/10.1039/c2jm15665b.

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20

Arbabzadeh, Maryam, Jeremiah X. Johnson, Gregory A. Keoleian, Paul G. Rasmussen, and Levi T. Thompson. "Twelve Principles for Green Energy Storage in Grid Applications." Environmental Science & Technology 50, no. 2 (December 23, 2015): 1046–55. http://dx.doi.org/10.1021/acs.est.5b03867.

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21

Chang, Zheng, Yaqiong Yang, Minxia Li, Xiaowei Wang, and Yuping Wu. "Green energy storage chemistries based on neutral aqueous electrolytes." J. Mater. Chem. A 2, no. 28 (2014): 10739–55. http://dx.doi.org/10.1039/c4ta00565a.

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22

Zhang, Suojiang, Jian Sun, Xiaochun Zhang, Jiayu Xin, Qingqing Miao, and Jianji Wang. "Ionic liquid-based green processes for energy production." Chem. Soc. Rev. 43, no. 22 (2014): 7838–69. http://dx.doi.org/10.1039/c3cs60409h.

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23

Bekebrok, Heinz, Hendrik Langnickel, Adam Pluta, Marco Zobel, and Alexander Dyck. "Underground Storage of Green Hydrogen—Boundary Conditions for Compressor Systems." Energies 15, no. 16 (August 18, 2022): 5972. http://dx.doi.org/10.3390/en15165972.

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The large-scale storage of hydrogen in salt caverns, modelled on today’s natural gas storage, is a promising approach to storing renewable energy over a large power range and for the required time period. An essential subsystem of the overall gas storage is the surface facility and, in particular, the compressor system. The future design of compressor systems for hydrogen storage strongly depends on the respective boundary conditions. Therefore, this work analyses the requirements of compressor systems for cavern storage facilities for the storage of green hydrogen, i.e., hydrogen produced from renewable energy sources, using the example of Lower Saxony in Germany. In this course, a hydrogen storage demand profile of one year is developed in hourly resolution from feed-in time series of renewable energy sources. The injection profile relevant for compressor operation is compared with current natural gas injection operation modes.
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24

Xia, Rongqi, Weiye Zhang, Yingni Yang, Junqi Zhao, Yi Liu, and Hongwu Guo. "Transparent wood with phase change heat storage as novel green energy storage composites for building energy conservation." Journal of Cleaner Production 296 (May 2021): 126598. http://dx.doi.org/10.1016/j.jclepro.2021.126598.

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25

Dubini, Alexandra. "Green energy from green algae: Biofuel production from Chlamydomonas reinhardtii." Biochemist 33, no. 2 (April 1, 2011): 20–23. http://dx.doi.org/10.1042/bio03302020.

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Looking for alternative ‘green’ energy technologies? Don't look too far! Microalgae are all around us and are being used, processed and packaged for different applications, from food to pharmaceutical products and now to generate renewable green energy such as hydrogen, biodiesel and other biofuels. Microalgae in general and green algae in particular have been studied for decades with the objective of utilizing their photosynthetic capacity and their ability to adapt to changing environment and nutrient conditions as a source of a variety of products. A new era has arrived where these functions are now being examined and targeted to efficiently convert solar energy into useful carbon-based fuels and chemical precursors (alkane, ethylene), as well as gas (hydrogen) or lipid-based storage compound such as triacylglycerols (TAGs) for biodiesel application.
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26

Zhu, Chuangao, Ao Wang, Lutong Yang, and Jia Li. "Design and application of smart-microgrid in industrial park." ITM Web of Conferences 47 (2022): 03011. http://dx.doi.org/10.1051/itmconf/20224703011.

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Due to the uncertain and randomness of both wind power photovoltaic output of power generation side and charging load of user side, a set of wind-solar-storage-charging multi-energy complementary smart microgrid system in the park is designed. Through AC-DC coupled, green energy, such as wind energy, distributed photovoltaic power and battery echelon utilization energy storage power, can be supplemented as factory power. While alleviating the power consumption pressure in the plant, it also realizes functions such as smoothing the fluctuation green energy power generation, and peak loading shifting. Vehicle DC super and fast charging are also integrated in this station. The system realizes real-time state monitoring of different energy sources, energy storage, power distribution, and loads, which can guarantee green, smooth, efficient and economic operation of the multi-energy complementary system in the plant.
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27

Enshasy, Hesham, Qasem Abu Al-Haija, Hasan Al-Amri, Mohamed Al-Nashri, and Sultan Al-Muhaisen. "A SCHEMATIC DESIGN OF HHO CELL AS GREEN ENERGY STORAGE." Acta Electronica Malaysia 3, no. 2 (March 5, 2019): 09–15. http://dx.doi.org/10.26480/aem.02.2019.09.15.

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28

Zhao, Wen, Samantha Joy B. Rubio, Yanliu Dang, and Steven L. Suib. "Green Electrochemical Energy Storage Devices Based on Sustainable Manganese Dioxides." ACS ES&T Engineering 2, no. 1 (October 25, 2021): 20–42. http://dx.doi.org/10.1021/acsestengg.1c00317.

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29

Rodríguez-Varela, Javier, Ivonne L. Alonso-Lemus, Oumarou Savadogo, and Karthikeyan Palaniswamy. "Overview: Current trends in green electrochemical energy conversion and storage." Journal of Materials Research 36, no. 20 (October 28, 2021): 4071–83. http://dx.doi.org/10.1557/s43578-021-00417-w.

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30

Baliga, J., R. W. A. Ayre, K. Hinton, and R. S. Tucker. "Green Cloud Computing: Balancing Energy in Processing, Storage, and Transport." Proceedings of the IEEE 99, no. 1 (January 2011): 149–67. http://dx.doi.org/10.1109/jproc.2010.2060451.

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31

Michaelides, Efstathios E. "Making Texas Green." Mechanical Engineering 141, no. 03 (March 1, 2019): 38–41. http://dx.doi.org/10.1115/1.2019-mar-2.

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Texas is proud of its oil and gas industry, but the state is blessed with abundant solar and wind power potential. Tapping that potential requires more than simply building out more wind turbines and solar panels–Texas will need a large, but achievable energy storage system. This study analyzes if Texas coulld become a green state in the future.
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32

Abdallh, Mustafa, Zainab Hussain, Hamsa Thamer, Ali Abd Ali, Emad Yousif, and Salam Mohammed. "Nanomaterials and Energy Storage in a Glance: a Review." Al-Nahrain Journal of Science 24, no. 2 (June 1, 2021): 21–26. http://dx.doi.org/10.22401/anjs.24.2.04.

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The challenge to provide a powerful instrument with a high energy conversion is of a great importance to our modern society, not only in terms of conversion but in high-capacity storage derived by the increase for energy demand. In addition, the environmental impact of these new technologies to create a green and sustainable environment. One of these green technologies is the use of dye-sensitized solar cells to produce energy and lithium-ion batteries to store the generated energy. The need for high electronic mobility and high surface volume and activity, nano metal oxide was investigated as alternative or a new material in generation and conversion of energy. For this purpose, many metal oxides were explored especially Zinc oxide (ZnO) and titanium oxide (TiO2) due to their electronic characteristics.
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33

Ponnamma, Deepalekshmi, Hemalatha Parangusan, Kalim Deshmukh, Pradip Kar, Aqib Muzaffar, S. K. Kadheer Pasha, M. Basheer Ahamed, and Mariam Al Ali Al-Maadeed. "Green synthesized materials for sensor, actuator, energy storage and energy generation: a review." Polymer-Plastics Technology and Materials 59, no. 1 (May 20, 2019): 1–62. http://dx.doi.org/10.1080/25740881.2019.1614327.

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34

Li, Xudong, Jieying Song, Peng Yang, Zengbo Dong, Shihui Yang, and Jinwei He. "Output analysis and capacity configuration of green backup power supply in data center." Journal of Physics: Conference Series 2310, no. 1 (October 1, 2022): 012040. http://dx.doi.org/10.1088/1742-6596/2310/1/012040.

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Abstract The backup power supply ensures the stability and reliability of the power supply for a data center. Starting from green backup power supply, this paper studies the selection and configuration method of energy storage mode of backup power supply according to the backup power demand of data center and peak regulation demand of power grid, and analyzes different forms of green backup power supply and the output characteristics of hydrogen fuel cell. Aiming at improving the economy of green backup power assisted peak regulation, the capacity configuration principles of hydrogen energy storage and electrochemical energy storage technology are clarified, and then the capacity configuration of standby power in data center is simulated. The results show that the capacity configuration requirements of lithium battery, fuel cell and hydrogen storage tank corresponding to engineering life can be obtained through algorithm optimization.
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35

Zhang, Yanting, Zhe Zhu, Wei Ning, and Amir M. Fathollahi-Fard. "An Improved Optimization Algorithm Based on Density Grid for Green Storage Monitoring System." Sustainability 14, no. 17 (August 30, 2022): 10822. http://dx.doi.org/10.3390/su141710822.

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This study takes a sample of green storage monitoring data for corn from a biochemical energy enterprise, based on the enterprise’s original storage monitoring system while establishing a “green fortress” intending to achieve green and sustainable grain storage. This paper proposes a set of processing algorithms for real-time flow data from the storage system based on cluster analysis to detect abnormal storage conditions, achieve the goal of green grain storage and maximize benefits for the enterprises. Firstly, data from the corn storage monitoring system and the current status of research on data processing algorithms are analyzed. Our study summarizes the processing of re-al-time stream data together with the characteristics of the monitoring system and discusses the application of clustering analysis algorithms. The study includes an in-depth study of the green storage monitoring system data for corn and the processing requirements for real-time stream data. As the main novelty of this research, the optimization algorithm model is applied to the green storage monitoring system for maize and is validated. Finally, the processing results for the green storage monitoring data for maize are presented in graphical and textual formats.
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Wang, Xiangdong, and Zijia Lu. "Analysis of Heat and Moisture Transfer and Thermal Comfort in Green Logistics Storage Space." International Journal of Heat and Technology 40, no. 5 (November 30, 2022): 1241–48. http://dx.doi.org/10.18280/ijht.400516.

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Regular logistics storage spaces suffer a very high temperature during summer. To build a green logistics storage space, it is truly necessary to optimize the thermal environment in summer. At present, there are few related studies on the energy consumption, thermal environment and human comfort of green logistics storage spaces. Therefore, this paper analyzes the heat and moisture transfer in and studies the impacts of the thermal environment of green logistics storage space. Based on the survey results, a coupled heat-moisture transfer model of green logistics storage space was constructed, which consists of three parts - the envelope structure, the hot and humid indoor environment, and the heating, ventilation and air conditioning (HVAC) system. Based on the idea of linear regression, a model was established to predict human body’s subjective thermal sensation in green logistics storage space. The experiment showed the analysis results of heat and moisture transfer and thermal comfort in green logistics storage space, and verified the effectiveness of the proposed model.
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37

Li, Fu Zhu, Cun Tang Wang, Yu Qin Guo, and Fei Chen. "A Compressed Air Green Storage Device Based on the Hydro-Pneumatic Conversion and its Characteristic Analysis." Advanced Materials Research 516-517 (May 2012): 830–35. http://dx.doi.org/10.4028/www.scientific.net/amr.516-517.830.

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Aiming to the key demands of cost, service life, environment and the time of energy storage in the energy storage technology of the distributed power generation of renewable resources, a novel compressed air green storage device based on the hydro-pneumatic conversion is put forward on the base of thermodynamics foundational principles. By the theoretical analysis for the energy cycle process of the storage device proposed, the corresponding calculation formulae are deduced for the energy storage efficiency and density under the condition of ideal gas, respectively. In addition, the changes of above index with pressure, compression ratio, and isentropic exponent are also researched. And the results show that the energy storage efficiency and density can be improved efficiently by controlling the energy conversion under the near isothermal condition so as to enhance the heat exchange capacity between the given energy storage device and its surrounding environment.
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38

Chaleawlert-umpon, S., and C. Liedel. "More sustainable energy storage: lignin based electrodes with glyoxal crosslinking." Journal of Materials Chemistry A 5, no. 46 (2017): 24344–52. http://dx.doi.org/10.1039/c7ta07686j.

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39

Wang, Gui Xing, Zhe Heng Zhou, Shuai Zheng, Qing Xie, Chao Ping Rao, and Bing Sen Xu. "Research on the Flywheel Energy Storage System Applied in Green Architecture." Advanced Materials Research 1008-1009 (August 2014): 1466–69. http://dx.doi.org/10.4028/www.scientific.net/amr.1008-1009.1466.

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In this research, a storage system, suitable for the power system of construction, is proposed and optimized. The storage system mainly consists of control system, converter, flywheel and motor. This system can release the pressure of the power grid during the on-peak period and supply the consumers with cheap energy. This research is going to analyze the characters of the system and then adjust its structure to the architecture.
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Gorás, M., Z. Vranayová, and F. Vranay. "The trend of using solar energy of a green intelligent building and thermal energy storage to reduce the energy intensity of the building." IOP Conference Series: Materials Science and Engineering 1209, no. 1 (December 1, 2021): 012069. http://dx.doi.org/10.1088/1757-899x/1209/1/012069.

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Abstract The trend is to reduce the energy intensity of buildings. Thermal energy storage (TES) is the biggest challenge for buildings. It is a technology that supplies thermal energy by heating or cooling a tank, which then serves for the system in the building. Comparison of hitherto known systems ATES, BTES, PTES and research TTES. The most important factors for the accumulation of thermal energy are capacity (the energy stored in the system - depends on the storage process, the medium, and the size of the system), power (how fast the energy stored in the system can be discharged and charged), efficiency (the ratio of the energy provided to the user to the energy needed to charge the storage system. It accounts for the energy loss during the storage period and the charging/discharging cycle), storage (how long the energy is stored and lasts hours to months), charging and discharging (how much time is needed to charge or discharge the system), and cost (refers to capacity (€/kWh) or power (€/kW) of the TES system and depends on the capital and operation costs of the storage equipment and its lifetime).
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Castro Oliveira, Miguel, Muriel Iten, and Henrique A. Matos. "Review of Thermochemical Technologies for Water and Energy Integration Systems: Energy Storage and Recovery." Sustainability 14, no. 12 (June 20, 2022): 7506. http://dx.doi.org/10.3390/su14127506.

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Thermochemical technologies (TCT) enable the promotion of the sustainability and the operation of energy systems, as well as in industrial sites. The thermochemical operations can be applied for energy storage and energy recovery (alternative fuel production from water/wastewater, in particular green hydrogen). TCTs are proven to have a higher energy density and long-term storage compared to standard thermal storage technologies (sensible and latent). Nonetheless, these require further research on their development for the increasing of the technology readiness level (TRL). Since TCTs operate with the same input/outputs streams as other thermal storages (for instance, wastewater and waste heat streams), these may be conceptually analyzed in terms of the integration in Water and Energy Integration System (WEIS). This work is set to review the techno-economic and environmental aspects related to thermochemical energy storage (sorption and reaction-based) and wastewater-to-energy (particular focus on thermochemical water splitting technology), aiming also to assess their potential into WEIS. The exploited technologies are, in general, proved to be suitable to be installed within the conceptualization of WEIS. In the case of TCES technologies, these are proven to be significantly more potential analogues to standard TES technologies on the scope of the conceptualization of WEIS. In the case of energy recovery technologies, although a conceptualization of a pathway to produce usable heat with an input of wastewater, further study has to be performed to fully understand the use of additional fuel in combustion-based processes.
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42

Lv, Menghan. "Shared Energy System Construction Scheme of PV Array and Energy Storage Technology." Academic Journal of Science and Technology 2, no. 3 (August 26, 2022): 31–34. http://dx.doi.org/10.54097/ajst.v2i3.1440.

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My country's ecological and environmental problems are fundamentally the problems of high-carbon energy structure and high-energy-consuming, high-carbon industrial structure, which must must be solved from the source of energy structure and industrial structure transformation and upgrading. Energy consumption patterns for operation, production and living, build a high-level energy and resource-saving society, further strengthen the intensive and efficient use of fossil energy, improve the electrification level of the whole society, and build a cleaner and more efficient green and low-carbon energy production, supply and consumption system. On this basis, we propose a shared energy system construction plan of photovoltaic array and energy storage technology: taking electricity as the main energy, combining the park's photovoltaic energy storage system with shared energy storage to achieve source-grid-load-storage Coordinated and optimized to meet the user's own electricity demand and the rational use of energy.
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43

Salameh, Tareq, Abdul Ghani Olabi, Mohammad Ali Abdelkareem, Mohd Shahbudin Masdar, Siti Kartom Kamarudin, and Enas Taha Sayed. "Integrated Energy System Powered a Building in Sharjah Emirates in the United Arab Emirates." Energies 16, no. 2 (January 9, 2023): 769. http://dx.doi.org/10.3390/en16020769.

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In this study, a green hydrogen system was studied to provide electricity for an office building in the Sharjah emirate in the United Arab Emirates. Using a solar PV, a fuel cell, a diesel generator, and battery energy storage; a hybrid green hydrogen energy system was compared to a standard hybrid system (Solar PV, a diesel generator, and battery energy storage). The results show that both systems adequately provided the power needed for the load of the office building. The cost of the energy for both the basic and green hydrogen energy systems was 0.305 USD/kWh and 0.313 USD/kWh, respectively. The cost of the energy for both systems is very similar, even though the capital cost of the green hydrogen energy system was the highest value; however, the replacement and operational costs of the basic system were higher in comparison to the green hydrogen energy system. Moreover, the impact of the basic system in terms of the carbon footprint was more significant when compared with the green hydrogen system. The reduction in carbon dioxide was a 4.6 ratio when compared with the basic system.
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Thomas, Bony, Shiyu Geng, Mohini Sain, and Kristiina Oksman. "Hetero-Porous, High-Surface Area Green Carbon Aerogels for the Next-Generation Energy Storage Applications." Nanomaterials 11, no. 3 (March 8, 2021): 653. http://dx.doi.org/10.3390/nano11030653.

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Various carbon materials have been developed for energy storage applications to address the increasing energy demand in the world. However, the environmentally friendly, renewable, and nontoxic bio-based carbon resources have not been extensively investigated towards high-performance energy storage materials. Here, we report an anisotropic, hetero-porous, high-surface area carbon aerogel prepared from renewable resources achieving an excellent electrical double-layer capacitance. Two different green, abundant, and carbon-rich lignins which can be extracted from various biomasses, have been selected as raw materials, i.e., kraft and soda lignins, resulting in clearly distinct physical, structural as well as electrochemical characteristics of the carbon aerogels after carbonization. The obtained green carbon aerogel based on kraft lignin not only demonstrates a competitive specific capacitance as high as 163 F g−1 and energy density of 5.67 Wh kg−1 at a power density of 50 W kg−1 when assembled as a two-electrode symmetric supercapacitor, but also shows outstanding compressive mechanical properties. This reveals the great potential of the carbon aerogels developed in this study for the next-generation energy storage applications requiring green and renewable resources, lightweight, robust storage ability, and reliable mechanical integrity.
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45

Satpute, Vaibhav, and Anand Jawanjal. "Tapping Sun Energy coupled with affordable Energy Storage – Future Game Changer." IRA-International Journal of Technology & Engineering (ISSN 2455-4480) 7, no. 2 (S) (July 10, 2017): 65. http://dx.doi.org/10.21013/jte.icsesd201707.

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Sun provides abundant source of renewable energy that can be integrated with the electrical grid. Climate change issues have compelled policy makers to look into various ways to reduce carbon footprint and use green, renewable energy. Solar power, along with other alternative sources for energy, is quite popular these days. Talking about Solar, the primary disadvantage of solar power is that it obviously cannot be created during the night and power generated is also reduced during times of cloud cover. Energy Storage is a flexible asset that provides unprecedented flexibility in grid optimization. Cost effective solar energy storage methods are urgently needed due to the increased demand for solar power and due to its variability. But in today’s scenario, energy storage systems are not commercially economic for all customers, and that to more work needs to be done by industry, government, and regulators to support the continuing cost reductions. It is expected that the Energy Storage costs would slide to 41% by 2020.The value that solar and storage can together add to the energy system is leading to a more efficient, cleaner, and more secure future. However, solar energy storage becomes critical when unsteady sources of energy provide. Thus, affordable energy storage system along with the cheaper Solar energy would be lethal combination making an ultimate Game Changer for the Power Industry and Sustainability.
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Park, Hi-Chun, and Martin K. Patel. "Naphtha storage fraction and green house gas emissions in the Korean petrochemical industry." Energy & Environment 29, no. 6 (March 29, 2018): 919–37. http://dx.doi.org/10.1177/0958305x18762446.

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This paper shows for a Korean case study how the naphtha storage fraction and CO2 emissions from naphtha use in the petrochemical industry can be estimated. We have used the Non-Energy use Emission Accounting Tables model to estimate CO2 emissions by subtracting the carbon stored in products from the total carbon input. We also value the country’s naphtha storage fraction by calculating carbon storage in basic chemicals. The naphtha storage fraction and associated CO2 emissions from non-energy use depend on the production and trade structure of a country. Therefore, it is reasonable for Korea (with its large production and net exports of chemicals) to estimate a county-specific storage fraction. The naphtha storage fraction estimated using the Non-Energy use Emission Accounting Tables model was over 90% in Korea between 2011 and 2015. It is much higher than the Intergovernmental Panel on Climate Change default fraction of 75%. A revision of the naphtha storage fraction from 75 to 90% is proposed for Korea. The Intergovernmental Panel on Climate Change allows countries to apply their own values that more accurately represent their country’s situation. The Korean government is advised to consider this finding in its national emission accounting.
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Ciacci, Luca, and Fabrizio Passarini. "Life Cycle Assessment (LCA) of Environmental and Energy Systems." Energies 13, no. 22 (November 12, 2020): 5892. http://dx.doi.org/10.3390/en13225892.

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48

Nazir, Muhammad Shahzad, Ahmed N. Abdalla, Ahmed Sayed M. Metwally, Muhammad Imran, Patrizia Bocchetta, and Muhammad Sufyan Javed. "Cryogenic-Energy-Storage-Based Optimized Green Growth of an Integrated and Sustainable Energy System." Sustainability 14, no. 9 (April 28, 2022): 5301. http://dx.doi.org/10.3390/su14095301.

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The advancement of using the cryogenic energy storage (CES) system has enabled efficient utilization of abandoned wind and solar energy, and the system can be dispatched in the peak hours of regional power load demand to release energy. It can fill the demand gap, which is conducive to the peak regulation of the power system and can further promote the rapid development of new energy. This study optimizes the various types of energy complementary to the CES system using hybrid gravitational search algorithm-local search optimization (hGSA-LS). First, the mathematical model of the energy storage system (ESS) including the CES system is briefly described. Second, an economic scheduling optimization model of the IES is constructed by minimizing the operating cost of the system. Third, the hGSA-LS methods to solve the optimization problem are proposed. Simulations show that the hGSA-LS methodology is more efficient. The simulation results verify the feasibility of CES compared with traditional systems in terms of economic benefits, new energy consumption rate, primary energy saving rate, and carbon emissions under different fluctuations in energy prices. Optimization of the system operation using the proposed hGSA-LS algorithm takes 5.87 s; however, the GA, PSO, and GSA require 12.56, 10.33, and 7.95 s, respectively. Thus, the hGSA-LS algorithm shows a comparatively better performance than GA, PSO, and GSA in terms of time.
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49

Kühn, Michael, Natalie C. Nakaten, and Thomas Kempka. "Geological storage capacity for green excess energy readily available in Germany." Advances in Geosciences 54 (December 3, 2020): 173–78. http://dx.doi.org/10.5194/adgeo-54-173-2020.

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Abstract. Energy supply in Germany is subject to a profound change. The present paper addresses the German potential of storing excess energy from renewable power sources in the geological subsurface. Wind and solar electricity can be transformed into hydrogen, and with carbon dioxide subsequently into methane. When needed, electricity is regained in a gas turbine power plant combusting the methane. Here, we are taking into account the actual German storage capacity for natural gas and show that the outlined technology is ready for operation and economically competitive. The current potential for combined storage of methane and carbon dioxide allows to store around 80 TWh renewable excess energy. This is far more than required to date and estimated to provide the entire coverage in 2050.
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Borkar, Hitesh, V. N. Singh, B. P. Singh, M. Tomar, Vinay Gupta, and Ashok Kumar. "Room temperature lead-free relaxor–antiferroelectric electroceramics for energy storage applications." RSC Adv. 4, no. 44 (2014): 22840–47. http://dx.doi.org/10.1039/c4ra00094c.

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