Relevant bibliographies by topics / Maisotsenko

Academic literature on the topic 'Maisotsenko'

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

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Journal articles on the topic "Maisotsenko"

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Rezaee, Vahid, and Arash Houshmand. "Feasibility Study Of Maisotsenko Indirect Evaporative Air Cooling Cycle In Iran." GeoScience Engineering 61, no. 2 (June 1, 2015): 23–36. http://dx.doi.org/10.1515/gse-2015-0015.

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Abstract This paper presents energy and exergy analysis of air cooling cycle based on novel Maisotsenko indirect evaporative cooling cycle. Maisotsenko cycle (M-cycle) provides desired cooling condition above the dew point and below the wet bulb temperature. In this study, based on average annual temperature, The Iran area is segmented into eleven climates. In energy analysis, wet-bulb and dew point effectiveness, cooling capacity rate and in exergy analysis, exergy input rate, exergy destruction rate, exergy loss, exergy efficiency, exergetic COP and entropy generation rate for Iran's weather conditions in the indicated climates are calculated. Moreover, a feasibility study based on water evaporation rate and Maisotsenko cycle was presented. Energy and exergy analysis results show that the fifth, sixth, seventh and eighth climates are quite compatible and Rasht, Sari, Ramsar and Ardabile cities are irreconcilable with the Maisotsenko cycle.
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Gillan, Leland. "MAISOTSENKO CYCLE FOR COOLING PROCESSES." International Journal of Energy for a Clean Environment 9, no. 1-3 (2008): 47–64. http://dx.doi.org/10.1615/interjenercleanenv.v9.i1-3.50.

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Levchenko, D., I. Yurko, A. Artyukhov, and V. Baga. "Maisotsenko cycle applications for multistage compressors cooling." IOP Conference Series: Materials Science and Engineering 233 (August 2017): 012023. http://dx.doi.org/10.1088/1757-899x/233/1/012023.

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Chow, T. T., Guangya Zhu, and C. K. Lee. "System optimization of innovative tri-generation system for distributed power application." E3S Web of Conferences 111 (2019): 06018. http://dx.doi.org/10.1051/e3sconf/201911106018.

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The building sector is one major primary energy consumer and pollutant emission source. In recent years, the building-related research studies on the potential use of Maisotsenko-cycle in energy systems have been increasing in recent years. The growing interest lies in its expanded applications beyond the air-conditioning systems (the main “energy consumers” in buildings) into the prime movers (the key players in power generation). In order to evaluate its application merits in the practical tri-generation system of the urban districts, an extensive computer simulation platform has been developed. Based on a case study, this paper describes the techniques in the mixed use of numerical tools in performing system optimization studies for distributed power application on a university campus site. The practicality of the methodology is demonstrated through a hypothetical tri-generation system primed with Maisotsenko combustion turbine cycle. The findings are very much interesting.
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Reyzin, Ilya. "EVALUATION OF THE MAISOTSENKO POWER CYCLE THERMODYNAMIC EFFICIENCY." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 129–39. http://dx.doi.org/10.1615/interjenercleanenv.2012005808.

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Gillan, Leland, Alan Gillan, Aleksandr Kozlov, and David Kalensky. "AN ADVANCED EVAPORATIVE CONDENSER THROUGH THE MAISOTSENKO CYCLE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 251–58. http://dx.doi.org/10.1615/interjenercleanenv.2013006619.

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Saghafifar, Mohammad, and Mohamed Gadalla. "Analysis of Maisotsenko open gas turbine bottoming cycle." Applied Thermal Engineering 82 (May 2015): 351–59. http://dx.doi.org/10.1016/j.applthermaleng.2015.02.032.

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Khalatov, Artem, I. Karp, and B. Isakov. "PROSPECTS OF THE MAISOTSENKO THERMODYNAMIC CYCLE APPLICATION IN UKRAINE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 141–57. http://dx.doi.org/10.1615/interjenercleanenv.2012005916.

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Weerts, Benjamin. "COOLERADO AND MODELING AN APPLICATION OF THE MAISOTSENKO CYCLE." International Journal of Energy for a Clean Environment 12, no. 2-4 (2011): 287–307. http://dx.doi.org/10.1615/interjenercleanenv.2013005585.

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Zhu, Guangya, Tin-Tai Chow, and Chun-Kwong Lee. "Performance analysis of biogas-fueled maisotsenko combustion turbine cycle." Applied Thermal Engineering 195 (August 2021): 117247. http://dx.doi.org/10.1016/j.applthermaleng.2021.117247.

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Dissertations / Theses on the topic "Maisotsenko"

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SadighiDizaji, Hamed. "Investigation of the Maisotsenko Cycle Based Air Conditioning Systems." Thesis, 2021. http://hdl.handle.net/2440/130752.

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Water evaporative based air coolers become more and more popular because of their lower energy consumption compared to the compressor-refrigerant based coolers. Low cooling capacity (theoretically wet-bulb temperature at 100% relative humidity), adding moisture to the product air and probable health issues due to the contaminated water droplets are the main shortcomings of direct evaporative air coolers. Although conventional indirect evaporative air cooler (which is direct evaporative cooler + a heat exchanger) overcomes some of the mentioned shortcomings (i.e. adding no moisture to the product air), the minimum achievable temperature would even be increased and remains as the main weakness of the indirect evaporative air coolers. Maisotsenko-cycle (M-cycle) based indirect evaporative cooler (IEC) overcomes all mentioned problems as it is able to provide lower air temperature (below the wet-bulb temperature towards the dew point temperature) without adding moisture to the product air and without further energy consumption. Besides, M-cycle cooler does not have any negative impact on environment and it does not have any potential health issue due to the probable contaminated water droplets. However, the research on M-cycle IEC is limited. No potential analytical model has been provided before for M-cycle IEC, and cumbersome timeconsuming numerical simulations have been employed for design and analysis purposes. Hence, this research aims to develop better understanding on the thermalexergetic behaviour of M-cycle cooler by developing new high-accurate quick analytical models for different working conditions. Experimental set-up is developed to validate the results of the programmed analytical models and then the models are employed to perform a comprehensive sensitivity analysis of the key operation and design parameters of the M-cycle IEC. Two high accurate quick solving analytical models are developed and presented for two main different working conditions of multi-stage Maisotsenkocycle based indirect evaporative coolers termed water-spray mechanism and wetsurface mechanism. The models are able to generate cooling characteristics of the cooler very quick (compared to the numerical solutions) and accurate. The models are also able to provide temperature/humidity distribution (as a function of the locations inside the cooler) in addition to the outlet characteristics. Thus, the models can be considered as a strong research and design tool for M-cycle coolers. The models are further expanded to analyse the exergetic characteristics of the M-cycle cooler as well. Although M-cycle IEC was first developed as the air conditioning system, other potential applications of M-cycle is proposed in this research as a novel air pre-cooling technology for gas turbine based power plants which suffer lower output power problem in summers (due to hot intake air temperature). The proposed system is based on a hybrid cycle of M-cycle and absorption chiller. The absorption chiller is powered by the released heat from the exhaust gas of the turbine, and the required water of M-cycle could be provided by the condensed water of the saturated air which make the system as an efficient air pre-cooling technology. This thesis is presented in the form of a collection of the published papers which are the results of research. These five papers have been chosen to best demonstrate the study of M-cycle based air coolers. Additional background information is also provided in order to establish the context and significance of this work.
Thesis (Ph.D.) -- University of Adelaide, School of Mechanical Engineering, 2021
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Book chapters on the topic "Maisotsenko"

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Caliskan, Hakan, Ibrahim Dincer, and Arif Hepbasli. "Assessment of Maisotsenko Combustion Turbine Cycle with Compressor Inlet Cooler." In Progress in Clean Energy, Volume 1, 41–55. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-16709-1_3.

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Mahmood, Muhammad H., Muhammad Sultan, and Takahiko Miyazaki. "Maisotsenko-Cycle Assisted Desiccant Dehumidification System Configurations for Agricultural Product Storage." In Energy-Efficient Systems for Agricultural Applications, 1–17. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-86394-4_1.

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Sultan, Muhammad, Hadeed Ashraf, Takahiko Miyazaki, Redmond R. Shamshiri, and Ibrahim A. Hameed. "Temperature and Humidity Control for the Next Generation Greenhouses: Overview of Desiccant and Evaporative Cooling Systems." In Next-Generation Greenhouses for Food Security. IntechOpen, 2021. http://dx.doi.org/10.5772/intechopen.97273.

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Temperature and humidity control are crucial in next generation greenhouses. Plants require optimum temperature/humidity and vapor pressure deficit conditions inside the greenhouse for optimum yield. In this regard, an air-conditioning system could provide the required conditions in harsh climatic regions. In this study, the authors have summarized their published work on different desiccant and evaporative cooling options for greenhouse air-conditioning. The direct, indirect, and Maisotsenko cycle evaporative cooling systems, and multi-stage evaporative cooling systems have been summarized in this study. Different desiccant materials i.e., silica-gels, activated carbons (powder and fiber), polymer sorbents, and metal organic frameworks have also been summarized in this study along with different desiccant air-conditioning options. However, different high-performance zeolites and molecular sieves are extensively studied in literature. The authors conclude that solar operated desiccant based evaporative cooling systems could be an alternate option for next generation greenhouse air-conditioning.
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Conference papers on the topic "Maisotsenko"

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Maisotsenko, Valeriy, and Ilya Reyzin. "The Maisotsenko Cycle for Electronics Cooling." In ASME 2005 Pacific Rim Technical Conference and Exhibition on Integration and Packaging of MEMS, NEMS, and Electronic Systems collocated with the ASME 2005 Heat Transfer Summer Conference. ASMEDC, 2005. http://dx.doi.org/10.1115/ipack2005-73283.

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The Maisotsenko Cycle (M-Cycle) combines heat exchange and evaporative cooling [1–3] in an effective indirect evaporative cooling process resulting in product flow temperature approaching incoming air dew point (not wet bulb) temperature. Thermodynamically, the M-Cycle is based on air precooling before passing through the heat rejection water evaporating area, so the difference between the enthalpy of the air at its dew point temperature and the same air saturated at a higher temperature is used to provide cooling capacity to reject the heat, for example from the electronics. Today Delphi Corp and Coolerado Inc. are working on producing M-Cycle based heat- and mass exchangers for the Coolerado Coolers™ used in air conditioning. Other market applications, including electronics cooling, are being considered as well. A broad range of the cooling capacity (for example, from 10 W to 50 kW and more) could be obtained from the coolers utilizing M-Cycle. Due to superior thermodynamic process, M-Cycle based air coolers have a very high Energy Efficiency Ratio (EER). As per National Renewable Energy Laboratory (NREL), the average cooling capacity of Coolerado Coolers™ have EER more than 45; relatively to EER equal 13 for the best conventional air coolers. The M-cycle is much more efficient than any other heat rejection/recovery cycle, and the Coolerado Cooler™, as a single air cooling device has better specific characteristics (cooling capacity, air pressure drop, power consumption, etc.) than any existing coolers. Unlike traditional vapor compression, absorption, or thermoelectric refrigeration systems, where increase of air inlet temperature dramatically reduces cooling capacity, the M-Cycle based unit cooling capacity goes up with air inlet temperature rise. M-cycle based device similar to Coolerado Cooler™ can also cool any fluid to the temperature approaching the dew point temperature of incoming air without using compressor and refrigerant. That can revolutionize the electronics cooling market. The Coolerado Cooler was recognized by the prestigious R&D 100 Awards program as one of 2004’s most technologically significant products introduced to the world.
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Jenkins, P. E., M. Cerza, and Mohammad M. Al Saaid. "Analysis of Using the M-Cycle Regenerative-Humidification Process on a Gas Turbine." In ASME Turbo Expo 2014: Turbine Technical Conference and Exposition. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/gt2014-25178.

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This investigation focused on the analysis of using the Maisotsenko Cycle (M-Cycle) to improve the efficiency of a gas turbine engine. By combining the Maisotsenko Cycle (M-Cycle) with an open Brayton cycle, a new cycle, is known as the Maisotsenko Combustion Turbine Cycle (MCTC), was formed. The MCTC used an Indirect Evaporative Air Cooler as a saturator with a gas turbine engine. The saturator was applied on the side of the turbine exhaust (M-Cycle#2) in the analysis. The analysis included calculations and the development of an Engineering Equation Solver (EES) code to model the MCTC system performance. The resulting performance curves were graphed to show the effects of several parameters on the thermal efficiency and net power output of the gas turbine engine. The models were also compared with actual experimental test results from a gas turbine engine. Conclusions and discussions of results are also given.
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Gillan, Leland, and Valeriy Maisotsenko. "Maisotsenko Open Cycle Used for Gas Turbine Power Generation." In ASME Turbo Expo 2003, collocated with the 2003 International Joint Power Generation Conference. ASMEDC, 2003. http://dx.doi.org/10.1115/gt2003-38080.

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The Maisotsenko Open Cycle combines the thermodynamic processes of heat exchange and evaporative cooling in a unique indirect evaporative cooler resulting in product temperatures that approach the dew point temperature, (not the wet bulb temperature) of the working gas. It is an open thermodynamic cycle utilizing several thermodynamic processes that cools a product fluid with a liquid evaporating into a gas, generally water evaporating into air from the atmosphere and returns it to the atmosphere. It is a new cycle as no other cycle can be diagramed in the same way on the psychrometric chart of a gas. In a gas turbine, the gas is air and evaporate is water. An atmospheric pressure heat and mass exchanger operating with the Maisotsenko Cycle can be used to cool compressor inlet air below the wet bulb temperature. In a high-pressure heat and mass exchanger the cycle can create a compressed air saturator using heat from the turbine exhaust gases and also cools water for heat recovery in a compressor inter-cooler. The same saturator will humidify and/or superheat the compressed air before entering a combustor to the amount desired. From a practical stand point the limit of humidification of the compressed air is the amount of heat available at a temperature above its dew point temperature from the exhaust gas and/or intercompressor coolers. The amount of superheating or humidifying of the compressed air is easily controlled and changed during operation allowing added power, or greater efficiency, (60% overall thermal efficiency) quickly and easily. The equipment uses existing shell and tube heat exchanger or plate heat exchangers technologies. There are many other benefits ranging from lower NOx to greatly reduced equipment cost compared to any other power cycle enhancement systems.
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Morosuk, T., G. Tsatsaronis, V. Maisotsenko, and A. Kozlov. "Exergetic Analysis of a Maisotsenko-Process-Enhanced Cooling Tower." In ASME 2012 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2012. http://dx.doi.org/10.1115/imece2012-87581.

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The Maisotsenko-process (M-process or M-cycle) is a complex process associated with humid air. Heat transfer and evaporative cooling occur in a unique indirect evaporative cooler resulting in product temperatures that approach the dew point temperature. This process utilizes the enthalpy difference between air at its dew point temperature, and air saturated at a higher temperature. This enthalpy difference is used to reject heat from the air stream with the high temperature. The different applications of the M-process contribute to effective energy savings. The M-process technology was realized initially in the year 1984. By enhancing cooling towers with the M-process it is possible to (a) cool water to dew point temperature; (b) reduce pressure drop and required fan power, and (c) modify existing cooling towers to substantially decrease cooled water temperature. An exergetic analysis identifies the real thermodynamic inefficiencies and the potential of improvement for the M-process. This paper demonstrates the detailed exergetic analysis of the M-process with separate consideration of the thermal and mechanical exergies (as two parts of the physical exergy) and the chemical exergy.
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Worek, William M., Mark Khinkis, David Kalensky, and Valeriy Maisotsenko. "Integrated Desiccant–Indirect Evaporative Cooling System Utilizing the Maisotsenko Cycle." In ASME 2012 Heat Transfer Summer Conference collocated with the ASME 2012 Fluids Engineering Division Summer Meeting and the ASME 2012 10th International Conference on Nanochannels, Microchannels, and M. ASME, 2012. http://dx.doi.org/10.1115/ht2012-58039.

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Kashif, Muhammad, Takahiko Miyazaki, Muhammad Sultan, Zahid Mahmood Khan, and Muhammad H. Mahmood. "Investigation of Maisotsenko Cycle (M-cycle) Air-Conditioning System for Multan(Pakistan)." In 2017 International Conference on Energy Conservation and Efficiency (ICECE). IEEE, 2017. http://dx.doi.org/10.1109/ece.2017.8248823.

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Keeley-LeClaire, Théo, Eric Teitelbaum, Suin Shim, Michael Bozlar, Howard A. Stone, and Forrest Meggers. "Extracting Radiant Cooling From Building Exhaust Air Using the Maisotsenko Cycle Principle." In 7th International Building Physics Conference. Syracuse, New York: International Association of Building Physics (IABP), 2018. http://dx.doi.org/10.14305/ibpc.2018.ec-1.04.

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El-Damaty, Waleed, and Mohamed Gadalla. "Exergoeconomic Analysis of Intercooled, Reheated and Recuperated Gas Turbine Cycles With Air Film Blade Cooling." In ASME 2018 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/imece2018-88483.

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For many years, thermodynamic analysis was considered to be the principal tool that is used to predict the performance of a power plant. Recently, the environmental effect and the cost of power plants have been considered as important as the thermodynamic performance in design of power plants. Thus, researchers started to adopt a relevantly new approach called the exergoeconomic analysis which combines the thermodynamic technicalities as well as the economic analysis to design power plants. The exergoeconomic analysis provides crucial information that helps in foreseeing not only the thermodynamic performance but also all economic variables related to power plants. Increasing the efficiency of the power plant has been the major concern in power plants. Thus, the global approach of reaching high turbine inlet temperatures to improve the efficiency of power plants, has exposed the turbine blades to some serious problems. Thereby, cooling the turbine blades has become an important aspect that needs to be taken care of during the power plant operation. In this paper, a cooled gas turbine with intercooler, recuperator and reheater is adopted where it is incorporated with a cooling system. An exergoeconomic analysis accompanied by a sensitivity analysis was performed on the gas turbine cycle to determine the exergo-economic factor and the relative cost difference in addition to study the effect of different variables on the gas turbine thermal and exergetic efficiency, net specific work and the total cost rate. Average cost theory approach was adopted from various thermo-economic methodologies to determine the cost calculation during this investigation. The results showed a reduction in the total coolant mass flow rate in the base case where no cooling systems are integrated from 3.349 kg/s to 3.01 kg/s, 2.995 kg/s and 2.977 kg/s in the case of integrating the cooling systems triple stage Maisotsenko desiccant, triple stage precooling Maisotsenko desiccant and triple stage extra cooling Maisotsenko desiccant, respectively. Accordingly, the thermal efficiency has increased to reach 52.69%, 52.89% and 53.12% by the integration of TS-MD, TS-PMD and TS-EMD cooling systems, respectively.
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Tariq, Rasikh, and Nadeem Ahmed Sheikh. "Maisotsenko cycle based counter and cross flow heat and mass exchanger: A computational study." In 2017 International Conference on Energy Conservation and Efficiency (ICECE). IEEE, 2017. http://dx.doi.org/10.1109/ece.2017.8248827.

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El-Damaty, Waleed, and Mohamed Gadalla. "Analysis of Integrated Cooling Systems for Gas Turbine Power Plants." In ASME 2017 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2017. http://dx.doi.org/10.1115/imece2017-72378.

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With the current increase in electricity consumption and energy demand, most of the research focus is shifted towards the means of increasing the power plants efficiency in order to produce more electricity by using as less fuel as possible. Gas turbine power plants specifically have been under the study in the recent years due to its feasibility, low capital cost, simple design, compact size and higher efficiency compared to steam turbine power plants. There are a lot of operating conditions that affect the performance of the gas turbine which includes the inlet air climatic conditions, mass flow rate and the turbine inlet temperature. Many improvements and enhancements became applicable through the advancement in the material and cooling technologies. Cooling techniques could be used to cool the inlet air entering the compressor by utilizing evaporative coolers and mechanical chillers, and to cool the turbine blades in order to avoid a decline in the life of turbine blades due to unwanted exposure to thermal stresses and oxidation. Internal convection cooling, film cooling and transpiration cooling are the three main techniques that can be used in the process of turbine blades cooling. The main objective of this proposal is to improve the durability and performance of gas turbine power plants by proposing the usage of integrated system of solid desiccant with Maisotsenko cooler in the turbine blade cooling and inlet air cooling processes. Four configurations were presented and the results were an increase in the efficiency of the gas turbine cycle for all the cases specially the two stage Maisotsenko desiccant cooling system where the efficiency increased from 33.33% to 34.17% as well as maintaining the turbine inlet temperature at a desired level of 1500°K.
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