Your search keyword '"Evaporative cooling"' showing total 2,588 results

1. Parametric Study of Transpiration Cooling Using Oxides for Sharp Hypersonic Leading Edges

Author

Ko, Danny D, Mannion, Anthony, Zhong, Xiaolin, and Ju, Yongho Sungtaek

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Aerospace Engineering, Boundary Layers, Computational Fluid Dynamics, Thermal Control and Protection, Mass Flow Rate, Thermochemistry and Chemical Kinetics, Nonequilibrium Flows, Transpiration Cooling, Hypersonic Flight, Evaporative Cooling, Vapor-Liquid Equilibrium, Mechanical Engineering, Interdisciplinary Engineering, Mechanical Engineering & Transports, Fluid mechanics and thermal engineering

Abstract

Recent escalating interest in the development of highly maneuverable hypersonic vehicles demands sharp leading edges. However, sharp leading edges induce severe aerothermal conditions where conventional passive or ablative thermal protection systems fail to protect the leading edge. Here, we numerically demonstrate transpiration cooling employing oxide coolants as a new alternative system to thermally protect sharp leading edges. We parametrically characterize the performance of transpiration cooling for various coolant properties, flight conditions, and leading edge radii using a semi-analytic boundary-layer model validated with third-order direct numerical simulations. We further utilize direct numerical simulation to examine the impact of the thermochemical behavior of oxide vapors with the external hypersonic flow on transpiration cooling. Our findings do not readily align with an optimal set of material properties for transpiration cooling. Instead, certain coolant properties are more appropriate for various flight conditions and leading edge sizes. Our results also demonstrate that the thermochemical interactions between the oxide vapors and the external hypersonic flow have a negligible impact on the performance of transpiration cooling. Our study provides numerical frameworks to evaluate the performance of transpiration cooling and optimize the coolant properties for various flight conditions to protect sharp leading edges, which are paramount across hypersonic applications.

Published

2024

2. Development of Innovative Thermoplastic Foam Materials Using Two Additive Manufacturing Technologies for Application in Evaporative Cooling Systems.

Author

Castillo-González, Jesús, Comino, Francisco, Caruana, Roberta, Guilizzoni, Manfredo, Conrat, Paula, Ruiz de Adana, Manuel, and Navas-Martos, Francisco J.

Subjects

*FOAMED materials, *AIR conditioning, *BLOWING agents, *COOLING of water, *MANUFACTURING processes, *FOAM, *EVAPORATIVE cooling

Abstract

Evaporative cooling systems have emerged as low-energy consumption alternatives to traditional vapor compression systems for building air conditioning. This study explored the feasibility of utilizing polymeric foamed materials produced through additive manufacturing as wetting materials in evaporative cooling systems. Specifically, two different commercial polylactic acid filaments, each containing a percentage of a chemical blowing agent, were studied. Experiments were designed to evaluate the influence of critical process parameters (line width, flow rate, speed, and layer height) on the performance of the resulting foamed materials in terms of evaporative cooling by conducting water absorption, capillarity, porosity, and wettability tests. Considering that high water absorption, capillarity, and porosity, coupled with an intermediate contact angle, are advantageous for evaporative cooling effectiveness, a low flow rate was found to be the most important parameter to improve these properties' values. The results showed that the appropriate combination of polymer and process parameters allowed the production of foamed polymer-based materials processed by additive manufacturing technology with optimal performance. [ABSTRACT FROM AUTHOR]

Published

2024

3. Innovative Approaches to Windcatcher Design: A Review on Balancing Tradition Sustainability and Modern Technologies for Enhanced Performance.

Author

Sirror, Hala

Subjects

*COMPUTATIONAL fluid dynamics, *INDOOR air quality, *EVAPORATIVE cooling, *MODERN architecture, *NATURAL ventilation, SOLAR chimneys

Abstract

This review investigates the role of windcatchers in modern architecture, exploring their optimization through the integration of traditional designs with contemporary technologies. Historically utilized in hot and arid climates for passive cooling, windcatchers offer energy-efficient solutions for improving indoor air quality (IAQ). This study examines the sustainability of traditional windcatcher designs and their relevance in preserving heritage structures. Using advanced tools like computational fluid dynamics (CFD) modeling, modern adaptations of windcatchers can be optimized for urban environments. This review also explores hybrid systems, combining windcatchers with solar chimneys, evaporative cooling, or heat pumps, to enhance performance in low-wind conditions by balancing natural and mechanical ventilation. Additionally, it addresses the role of artificial intelligence (AI) in heritage planning, facilitating the design and integration of windcatchers into contemporary architecture. The findings suggest that windcatchers, combined with modern design strategies and hybrid systems, continue to be viable and sustainable solutions for passive cooling, contributing to energy-efficient and climate-resilient buildings across different environmental and urban contexts. [ABSTRACT FROM AUTHOR]

Published

2024

4. Current Status, Challenges, and Opportunities of Evaporative Cooling for Building Indoor Thermal Comfort Using Water as a Refrigerant: A Review.

Author

Ishugah, Tom Fred, Kiplagat, Jeremiah, Madete, June, Musango, Jones, and Ahmed, Mahmoud

Subjects

*OZONE layer depletion, *EVAPORATIVE cooling, *THERMAL comfort, *ELECTRICAL energy, *ENERGY consumption

Abstract

This study presents a review of advances made in evaporative cooling technologies, emphasizing their application in indoor thermal comfort. It highlights that the rising demand for cooling has primarily been met by conventional mechanical vapor compression systems. However, these systems face two significant issues: high electrical energy requirements and the use of refrigerants like chlorofluorocarbons (CFCs) and hydrofluorocarbons (HFCs), which contribute to ozone layer depletion and global warming. The findings indicate that evaporative cooling technology is a promising alternative due to its low energy demand and potential to integrate renewable energy, therefore enhancing its environmental benefits. The study also details various evaporative cooling technologies, recent improvements in their performance, practical applications, challenges, and opportunities for providing indoor thermal comfort. [ABSTRACT FROM AUTHOR]

Published

2024

5. Performance and Applicability Analysis of Indirect Evaporative Cooling Units in Data Centers Across Various Humidity Regions.

Author

Wei, Qian, Lu, Jun, Xia, Xiaoping, Zhang, Bin, Ying, Xiang, and Li, Leihong

Subjects

EVAPORATIVE cooling, CITIES & towns, HEAT transfer, OPERATING costs, SIMULATION software, SERVER farms (Computer network management)

Abstract

Indirect evaporative cooling (IEC), which utilizes natural cooling sources, is an advanced and promising technology to reduce the energy consumption of cooling systems in a data center (DC). This study presents a model of an IEC air-conditioning unit in a DC using TRNSYS simulation software validated using actual operational data to investigate the adaptability of IEC units in data centers located in regions with varying humidity levels, providing a reference for their application and promotion in DCs. Based on this premise, the authors analyzed the meteorological characteristics of Urumqi (a dry region), Beijing (a region with medium humidity), and Shanghai (a region with high humidity), which are representative cities in different humidity zones. The analysis identified the annual operating hours of the unit's three operation modes, including fresh-air indirect heat transfer (FAIHT), IEC, and hybrid. Simultaneously, the authors conducted a simulation of the unit's yearly energy consumption and determined time change curves for annual energy consumption, hourly coefficient of performance (COP) throughout the year, and mechanical cooling in various locations. The results indicate that IEC air-conditioning systems are highly effective in promoting the efficiency of data centers in various humidity regions. Dry locations demonstrate the greatest adaptability, followed by regions with medium humidity and, finally, regions with high humidity. The findings indicate that IEC units provide significant energy efficiency and cost-effectiveness when deployed in typical urban DCs across various humidity zones in China. The average annual power-usage effectiveness (PUE) of each city's DC utilizing the unit is less than 1.3, and the unit's annual operational cost savings exceed 30%. [ABSTRACT FROM AUTHOR]

Published

2024

6. Improvement of thermal environment in the outdoor atrium by employing the spray system.

Author

Ding, Nan, Su, Jingyu, Pang, Feng, and Meng, Xi

Subjects

*ENERGY consumption of buildings, *EVAPORATIVE cooling, *METAL spraying, *ATRIUMS (Architecture), *SPRAY cooling

Abstract

Outdoor atriums have recently been applied with increasing frequency for natural illumination, but they produce a harsh thermal environment easily in summer. Moreover, overheating of the outdoor atrium necessitates air-conditioning to moderate indoor thermal comfort. Simultaneously, the substantial heat emissions from air-conditioning outdoor units worsen the outdoor thermal environment, creating a vicious cycle. Traditional passive evaporative methods involving water and greenery, while capable of regulating the thermal environment, suffer from low evaporative efficiency and pose significant challenges. To improve thermal environment in outdoor atriums, the spray system was employed due to its high cooling efficiency, especially in open or semi-open spaces. In this study, a comparative experiment was conducted to evaluate the effectiveness of using a spray system for evaporative cooling in open outdoor spaces. Furthermore, employing high-efficiency evaporative cooling through spraying to disrupt the vicious cycle of indoor and outdoor thermal environments. The dual goals include regulating indoor and outdoor thermal conditions while also mitigating the local heat island effect. Temperature and humidity distribution within the atrium and adjacent hallways were monitored, along with the impact on air-conditioning operation consumption in neighboring offices. Results showed that the spray system significantly improved the thermal environment in the outdoor atrium, reducing the average and peak air temperatures by 0.94–2.83 °C and 2.92–5.21 °C, respectively. It also resulted in a drop in the average temperature by 0.56–1.62 °C and the peak temperature by 2.31–3.25 °C in adjacent hallways. This effectively eased the issue of overheating in these areas while raising the comfort level in adjacent office spaces. The predicted mean vote decreased from 1.46 to 0.87, indicating a significant improvement in thermal environment in neighboring offices. Furthermore, the daily energy consumption was reduced by 10.6–12.4% in neighboring offices. This study provided the valuable guidance for improving thermal environments within outdoor atrium. [ABSTRACT FROM AUTHOR]

Published

2024

7. 岭南庭园的现代空间构型 ——以广州市文化馆广府园创作为例.

Author

邓心宇, 倪 阳, and 原 玮

Subjects

GARDEN structures, EVAPORATIVE cooling, LANDSCAPE gardening, MODERN architecture, FLEXIBLE structures, GARDEN design, LANDSCAPE assessment

Abstract

Copyright of South Architecture / Nanfang Jianzhu is the property of South Architecture Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

8. Enclosed Barn Conditioning System: A Comparison Between Traditional and Indirect Evaporative Cooling.

Author

Puglia, Marco, Mirandola, Saverio, Cossu, Michele, Morselli, Nicolò, Allesina, Giulio, Pedrazzi, Simone, Muscio, Alberto, and Tartarini, Paolo

Subjects

EVAPORATIVE cooling, AIR conditioning, AGRICULTURE, SOLAR temperature, THERMODYNAMIC cycles

Abstract

Enclosed barns can be an effective farming system, providing proper animal welfare conditions to the cattle, with also positive effect on dairy productivity. On the other hand, the air conditioning process can be extremely energy-intensive and expensive, especially during summer months. This is not only due to the high air temperature and the solar irradiance, but also because of the metabolic heat produced by the cattle. The climatic condition considered for this study is the temperate-no dry season-hot summer, typical of northern Italy, where more than 80% of Italian milk is produced. Two conditioning strategies have been evaluated: the traditional chiller with a reverse thermodynamic cycle and an indirect evaporative cooling system based on the Maisotsenko cycle. The two systems were analytically compared considering an enclosed barn with a population of 500 lactating cows, highlighting the pros and cons of each systems. Traditional reverse cycle is capable of consistently reaching the chosen thermo-hygrometric conditions, ensuring the highest dairy productivity. However, this comes at the expense of significant energy expenditure. On the other hand, indirect evaporative cooling is not always able to reach the planned conditions, but it guarantees a significantly lower energy expenditure. [ABSTRACT FROM AUTHOR]

Published

2024

9. A system for efficient and sustainable cogeneration of water and electricity: Temperature difference induced by photothermal conversion and evaporative cooling.

Author

Wu, Fucai, Hu, Chunyan, Zhu, Zhijia, Zheng, Jian, Huang, Zhangmi, and Liu, Baojiang

Subjects

*EVAPORATIVE cooling, *CLEAN energy, *EVAPORATIVE power, *HEAT sinks, *POWER resources, *THERMOELECTRIC generators

Abstract

[Display omitted] • A novel cogeneration system based on thermoelectricity and evaporative cooling. • The highly hydrated polymer network reduces the enthalpy of evaporation. • The synergistic mechanism between evaporation and thermoelectricity is elucidated. • Multifunctional applications for wastewater treatment and power supply. Solar energy, with its sustainable properties, has garnered considerable attention for its potential to produce green electricity and clean water. This paper proposes a multistage energy transfer co-generation system (MWCNTs-covered thermoelectric module with aerogel and cooler, AC-CTEM) combining power generation and evaporative cooling. On the light-absorbing surface, the hot side of a thermoelectric module is covered with a hydrophobic coating made of PDMS and MWCNT. The cold side transfers heat to the evaporation zone using a heat sink. Aerogel evaporators are cross-linked with chitosan and polyurethane, which reduces the enthalpy of evaporation and facilitates efficient interfacial evaporation to remove heat and return it to refrigeration. Additionally, with the addition of Fresnel lenses and wind energy to the enhancement device, the system achieved an evaporation rate of 3.445 kg m−2 h−1 and an open-circuit voltage of 201.12 mV under 1 kW m−2 solar irradiation. The AC-CTEM system also demonstrated long-term stability and effectiveness in treating various types of non-potable water. Furthermore, we demonstrated the practical utility of the system by successfully cultivating grass seeds and powering electronic equipment. The AC-CTEM system exemplifies a practical energy-saving approach for the development of highly efficient co-generation systems. [ABSTRACT FROM AUTHOR]

Published

2025

10. Experimental study on the performance of the vertical shell-tube indirect evaporative cooler with inner grooved tubes

Author

Wen-He Zhou and Ang Li

Subjects

Evaporative cooling, Vertical tube indirect evaporative cooler, Cooling efficiency, Experimental test, Medicine, Science

Abstract

Abstract The vertical tube indirect evaporative cooler (VTIEC) could be preferred one to air-conditioning buildings if its water film quality could be improved. This paper proposed a new VTIEC with inner grooved tubes to improve the water film quality and obtained its performance by experimental method. The results indicated that inner grooved tubes have positive effects on the water film and performance of the new VTIEC. A low working air enthalpy at inlet can significantly improve the total cooling capacity from evaporation, and then VTIEC performance. In this paper conditions, the velocity ratio of 1.52 of the produced air to the working air is better one condition compared to 1.01 and 2.28. The produced air velocity is positive effect on the cooling capacity per unit area until the produced air velocity of about 4.05 m/s and is negative effect on COP. The maximum unit cooling capacity, wet-bulb efficiency and COP are 307.74W/m2, 81.7% and 44.97.The results will promote the application of the new VTIEC.

Published

2024

11. A review of recent studies of both heat pipe and evaporative cooling in passive heat recovery

Author

Mohsin Alsayah Ahmed, Faraj Johain J., and Eidan Adel A.

Subjects

heat pipe heat exchanger, evaporative cooling, passive heat recovery, thermosyphon heat pipe, wick heat pipe heat exchanger, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The present article aims to cover the most recent advancements in heat recovery technology in heating, ventilation, and air conditioning and identify areas that have not been thoroughly investigated. Extensive information is available on heat recovery technologies and exchangers in central systems. Furthermore, the research examines both direct and indirect evaporative cooling approaches. The literature discusses how the heat recovery process is influenced by climatic conditions, air flow rate, and the type of heat exchanger employed. The latest studies contributing to enhancing the performance of heat exchangers were also considered. The results of the study indicate that recent years have witnessed great interest from researchers in the field of lost energy recovery; the experimental, theoretical, and numerical studies have focused on studies of the influencing factors that contribute to improving the performance of the energy recovery process. The current project involves doing an analytical and comparative analysis of the newest research about enhancing the efficiency of thermosyphon heat exchangers and various forms of evaporative cooling.

Published

2024

12. An arctic breeding songbird overheats during intense activity even at low air temperatures

Author

Ryan S. O’Connor, Oliver P. Love, Lyette Régimbald, Audrey Le Pogam, Alexander R. Gerson, Kyle H. Elliott, Anna L. Hargreaves, and François Vézina

Subjects

Arctic breeding species, Climate change, Evaporative cooling, Flight, Heat tolerance, Hyperthermia, Medicine, Science

Abstract

Abstract Birds maintain some of the highest body temperatures among endothermic animals. Often deemed a selective advantage for heat tolerance, high body temperatures also limits birds’ thermal safety margin before reaching lethal levels. Recent modelling suggests that sustained effort in Arctic birds might be restricted at mild air temperatures, which may require reductions in activity to avoid overheating, with expected negative impacts on reproductive performance. We measured within-individual changes in body temperature in calm birds and then in response to an experimental increase in activity in an outdoor captive population of Arctic, cold-specialised snow buntings (Plectrophenax nivalis), exposed to naturally varying air temperatures (− 15 to 36 °C). Calm buntings exhibited a modal body temperature range from 39.9 to 42.6 °C. However, we detected a significant increase in body temperature within minutes of shifting calm birds to active flight, with strong evidence for a positive effect of air temperature on body temperature (slope = 0.04 °C/ °C). Importantly, by an ambient temperature of 9 °C, flying buntings were already generating body temperatures ≥ 45 °C, approaching the upper thermal limits of organismal performance (45–47 °C). With known limited evaporative heat dissipation capacities in these birds, our results support the recent prediction that free-living buntings operating at maximal sustainable rates will increasingly need to rely on behavioural thermoregulatory strategies to regulate body temperature, to the detriment of nestling growth and survival.

Published

2024

13. Critical assessment of water enthalpy characterization through dark environment evaporation.

Author

Caratenuto, Andrew and Yi Zheng

Subjects

*HEATS of vaporization, *EVAPORATIVE cooling, *DIFFERENTIAL scanning calorimetry, *SURFACE area, *ENTHALPY

Abstract

Comparative evaporation rate testing in a dark environment, commonly used to characterize a reduced vaporization enthalpy in interfacial solar evaporators, requires the assumption of equal energy input between cases. However, this assumption is not generally valid, leading to misleading characterization results. Interfacial evaporators yield larger evaporation rates in dark conditions due to enlarged liquid-vapor surface areas, resulting in increased evaporative cooling and larger environmental temperature differentials. Theoretical and experimental evidence is provided, which shows that these temperature differences invalidate the equal energy input assumption. The results indicate that differences in evaporation rates correspond to energy input variations, without requiring enthalpy to be reduced below theoretical values. These findings offer alternative explanations for previous claims of reduced vaporization enthalpy and contradict enthalpy-related conclusions drawn from differential scanning calorimetry. We conclude that postulating a reduced vaporization enthalpy using the dark environment method is inaccurate and that re-evaluation of vaporization enthalpy reduction is required. [ABSTRACT FROM AUTHOR]

Published

2024

14. Experimental study on the performance of the vertical shell-tube indirect evaporative cooler with inner grooved tubes.

Author

Zhou, Wen-He and Li, Ang

Abstract

The vertical tube indirect evaporative cooler (VTIEC) could be preferred one to air-conditioning buildings if its water film quality could be improved. This paper proposed a new VTIEC with inner grooved tubes to improve the water film quality and obtained its performance by experimental method. The results indicated that inner grooved tubes have positive effects on the water film and performance of the new VTIEC. A low working air enthalpy at inlet can significantly improve the total cooling capacity from evaporation, and then VTIEC performance. In this paper conditions, the velocity ratio of 1.52 of the produced air to the working air is better one condition compared to 1.01 and 2.28. The produced air velocity is positive effect on the cooling capacity per unit area until the produced air velocity of about 4.05 m/s and is negative effect on COP. The maximum unit cooling capacity, wet-bulb efficiency and COP are 307.74W/m2, 81.7% and 44.97.The results will promote the application of the new VTIEC. [ABSTRACT FROM AUTHOR]

Published

2024

15. 太阳能光伏蒸发冷却通风空腔的实验研究.

Author

刘雅慧, 闫伟超, 崔 鑫, 杨传钧, 张 煜, and 金立文

Subjects

*PHOTOVOLTAIC power generation, *ELECTRIC power, *EVAPORATIVE cooling, *PHOTOVOLTAIC cells, *BUILDING envelopes, *BUILDING-integrated photovoltaic systems

Abstract

A solution for solar photovoltaic evaporative cooling and ventilation cavities was proposed to address the bottleneck problems faced by photovoltaic modules in the application of building envelope structures, such as increased working temperature and reduced power generation efficiency caused by photovoltaic module heat generation, as well as their potential impact on building cooling and heating loads. This solution involved installing photovoltaic cells on the surface of the building envelope and keeping a certain distance from the building wall to form a ventilation cavity. At the same time, an evaporative cooling device was arranged on one side of the back panel of the photovoltaic cells. By setting up an outdoor test platform and conducting controlled experiments, the impact of the evaporative cooling effect on the thermal and moisture performance of each component of the solar photovoltaic ventilation cavity and the changes in its electrical properties were studied. Experimental results show that the ventilation cavity with evaporative cooling has a significant cooling effect on the photovoltaic front, photovoltaic backplane, cavity backplane and cavity interior. Compared with the ventilation cavity without evaporative cooling, the average temperatures of these parts are reduced by approximately 3. 7, 7. 6, 4. 5, and 3. 9 ℃, respectively, with the percentage reductions being 10. 2%, 20. 8%, 13. 6%, and 11. 9% respectively. At the same time, the all-day average electrical power of the ventilation cavity with evaporative cooling is improved by approximately 15. 9% compared to the ventilation cavity without evaporative cooling. These experimental data verify the effectiveness of evaporative cooling technology in reducing the operating temperature of photovoltaic modules and improving the power generation efficiency of photovoltaic modules, and provide data support for the further application of photovoltaic building integration. [ABSTRACT FROM AUTHOR]

Published

2024

16. Detection Dogs Working in Hot Climates: The Influence on Thermoregulation and Fecal Consistency.

Author

Slotta-Bachmayr, Leopold, Oyugi, Antony, Mutoro, Noreen, Burak, Mary, and Wykstra, Mary

Subjects

*DETECTOR dogs, *WORKING dogs, *EVAPORATIVE cooling, *COOLDOWN, *HOT working, *BODY temperature, *DOGS, *HEAT stroke

Abstract

Simple Summary: The performance of search dogs is limited by their ability to cool down their body because the main cooling ability—panting—contradicts sniffing. We investigated the effect of hot environments on the general body condition of detection dogs working in Kenya. These dogs search for cheetah scats in their arid and hot habitat, where it is especially challenging for them to work. After a working day in the fields, these dogs showed a softer stool, which means a higher stress level, and elevated body temperature during the routine check-in the next morning. Our results showed that the use of search dogs in hot conditions is possible and useful but requires increased attention to prevent heat-related illness. Body temperature is an important physiological parameter that influences the performance of working dogs. The main cooling mechanism in dogs is panting to support evaporative cooling, which reduces the dog's ability to detect scents. In this study, we investigated the general body condition of four detection dogs searching for cheetah scats in a hot environment in northern Kenya. We evaluated the effect on the dog's body temperature post-work in the short term (within hours) and long term (12–24 h). The fecal consistency and mean body temperature of the investigated dogs differed significantly between individuals but not between locations (moderate Nairobi and hot Samburu). On the morning after fieldwork, the dogs showed a significantly increased body temperature (37.9 ± 0.8 °C) compared to resting days (37.5 ± 2.2 °C). In the short term, on the first day of fieldwork, the dog's body temperature (n = 2) decreased after 10 min of rest. On the second consecutive day of fieldwork, the 10-min recovery period was too short, and the body temperature did not decrease significantly. Our data showed that the use of detection dogs in hot conditions is possible and useful but requires increased attention to prevent heat-related illness. [ABSTRACT FROM AUTHOR]

Published

2024

17. Performance prediction for modified design of dew point evaporative cooler for air cooling.

Author

Patunkar, Prashant and Dingare, Sunil

Subjects

*PLATE heat exchangers, *DEW point, *HEAT exchangers, *PRESSURE drop (Fluid dynamics), *AIR conditioning

Abstract

Traditional air conditioning systems use lot of energy; thus, dew point evaporative air-cooling systems could be a good alternative. Many experts studied the impact of constructional and operating characteristics on Maisotsenko cycle (M-cycle) to improve its performance. Cooler performance is influenced by the heat exchanger. Heat exchangers were constructed using flat and corrugated plates. The present study proposes the use of geometrically modified trapezoidal corrugated plates for counter flow heat exchanger, which consists of alternate air and water flow passageways. The numerical model is developed to predict the performance under variety of inlet air conditions and channel dimensions. In the standard range of incoming air properties such as relative humidity, the performance parameters assist in making cooler recommendations. Comparison and validation of simulation results are done with published experimental data for corrugated and trapezoidal corrugated plate heat exchangers. For trapezoidal corrugated plates, simulation findings revealed 10% increase in wet bulb efficiency and 7% increase in dew point efficiency over corrugated plates. The efficiency of wet bulb and dew point decreases as channel gap widens. For trapezoidal corrugated plates, the larger channel spacing minimises pressure drop. [ABSTRACT FROM AUTHOR]

Published

2024

18. Global and regional hydrological impacts of global forest expansion.

Author

King, James A., Weber, James, Lawrence, Peter, Roe, Stephanie, Swann, Abigail L. S., and Val Martin, Maria

Subjects

CLIMATE change mitigation, CLIMATE change, FORESTS & forestry, EVAPORATIVE cooling, ATMOSPHERIC circulation, SHRUBLANDS, AFFORESTATION

Abstract

Large-scale reforestation, afforestation, and forest restoration schemes have gained global support as climate change mitigation strategies due to their significant carbon dioxide removal (CDR) potential. However, there has been limited research into the unintended consequences of forestation from a biophysical perspective. In the Community Earth System Model version 2 (CESM2), we apply a global forestation scenario, within a Paris Agreement-compatible warming scenario, to investigate the land surface and hydroclimate response. Compared to a control scenario where land use is fixed to present-day levels, the forestation scenario is up to 2 °C cooler at low latitudes by 2100, driven by a 10 % increase in evaporative cooling in forested areas. However, afforested areas where grassland or shrubland are replaced lead to a doubling of plant water demand in some tropical regions, causing significant decreases in soil moisture (∼ 5 % globally, 5 %–10 % regionally) and water availability (∼ 10 % globally, 10 %–15 % regionally) in regions with increased forest cover. While there are some increases in low cloud and seasonal precipitation over the expanded tropical forests, with enhanced negative cloud radiative forcing, the impacts on large-scale precipitation and atmospheric circulation are limited. This contrasts with the precipitation response to simulated large-scale deforestation found in previous studies. The forestation scenario demonstrates local cooling benefits without major disruption to global hydrodynamics beyond those already projected to result from climate change, in addition to the cooling associated with CDR. However, the water demands of extensive forestation, especially afforestation, have implications for its viability, given the uncertainty in future precipitation changes. [ABSTRACT FROM AUTHOR]

Published

2024

19. Exploring the Impacts of System Geometry on Heat Transfer Efficiency in Coil-and-Tube Heat Exchangers.

Author

Saleem, Jaafar, Chahrour, Khaled M.N., and Habeeb, Laith Jaafer

Subjects

*AIR conditioning efficiency, *HEAT exchanger efficiency, *HEAT exchangers, *COMPUTATIONAL fluid dynamics, *EVAPORATIVE cooling

Abstract

The purpose of this research is to investigate in depth the effect of system geometry on the performance of coil-and-tube heat exchangers. This work investigates the use of direct evaporative cooling (DEC) to improve the efficiency of air conditioning systems in extremely hot weather. DEC systems must be sized and constructed properly for the particular building and climate in which they are going to be installed. The ultimate goal is to reduce energy usage while producing affordable, green cooling options for regions with exceptionally hot temperatures. For simulation, we used computational fluid dynamics with ANSYS software. We purposefully varied the quantity of nozzles and the number of turns in the cooling tubes to see how they affected the effectiveness of the system. The temperature and velocity plot findings revealed a substantial difference, demonstrating that these engineering elements had an impact on the heat exchange process. According to the results, setups with 35 nozzles and 13 nozzle turns had a maximum coefficient of performance of 4.537 at an entry velocity of 2 m/s, showing that this configuration is ideal in the investigated conditions. The findings emphasize the need for strategically modifying some engineering parameters to increase heat exchanger performance and offer exciting prospects for the design and optimization of such systems. More research is needed to better understand these complicated interactions, including the investigation of different fluids, channel diameters, pressure conditions, and performance in the transient state. [ABSTRACT FROM AUTHOR]

Published

2024

20. Humidity-Controlling Ceramic Bricks: Enhancing Evaporative Cooling Efficiency to Mitigate Urban Heat Island Effect.

Author

Jin, Xueli, Wang, Junsong, Tan, Kanghao, and Zou, Zhenjie

Subjects

*URBAN heat islands, *FLEXURAL strength, *MANUFACTURING processes, *VOLCANIC ash, tuff, etc., *SURFACE temperature

Abstract

Passive evaporative cooling technology using the building envelope is a crucial measure to mitigate the urban heat island effect. This study aims to enhance the cooling efficiency of the surface of enclosure structures by utilizing volcanic ash, potassium–sodium stone powder, and silica-based mesoporous oxide (SMO) as primary materials. These components are incorporated into the ceramic brick production process to create innovative humidity-controlling ceramic bricks (HCCTs). This study extensively investigates the impact of SMO and the amount of applied glaze on the physical and mechanical characteristics of these HCCTs. Additionally, it examines the water absorption and evaporative cooling properties of the studied materials under optimal substitution conditions. Numerical calculations are used to determine the heat and moisture transfer properties of HCCTs. The results indicate that incorporating 2% SMO and applying 70 g/m2 of glaze results in a moisture absorption capacity of 385 g/m2 and a moisture discharge capacity of 370 g/m2. These conditions also yield a notable flexural strength of 15.2 MPa. Importantly, the HCCTs exhibit significantly enhanced capillary water absorption and water retention capabilities. Increased water absorption reduces surface temperature by 2–3 °C, maintaining the evaporative cooling effect for 20 to 30 h. It is also found that the temperature of HCCTs decreases linearly with increasing water content and porosity, while the temperature difference gradually decreases with thickness. Water migration in HCCTs with greater thickness is notably influenced by gravity, with water moving from top to bottom. Therefore, it is recommended that brick thickness does not exceed 15 mm. [ABSTRACT FROM AUTHOR]

Published

2024

21. Evaluation of the Skill of CMIP6 models in simulating the interannual variability of Subtropical Indian Ocean SST in present climate.

Author

Anila, Sebastian and Gnanaseelan, C.

Subjects

*SOUTHERN oscillation, *EVAPORATIVE cooling, *OCEAN, EL Nino

Abstract

This study explores the features of leading modes of Subtropical Indian Ocean (SIO) sea surface temperature (SST) variability and their representation in CMIP6 models. The first EOF mode of SIO SST, featured by an SST anomaly elongated from the northwestern to the southeastern SIO region is triggered by the El Niño/Southern Oscillation (ENSO). ENSO-induced wind anomalies over the SIO region weaken the climatological southeasterlies, reduce evaporative cooling, and consequently warm the SST in subtropics. The first SIO mode is closely related to the Indian Ocean Basin Mode. The CMIP6 models' skill in simulating this mode is attributable to their accurate representation of ENSO impacts in this region. At the same time, the skill of simulation of the second mode, the Subtropical Indian Ocean Dipole (SIOD), is poor in most models due to the misrepresentation of the pure tropical Indian Ocean Dipole (IOD) events. As pure IOD events generate SIOD, underestimation of the occurrence of pure IOD events will affect the development of SIOD in models. The CMIP6 model experiments reveal the absence of ENSO forcing on SIOD. Notably, regardless of the bias in co-occurred and pure IOD events, most of the models overestimate IOD strength due to the easterly surface wind bias and the associated thermocline depth bias. The easterly bias in the equatorial Indian Ocean surface wind weakens the Wyrtki jet, creating a shallow (deep) thermocline bias in the eastern (western) TIO. This induces an overestimation of warm (cold) SST in the western (eastern) TIO during positive IODs. [ABSTRACT FROM AUTHOR]

Published

2024

22. Inter-America meridional circulation and boreal summer climate.

Author

Jury, Mark R.

Subjects

*WIND shear, *WESTERLIES, *EVAPORATIVE cooling, *SURFACE temperature, *AIR flow

Abstract

Atmospheric convection across the northern inter-Americas is modulated by trade-wind subsidence and subtropical easterly waves from June to October. Northward migration of the equatorial trough is coupled to the meridional circulation (MC) and surface temperatures above 27ºC. Forming a MC index via S-N height sections of total and anomalous streamfunction, statistical relationships are examined which focus on Jun-Oct season when the South American monsoon is quiescent. Both east Pacific and tropical north Atlantic exhibit cool ocean – dry atmosphere response to an intensified MC. During periods of faster MC, composite humidity is depleted over the Caribbean 10–25 N in conjunction with westerly wind shear, thereby limiting atmospheric convection. The ocean response to intensified MC is evaporative cooling and a deep layer of increased salinity in the Caribbean, that may sustain anomalous air-sea interactions. Long-term trends reveal intensification of the MC in boreal summer: rising over the Amazon, subsiding over the Caribbean, inter-connected by lower and upper airflows. The annually pulsed MC conspires with inter-decadal trends to produce many of the features presented. [ABSTRACT FROM AUTHOR]

Published

2024

23. An Overview of Low-Cost Approaches for the Postharvest Storage of Fruits and Vegetables for Smallholders, Retailers, and Consumers.

Author

Gouda, Mohamed Hawali Bata and Duarte-Sierra, Arturo

Subjects

FARMERS, CONSUMERS, VEGETABLE storage, FRUIT storage, CONSUMER behavior, VEGETABLES

Abstract

Food loss and waste occur throughout the food supply chain and represent food security and environmental, economic, and societal problems. Fresh fruit and vegetables contribute to over 40% of global food loss and waste. A significant portion of fruit and vegetables loss takes place on the farm during postharvest handling in developing countries, which is linked to smallholders' financial and geographic constraints in purchasing modern postharvest handling technologies. While in developed countries, waste is the main problem identified at the retail and consumption levels because of inadequate logistics management, storage, and consumer behavior. The loss and waste deprive the population of a significant quantity of healthy food. To address this challenge, cost-effective, easy-to-use, and affordable approaches could be supplied to stakeholders. These strategies encompass the utilization of shading, low-cost packaging, porous evaporative cooling, zero-energy cooling chambers, and pot-in-pot coolers, for reductions in loss in developing countries. Meanwhile, in developed countries, biosensors, 1-methylcyclopropene, and imaging processing are employed to assess the quality of fresh fruit and vegetables at both retail and consumer levels. By exploring these methods, the review aims to provide smallholders, retailers, and consumers with efficient methods for improving produce operating techniques, resulting in reduced losses and waste and higher income. [ABSTRACT FROM AUTHOR]

Published

2024

24. The Role of Building-Integrated Greenery Systems in Building Sustainability Rating Systems.

Author

Reyes, Marcelo, Pérez, Gabriel, and Coma, Julià

Subjects

SUSTAINABLE construction, GREEN roofs, BUILT environment, EVAPORATIVE cooling, BUILDING envelopes

Abstract

Building rating systems allow for the evaluation of environmental buildings' impact throughout their lifecycle, thereby enabling improved design. The integration of vegetation into building envelopes, through green roofs and facades, provides multiple benefits that enhance the sustainability of a built environment. In arid climates, Building-Integrated Greenery Systems (BIGSs) contribute to energy savings and the improvement of the urban environment through evaporative cooling. However, the maintenance of these green systems requires efficient water use. This study thoroughly reviews six selected building sustainability certifications to determine the extent to which BIGSs are considered in the certification process. The findings indicate that BIGSs are not yet well integrated directly into these certifications. While the certifications recognize the biophilic effects on users and contributions to sustainable construction, they often overlook scientifically proven benefits such as acoustic insulation and urban noise reduction. This study highlights the importance of updating certification frameworks to fully incorporate the diverse advantages of BIGSs, especially in enhancing indoor environments and achieving energy savings. [ABSTRACT FROM AUTHOR]

Published

2024

25. Climate adaptive solution for artificial turf in cities: integrated rainwater storage and evaporative cooling.

Author

van Huijgevoort, Marjolein H. J., Cirkel, Dirk Gijsbert, and Voeten, Joris G. W. F.

Subjects

SYNTHETIC sporting surfaces, CLIMATE change, EVAPORATIVE cooling, CLIMATE change adaptation, CITIES & towns

Abstract

The number of artificial turf fields in cities has increased due to increased pressure on outside sport facilities caused by a higher population density. Downsides of these fields are changes in thermal conditions and decreased infiltration of rain. Artificial turf can reach very high surface temperatures leading to unfavourable playing conditions and contributing to the urban heat island effect. In this study the possibilities of a subsurface water storage and capillary irrigation system for evaporative cooling of artificial turf based on rainwater capture, storage and reuse are investigated. The system consists of an 85 mm water-retention subbase with capillary columns, a capillary shockpad and a natural infill. First, a laboratory experiment was conducted to test the evaporative potential of the system with different types of infill and artificial turf. Next, four research plots were designed in Amsterdam, The Netherlands, which consisted of natural grass, conventional artificial turf and two versions of the cooled artificial turf system (non-infill and standard). Evaporation from the cooled artificial turf reached maximum values around 4 mm/d during summer and surface temperatures were significantly lower than at the conventional artificial turf. Rainwater was stored below the fields. By combining these functions, these fields can help cities adapt to climate change. [ABSTRACT FROM AUTHOR]

Published

2024

26. Global variable-resolution simulations of extreme precipitation over Henan, China, in 2021 with MPAS-Atmosphere v7.3.

Author

Liu, Zijun, Dong, Li, Qiu, Zongxu, Li, Xingrong, Yuan, Huiling, Meng, Dongmei, Qiu, Xiaobin, Liang, Dingyuan, and Wang, Yafei

Subjects

*EVAPORATIVE cooling, *MICROPHYSICS, *PARAMETERIZATION, *TROPOSPHERE, *DEFAULT (Finance), *RAINSTORMS

Abstract

A historic rainstorm occurred over Henan, China, in July 2021 ("7.20" extreme precipitation event), resulting in significant human casualties and socioeconomic losses. A global variable-resolution model (MPAS-Atmosphere v7.3) was employed to simulate this extreme precipitation event. A series of simulations have been done at both quasi-uniform (60 and 15 km) and variable-resolution (60–15 and 60–3 km) meshes from hydrostatic to nonhydrostatic scale with two parameterization scheme suites. For the 48 h peak precipitation duration (20–22 July), the 60–3 km variable-resolution simulation coupled with the scale-aware convection-permitting parameterization scheme suite stands out predominantly among other simulation experiments as it reproduces this extreme precipitation event most accurately. At 15 km resolution, the 60–15 km variable-resolution simulation achieves comparable forecasting skills to the 15 km quasi-uniform simulation but at a much reduced computing cost. In addition, we found that the default mesoscale suite generally outperforms the convection-permitting suite at 15 km resolution as simulations coupled with the convection-permitting suite missed the third peak of this extreme precipitation event, while the mesoscale suite did not. Furthermore, it is found that the large-scale circulation plays a critical role in the peak precipitation simulations at 15 km resolution, via influencing the simulated low-level wind. During the second peak precipitation period, simulations with the convection-permitting parameterization scheme suite at 15 km resolution generate a prominent low-level easterly wind component bias, which is largely attributed to the excessively evaporative cooling in the lower troposphere. This study further reveals that at 15 km resolution the diabatic heating from the grid-scale precipitation accounts more for the low-level wind bias than the convective-scale precipitation. Given that two different cloud microphysics schemes, namely Thompson and WSM6 schemes, are used in the convection-permitting and default mesoscale parameterization scheme suites, respectively, these microphysics schemes are found to be the primary contributor to the low-level wind simulation bias. [ABSTRACT FROM AUTHOR]

Published

2024

27. An arctic breeding songbird overheats during intense activity even at low air temperatures.

Author

O'Connor, Ryan S., Love, Oliver P., Régimbald, Lyette, Le Pogam, Audrey, Gerson, Alexander R., Elliott, Kyle H., Hargreaves, Anna L., and Vézina, François

Subjects

*ATMOSPHERIC temperature, *LOW temperatures, *BODY temperature, *SONGBIRDS, *WARM-blooded animals, *TUNDRAS

Abstract

Birds maintain some of the highest body temperatures among endothermic animals. Often deemed a selective advantage for heat tolerance, high body temperatures also limits birds' thermal safety margin before reaching lethal levels. Recent modelling suggests that sustained effort in Arctic birds might be restricted at mild air temperatures, which may require reductions in activity to avoid overheating, with expected negative impacts on reproductive performance. We measured within-individual changes in body temperature in calm birds and then in response to an experimental increase in activity in an outdoor captive population of Arctic, cold-specialised snow buntings (Plectrophenax nivalis), exposed to naturally varying air temperatures (− 15 to 36 °C). Calm buntings exhibited a modal body temperature range from 39.9 to 42.6 °C. However, we detected a significant increase in body temperature within minutes of shifting calm birds to active flight, with strong evidence for a positive effect of air temperature on body temperature (slope = 0.04 °C/ °C). Importantly, by an ambient temperature of 9 °C, flying buntings were already generating body temperatures ≥ 45 °C, approaching the upper thermal limits of organismal performance (45–47 °C). With known limited evaporative heat dissipation capacities in these birds, our results support the recent prediction that free-living buntings operating at maximal sustainable rates will increasingly need to rely on behavioural thermoregulatory strategies to regulate body temperature, to the detriment of nestling growth and survival. [ABSTRACT FROM AUTHOR]

Published

2024

28. A comparative study of performance and energy efficiency in evaporative cooling: assessing different configurations of organic packings

Author

Shiva Kumar, Girish Hariharan, Ganesha A, Gowri Shankar M.C, Sampath Suranjan Salins, and Nitesh Kumar

Subjects

Humidification, evaporative cooling, celdek and coconut coir, evaporation rate, coefficient of performance, Dr Pham D T, Engineering, University of Birmingham, Birmingham, United Kingdom of Great Britain and Northern Ireland, Engineering (General). Civil engineering (General), TA1-2040

Abstract

This research is centered around the development and construction of a test apparatus for a counterflow evaporative cooler. The packing material utilized in the testing is coconut coir with wettability values of 300, 400 and 500 m2/m3. The experiments involve varying the air velocity. The study examined performance characteristics, including evaporation rates, cooler efficiency, coefficient of performance (COP) and energy consumption information, in relation to the standard Celdek 7090 packaging. The findings demonstrated that employing a coconut coir with optimal wettability resulted in a cooling efficiency and COP of 53.57% and 1.25, respectively. These values were slightly lower than those achieved with the usual Celdek 7090 packing. Coconut coir, as a biomass-derived material, possesses certain benefits that make it a suitable alternative for filling materials in evaporative cooling processes.

Published

2024

29. Enhancement of PV and concentered PV panels using evaporative cooling during summer and winter seasons: A case study in Egypt

Author

M. Salah Mansour, M. Halawa, H. Yahya, Moataz M. Abdel-Raouf, and M.A. Eid

Subjects

PV performance, PV enhancement, Concentrated PV, PV cooling, Evaporative cooling, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Numerous efforts are made to comprehend the performance evolution of photovoltaic (PV) panels. The elevated surface temperature causes a deterioration in PV panels' performance, hindering the expected increase in harvested energy associated with integrating solar reflectors. In this context, the year-round efficacy of cooling PV panels supported by reflective mirrors is investigated to assess the effectiveness of solar reflector implementation. A conventional PV panel, a CPV (cooled PV panel), and a CCPV (concentrated cooled PV panel) were compared side-by-side to determine their relative performance and energy productivity. Evaporative cooling pads are utilized to chill the two modified PV systems by varying the coolant flow rate during the summer and winter seasons of 2022 and 2023, respectively, in the environmental conditions of the Tenth of Ramadan City, Egypt. The findings indicate that the average daily power increment ratio (PIR) for CPV ranges from 4.7 % up to 7.4 %, while CCPV ranges from 6.7 % to 12 % for different climate conditions year-round. Finally, changing the setup configuration from CPV to CCPV increased the (PIR) 1.5 times during the summer tests and 1.7 times during the winter tests.

Published

2024

30. Asynchronous recovery of evaporation and transpiration following extreme snow damage in a subtropical forest

Author

Palingamoorthy Gnanamoorthy, Junbin Zhao, Abhishek Chakraborty, Pramit Kumar Deb Burman, Yaoliang Chen, Linjie Jiao, Jing Zhang, Yaqi Liu, Sigamani Sivaraj, Yiping Zhang, and Qinghai Song

Subjects

Evaporative cooling, Evapotranspiration, Subtropical forest, Canopy conductance, Post-damage, Physical geography, GB3-5030, Geology, QE1-996.5

Abstract

Study region: The Ailaoshan National Nature Reserve forest is a mountainous water catchment area for the Lancang River basin and a subtropical ecological conservation area in southwest China. Study focus: The study aimed to understand how water fluxes in a subtropical forest responds to extreme weather disturbances and their recoveries in the post-damage years. We used eddy covariance data (2010–2019) to investigate the evapotranspiration (ET), transpiration (T), evaporation (E), and canopy conductance (Gc) before and after an extreme snow event in 2015. New Hydrological Insights: In the snow damage year, the leaf area index (LAI) decreased by 49 % compared to the pre-damage levels. The severe vegetation damage caused a significant decrease in ET, T, E, and Gc by 35 %, 36 %, 23 %, and 33 %, respectively, compared to the pre-damage levels. T returned to its pre-damage level in 2016, one year after the snow damage. In contrast, LAI, ET, E and Gc recovered to their pre-damage levels in 2018, four years after the initial damage. Reduced ET caused a strong positive RFET, which diminished forest evaporative cooling and resilience. Our results suggest that the delayed E recovery enables water reserves in the ecosystems to be used through T to support rapid understory vegetation growth. This mechanism plays critical in bolstering ecosystem resilience as it facilitates swift recovery following disturbances in subtropical forests.

Published

2024

31. Applying Paraconsistent Annotated Logic Eτ for Optimizing Broiler Housing Conditions

Author

Angel Antonio Gonzalez Martinez, Irenilza de Alencar Nääs, Thayla Morandi Ridolfi de Carvalho-Curi, and Jair Minoro Abe

Subjects

non-classic logic, broiler production, exhaust fans, evaporative cooling, Agriculture (General), S1-972, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Broilers are particularly sensitive to heat stress, which can impair growth, and lower conversion efficiency and survival rates. Under a climate change scenario, maintaining optimal thermal conditions within broiler houses becomes more complex and energy-intensive. Climate change can worsen air quality issues inside broiler houses by increasing the concentration of harmful gases, and proper mechanical ventilation systems are essential for diluting and removing these gases. The present study aimed to develop and validate a model for the ideal broiler housing strategy by applying the Paraconsistent Annotated Evidential Logic Eτ. A database from four broiler houses in a commercial farm, rearing 157,700 birds from the 1st to the 42nd day of growth, was used in the research. All environmental data were recorded weekly inside the houses, and on day 42, flock mortality, overall feed-to-gain ratio, and body weight were calculated and registered. The Cohen’s Kappa statistics for each environmental parameter classification compared to the paraconsistent classification. Results indicated that temperature shows good agreement, relative humidity shows slight agreement, air velocity presents a good agreement, CO2 concentration has a slight agreement, and NH3 concentration is classified by slight agreement. The environmental and productivity variables as a function of the broiler age using the extreme True paraconsistent state indicate the model validation. The paraconsistent analysis presented the ideal scenario for broilers’ growth, maintaining the environmental variables level within a particular threshold and providing greater profit to broiler farmers.

Published

2024

32. Determination of Performance of Different Pad Materials and Energy Consumption Values of Direct Evaporative Cooler.

Author

Jakubowski, Tomasz, Boyacı, Sedat, Kocięcka, Joanna, and Atılgan, Atılgan

Subjects

*CONSUMPTION (Economics), *NATURAL ventilation, *WATER consumption, *CELLULOSE, *EVAPORATIVE cooling

Abstract

The purpose of this study is to determine the performances of luffa and greenhouse shading netting (which can be used as alternatives to commercial cellulose pads, that are popular for cooling greenhouses), the contribution of external shading to the evaporative cooling performance, and the energy consumption of the direct evaporative cooler. In this experiment, eight different applications were evaluated: natural ventilation (NV), natural ventilation combined with external shading net (NV + ESN), cellulose pad (CP), cellulose pad combined with external shading net (CP + ESN), luffa pad (LP), luffa pad combined with external shading net (LP + ESN), shading net pad (SNP), and shading net pad combined with external shading net (SNP + ESN). The cooling efficiencies of CP, CP + ESN, LP, LP + ESN, SNP, and SNP + ESN were found to be 37.6%, 45.0%, 38.9%, 41.2%, 24.4%, 29.1%, respectively. Moreover, their cooling capacities were 2.6 kW, 3.0 kW, 2.8 kW, 3.0 kW, 1.7 kW, 2.0 kW, respectively. The system water consumption values were 2.9, 3.1, 2.8, 3.2, 2.4, 2.4 l h−1, respectively. The performance coefficients of the system were determined to be 10.2, 12.1, 11.3, 11.9, 6.6, 7.8. The system's electricity consumption per unit area was 0.15 kWh m−2. As a result of the study, it was determined that commercially used cellulose pads have advantages over luffa and shading net materials. However, luffa pads can be a good alternative to cellulose pads, considering their local availability, initial cost, cooling efficiency, and capacity. [ABSTRACT FROM AUTHOR]

Published

2024

33. Applying Paraconsistent Annotated Logic Eτ for Optimizing Broiler Housing Conditions.

Author

Martinez, Angel Antonio Gonzalez, de Alencar Nääs, Irenilza, de Carvalho-Curi, Thayla Morandi Ridolfi, and Abe, Jair Minoro

Subjects

*COHEN'S kappa coefficient (Statistics), *HOUSING

Abstract

Broilers are particularly sensitive to heat stress, which can impair growth, and lower conversion efficiency and survival rates. Under a climate change scenario, maintaining optimal thermal conditions within broiler houses becomes more complex and energy-intensive. Climate change can worsen air quality issues inside broiler houses by increasing the concentration of harmful gases, and proper mechanical ventilation systems are essential for diluting and removing these gases. The present study aimed to develop and validate a model for the ideal broiler housing strategy by applying the Paraconsistent Annotated Evidential Logic Eτ. A database from four broiler houses in a commercial farm, rearing 157,700 birds from the 1st to the 42nd day of growth, was used in the research. All environmental data were recorded weekly inside the houses, and on day 42, flock mortality, overall feed-to-gain ratio, and body weight were calculated and registered. The Cohen's Kappa statistics for each environmental parameter classification compared to the paraconsistent classification. Results indicated that temperature shows good agreement, relative humidity shows slight agreement, air velocity presents a good agreement, CO2 concentration has a slight agreement, and NH3 concentration is classified by slight agreement. The environmental and productivity variables as a function of the broiler age using the extreme True paraconsistent state indicate the model validation. The paraconsistent analysis presented the ideal scenario for broilers' growth, maintaining the environmental variables level within a particular threshold and providing greater profit to broiler farmers. [ABSTRACT FROM AUTHOR]

Published

2024

34. Health and Thermal Comfort of Dairy Cattle in Compost-Bedded Pack Barns and Other Types of Housing: A Comparative Systematic Review.

Author

Oliveira, Carlos Eduardo Alves, Tinôco, Ilda de Fátima Ferreira, Sousa, Fernanda Campos de, Baêta, Fernando da Costa, Vieira, Frederico Márcio Côrrea, and Barbari, Matteo

Subjects

*THERMAL comfort, *DAIRY cattle, *EVAPORATIVE cooling, *HOT springs, *WEB databases, *VENTILATION, *NATURAL ventilation

Abstract

This systematic review was conducted to describe and discuss the main research findings available in the literature concerning the health and thermal comfort of dairy cattle housed in Compost-Bedded Pack Barn (CBP) systems, in comparison to Free Stall (FS), Tie-Stall (TS), and/or Loose Housing (LH) systems. Searches for peer-reviewed experimental articles in English were performed in the Scopus and Web of Science databases. Forty-three non-duplicated scientific articles were obtained and subjected to a four-stage evaluation process, according to the PRISMA methodology and predefined eligibility criteria. This process resulted in the selection of 13 articles for inclusion. Regarding animal health, the results provide evidence that the incidence of problems such as lameness, limb injuries, and reproductive disorders is lower in CBP systems. However, if bedding management is not effective in ensuring the provision of dry and comfortable surfaces, an increase in somatic cell count (SCC) and prevalence of mastitis incidence (PMI) may occur. For thermal comfort, it was found that the CBP system exhibited higher temperatures during summer and lower temperatures during winter when compared to FS with cross-ventilation in association with evaporative cooling. However, no differences were observed in terms of thermal comfort in spring and autumn. As this is a recent research area, caution should be exercised when extrapolating the results, considering the specificities of each cited study. [ABSTRACT FROM AUTHOR]

Published

2024

35. Analysis of an Evaporative Cooling Pad Connected to an Air Distribution System of Perforated Polyethylene Tubes in a Greenhouse.

Author

Pardo-Pina, Sofía, Ferrández-Pastor, Javier, Rodríguez, Francisco, and Cámara-Zapata, José M.

Subjects

*CLIMATE in greenhouses, *CLIMATE change adaptation, *EVAPORATIVE cooling, *CROP yields, *POLYETHYLENE, *HUMIDITY

Abstract

The increase in ambient temperature decreases crop yields. Therefore, greenhouse cooling techniques can be considered adaptation strategies to climate change. To improve the efficiency of crop production, semi-closed greenhouses are utilized, which reduce the mass and energy transfer from the greenhouse. Frequently, these types of structures include an evaporative panel and a distribution system through perforated inflated ducts. To further improve the management of this type of installation, the present work models its behavior. The proper functioning of these installations greatly depends on temperature, as well as the relative humidity of the exterior air. The results show how the exterior climate conditions affect the values of temperature and relative humidity inside the greenhouse due to its effect on the value of evaporative cooling. The cooling capacity of the air per unit mass of evaporated water is reduced when the temperature and/or humidity of the air to be treated in the evaporative panel increases. Thus, when the exterior air is at 40 °C and its relative humidity is 75%, its temperature after passing through the evaporative panel is 15 °C higher than when the initial state of the exterior air is 30 °C and 30%. The effect of the use of frequency drivers in the fans on energy consumption has also been evaluated. A reduction of 8% in the frequency value causes a 22% decrease in the power consumed and a 15% pressure drop in the circuit. Therefore, reducing the frequency of electrical energy can contribute to energy savings without affecting the climate inside the greenhouse. [ABSTRACT FROM AUTHOR]

Published

2024

36. Enhancing Air Conditioner Efficiency Through Evaporative Cooling of the Compressor: Field Test Results.

Author

Setyawan, Andriyanto

Subjects

*EVAPORATIVE cooling, *AIR conditioning efficiency, *GAS condensate reservoirs, *COOLING of water, *STANDARD of living, *AIR conditioning, *ENERGY consumption

Abstract

Energy demand for the air conditioning sector is increasing due to increasing population, increasing living standards, and global warming. This increase in demand must be accompanied by efforts to increase energy efficiency. Evaporative cooling is one effort that can be chosen to increase the energy efficiency of the air conditioning system. The use of evaporative cooling by utilizing condensate water from the evaporator has been experimentally investigated. This research was conducted directly on an air conditioner unit that had already been installed in a room. Specifically, experiments were carried out by flowing and dripping condensate water into the compressor body of an air conditioner and examining its effect on the performance of the air conditioner. The research results show that the use of condensate water can reduce suction temperature, discharge temperature and condensation temperature by 0.7°C, 3.2°C, and 1.2°C, respectively. As a result, cooling capacity increases by 2.8%, energy consumption decreases by 3.5%, and energy efficiency ratio increases by 7.6%. Overall, the use of condensate water for compressor cooling can improve air conditioner performance. [ABSTRACT FROM AUTHOR]

Published

2024

37. Influence of misting system on the thermal environment and thermal comfort of seated people in semi-outdoor space in Xi'an, China.

Author

Xie, Xu, Sun, Zhen, Zhu, Xi, Zhao, Shengkai, Wang, Zun, and Zhai, Yongchao

Subjects

THERMAL comfort, SOLAR radiation, EVAPORATIVE cooling, HUMIDITY

Abstract

In summer, factors such as solar radiation could make semi-outdoor spaces uncomfortable, and the use of misting systems for evaporative cooling is a low-energy improvement measure. To investigate the impact of misting system on the thermal environment and thermal comfort of seated people improvement, a field study was conducted at a semi-outdoor cafeteria in Xi'an. The results indicated that the misting system was capable of reducing the ambient air temperature by 2.4–4.9 °C and increasing the relative humidity by 17.1%–17.8%. Participants in misting condition reported lower thermal sensation and higher thermal acceptability, thermal preference, humidity sensation, humidity preference and humidity acceptability. In no misting condition, the upper SET∗ limit acceptable to 80% of the population was 28.5 °C. However, in the misting condition, the acceptable percentage of participants in each SET∗ interval was more than 90%. When SET∗ was 22.1–23.7 °C, the improvement in human thermal comfort through misting system was not significant. When SET∗ was 23.7–28.5 °C, the misting system significantly improve human thermal comfort. Finally, two control temperature thresholds of the misting system were provided according to the relationship between 80%, the maximum (89.3%) acceptable percentage and the air temperature, which were 30.1 °C and 26.5 °C, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

38. 填料蒸发预冷进风的机械通风空冷塔设计及其 运行性能.

Author

王明伟, 刘天天, 高琦, 王春伟, 沈吉勇, 刘守富, and 何锁盈

Abstract

Copyright of Electric Power is the property of Electric Power Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

39. Atmosphere teleconnections from abatement of China aerosol emissions exacerbate Northeast Pacific warm blob events.

Author

Hai Wang, Xiao-Tong Zheng, Wenju Cai, Zi-Wen Han, Shang-Ping Xie, Kang, Sarah M., Yu-Fan Geng, Fukai Liu, Chuan-Yang Wang, Yue Wu, Baoqiang Xiang, and Lei Zhou

Subjects

*MARINE heatwaves, *EXTREME weather, *AEROSOLS, *OCEAN temperature, *EVAPORATIVE cooling, *TOBACCO products

Abstract

During 2010 to 2020, Northeast Pacific (NEP) sea surface temperature (SST) experienced the warmest decade ever recorded, manifested in several extreme marine heatwaves, referred to as "warm blob" events, which severely affect marine ecosystems and extreme weather along the west coast of North America. While year-to-year internal climate variability has been suggested as a cause of individual events, the causes of the continuous dramatic NEP SST warming remain elusive. Here, we show that other than the greenhouse gas (GHG) forcing, rapid aerosol abatement in China over the period likely plays an important role. Anomalous tropospheric warming induced by declining aerosols in China generated atmospheric teleconnections from East Asia to the NEP, featuring an intensified and southward-shifted Aleutian Low. The associated atmospheric circulation anomaly weakens the climatological westerlies in the NEP and warms the SST there by suppressing the evaporative cooling. The aerosol-induced mean warming of the NEP SST, along with internal climate variability and the GHG-induced warming, made the warm blob events more frequent and intense during 2010 to 2020. As anthropogenic aerosol emissions continue to decrease, there is likely to be an increase in NEP warm blob events, disproportionately large beyond the direct radiative effects. [ABSTRACT FROM AUTHOR]

Published

2024

40. Evolution of avian heat tolerance: The role of atmospheric humidity.

Author

Freeman, Marc T., Coulson, Bianca, Short, James C., Ngcamphalala, Celiwe A., Makola, Mathome O., and McKechnie, Andrew E.

Subjects

*EVAPORATIVE power, *BODY temperature, *EVAPORATIVE cooling, *ATMOSPHERIC temperature, *FEVER, *HUMIDITY, *HOT weather conditions

Abstract

The role of atmospheric humidity in the evolution of endotherms' thermoregulatory performance remains largely unexplored, despite the fact that elevated humidity is known to impede evaporative cooling capacity. Using a phylogenetically informed comparative framework, we tested the hypothesis that pronounced hyperthermia tolerance among birds occupying humid lowlands evolved to reduce the impact of humidity‐impeded scope for evaporative heat dissipation by comparing heat tolerance limits (HTLs; maximum tolerable air temperature), maximum body temperatures (Tbmax), and associated thermoregulatory variables in humid (19.2 g H2O m−3) versus dry (1.1 g H2O m−3) air among 30 species from three climatically distinct sites (arid, mesic montane, and humid lowland). Humidity‐associated decreases in evaporative water loss and resting metabolic rate were 27%–38% and 21%–27%, respectively, and did not differ significantly between sites. Decreases in HTLs were significantly larger among arid‐zone (mean ± SD = 3.13 ± 1.12°C) and montane species (2.44 ± 1.0°C) compared to lowland species (1.23 ± 1.34°C), with more pronounced hyperthermia among lowland (Tbmax = 46.26 ± 0.48°C) and montane birds (Tbmax = 46.19 ± 0.92°C) compared to arid‐zone species (45.23 ± 0.24°C). Our findings reveal a functional link between facultative hyperthermia and humidity‐related constraints on evaporative cooling, providing novel insights into how hygric and thermal environments interact to constrain avian performance during hot weather. Moreover, the macrophysiological patterns we report provide further support for the concept of a continuum from thermal specialization to thermal generalization among endotherms, with adaptive variation in body temperature correlated with prevailing climatic conditions. [ABSTRACT FROM AUTHOR]

Published

2024

41. Intensified future heat extremes linked with increasing ecosystem water limitation.

Author

Denissen, Jasper M. C., Teuling, Adriaan J., Koirala, Sujan, Reichstein, Markus, Balsamo, Gianpaolo, Vogel, Martha M., Yu, Xin, and Orth, René

Subjects

*EVAPORATIVE cooling, *PLANT transpiration, *ATMOSPHERIC circulation, *SOIL moisture, *PLANT-soil relationships

Abstract

Heat extremes have severe implications for human health, ecosystems, and the initiation of wildfires. While they are mostly introduced by atmospheric circulation patterns, the intensity of heat extremes is modulated by terrestrial evaporation associated with soil moisture availability. Thereby, ecosystems provide evaporative cooling through plant transpiration and soil evaporation, which can be reduced under water stress. While it has been shown that regional ecosystem water limitation is projected to increase in the future, the respective repercussions on heat extremes remain unclear. In this study, we use projections from 12 Earth system models to show that projected changes in heat extremes are amplified by increasing ecosystem water limitation in regions across the globe. We represent the ecosystem water limitation with the ecosystem limitation index (ELI) and quantify temperature extremes through the differences between the warm-season mean and maximum temperatures. We identify hotspot regions in tropical South America and across Canada and northern Eurasia where relatively strong trends towards increased ecosystem water limitation jointly occur with amplifying heat extremes. This correlation is governed by the magnitude of the ELI trends and the present-day ELI which denotes the land–atmosphere coupling strength determining the temperature sensitivity to evaporative cooling. Many regions where ecosystem functioning is predominantly energy-limited or transitional in the present climate exhibit strong trends towards increasing the water limitation and simultaneously experience the largest increases in heat extremes. Sensitivity of temperature excess trends to ELI trends is highest in water-limited regions, such that in these regions relatively small ELI trends can amount to drastic temperature excess trends. Therefore, considering the ecosystem's water limitation is key for assessing the intensity of future heat extremes and their corresponding impacts. [ABSTRACT FROM AUTHOR]

Published

2024

42. การศึกษาผลกระที่บข้อุงกาวั 5 ช้นิิดุติ่อุการดุูดุซับ อุัติราการแพร่ และการระเห์ยในิผ้าทีี่􀃉ติิดุ บนิแผ่นิอุะลูมูิเนิียมู

Author

วััฒนานุสิที่ธุ์ิ, ก้องนที่่, อินชนะ, จุฬาลักษณ, and คูณศึร่สุข, อาทีิ่ติย􀁲

Abstract

The objective of this experimental study was to identify a suitable type of adhesive that can effectively enhance the absorbency rate and water evaporation capacity of fabrics, consequently improving the cooling capacity of evaporative coolers. Five distinct adhesives, utilized as binders between fabric and aluminum, were compared. The water absorption and diffusion rate through the adhered fabric onto the aluminum workpiece was evaluated by observing the behavior of water droplets. The evaporation capacity was measured in a test rig by assessing the outlet humidity ratio of air after flowing over the wetted sample. Among the tested adhesives, Draga glue demonstrated superior performance in terms of water diffusion rate, evaporation, and cost per unit mass. With Draga glue, water diffusion rates were 5.64, 7.36, and 11.52 times higher than those of SikaFlex 740, hot glue, and SA, respectively. The outlet humidity ratio from the Draga glue sample reached 16.91 g/kg, exceeding the rates of SikaFlex 740, hot glue, and SA by 22.17%, 22.46%, and 26.70%, respectively. Economically, Draga glue was found to be twice as cost-effective per unit mass as the other adhesives studied. These findings indicate that the use of Draga glue can significantly enhance the diffusion rate, evaporation, and cooling capacities of evaporative coolers. [ABSTRACT FROM AUTHOR]

Published

2024

43. Clusters of grapevine genes for a burning world.

Author

Coupel‐Ledru, Aude, Westgeest, Adrianus J., Albasha, Rami, Millan, Mathilde, Pallas, Benoît, Doligez, Agnès, Flutre, Timothée, Segura, Vincent, This, Patrice, Torregrosa, Laurent, Simonneau, Thierry, and Pantin, Florent

Subjects

*VITIS vinifera, *PLANT molecular biology, *GRAPES, *BOTANY, *ABSCISIC acid, *LOCUS (Genetics), *COMPUTATIONAL biology, *BOTANICAL chemistry

Abstract

A study published in the New Phytologist journal examines the genetic diversity of grapevines and their ability to withstand extreme heatwaves caused by climate change. The researchers conducted experiments on a grapevine diversity panel in South France during a record heatwave in 2019. They discovered that certain genomic regions were linked to heat tolerance, suggesting that genetic diversity could be used to breed fruit crops that can withstand heatwaves. The study also investigated the role of leaf size, leaf mass per area, and evaporative cooling in heat tolerance. The researchers identified candidate genes that may contribute to heat tolerance in grapevines. [Extracted from the article]

Published

2024

44. Efficiency Analysis of a Two-Stage Evaporative Cooling System with Sustainable Water Pad.

Author

Salman, Ameer Hayder, Jasim, Jasim Ahmed, Alwan Aljuboori, Mohammed Khudhair, and Zaidan, Ayad Awad

Subjects

*COOLING systems, *HEAT exchangers, *GLOBAL warming, *ATMOSPHERIC temperature, *POLLUTION

Abstract

The efficiency of evaporative media typically ranges from 80% to 90%. The most effective systems can reduce the temperature of dry air to 95% of the wet-bulb temperature, while the least effective systems can only accomplish 50%. The rate of evaporation efficiency experiences little decline over time. The climate in Iraq has a more extended period of summer in comparison to other nations. The ambient temperature during this season exceeds 50oC, making the evaporative cooling system appropriate for this region. The evaporative cooler in this study is created by incorporating multiple heat exchanger stages (water-air) to cool the input air indirectly and indirectly before cooling directly inside the traditional evaporative cooler. When compared to compression refrigeration systems, the multistage evaporative cooler helps to reduce energy use, environmental pollution, the effects of global warming, and manufacturing costs. The multistage evaporative cooler is appropriate for use in homes and sizable structures with high relative humidity and temperatures. The developed evaporative cooler's experimental findings demonstrated that the addition of a cooling stage to a conventional cooler reduces the out-dry bulb temperature by about 50% and the specific humidity by about 80%. [ABSTRACT FROM AUTHOR]

Published

2024

45. Thermal Effect of Probes Present in a Pharmaceutical Formulation during Freeze-Drying Measured by Contact-Free Infrared Thermography.

Author

Emteborg, Håkan and Charoud-Got, Jean

Subjects

FREEZE-drying, EVAPORATIVE cooling, THERMOGRAPHY, TEMPERATURE effect, TEMPERATURE measurements, SPATIAL resolution

Abstract

A high-resolution infrared (IR) camera was used for temperature measurements in a pharmaceutical formulation (mannitol/sucrose solution, 4:1%, m/m) during a freeze-drying process. The temperature was measured simultaneously at the surface as well as vertically (e.g., in-depth) along the side of custom-made cuvettes equipped with a germanium (Ge) window. Direct imaging during 45 h from −40 °C to 40 °C took place every 60 s on the surface and on the side with 0.28 × 0.28 mm per IR-pixel providing 2700 thermograms. The spatial resolution per cuvette was approximately 4225 pixels for the surface view (without a probe) and 6825 IR-pixels for the side view. Temperature effects and gradients due to the presence of a Pt100 and a LyoRx-probe in the pharmaceutical formulation were clearly visible and were quantified during the freezing step as well as the primary and secondary drying stages. The temperature was about 3.5 K higher during primary drying as compared to the temperature measured in the same material in adjacent cuvettes without probes. During secondary drying, evaporative cooling of upper layers was clearly visible. [ABSTRACT FROM AUTHOR]

Published

2024

46. Experimental Study of the Performance of Solar Evaporative Watercooler with Clay Tank.

Author

Moravej, Mojtaba

Subjects

COOLING of water, EVAPORATIVE cooling, CLAY, DRINKING water, PERFORMANCE theory, PHOTOVOLTAIC power systems

Abstract

The main goal of this research is to use integrated solar photovoltaic systems to cool drinking water evaporative cooling. For this purpose, a traditional system including a clay tank for cooling drinking water, which is equipped with a solar photovoltaic auxiliary system, was investigated experimentally. This device made by the author, which includes an old terracotta tank with holding equipment and a photovoltaic panel, along with six cooling fans was tested. The tests include investigating the effect of environmental factors and solar energy on the performance of this cooling water system. The testing process consists of the investigation of the traditional mode and the evaluation of the amount of cooled water and its comparison with the method of using the photovoltaic system and auxiliary fans. The research results showed that this type of water cooler has a maximum efficiency of about 16% in a normal state, and with the use of photovoltaic fans, the efficiency increases by about 9.5%. Also, in traditional mode, the device has the ability to cool water up to 15 °C lower than the ambient temperature, and if the photovoltaic system is used, this amount of cooling will be more than 21 °C that indicates suitable cooling for drinking water in summer and compared to some previous studies. [ABSTRACT FROM AUTHOR]

Published

2024

47. Desiccant Enhanced Indirect Evaporative Cooling: Laboratory Testing.

Author

Hollist, Jonathan, McMurry, Robert, and Vernon, David

Subjects

*HEATS of vaporization, *RESISTANCE heating, *EVAPORATIVE cooling, *HEAT storage, *CLEAN energy, *COOLING systems, *HEAT pumps

Published

2024

48. Your letters.

Author

Eades, Alwyn, Hinwood, Jon, Edge, Sam, Pallen, Mark, Parker, Aimee, Loman, Nick, Walker, Alan, Stock, Bob, Bullimore, Blaise, Giles, Alan, Kvaalen, Eric, Glover, Bryn, Malzeard, Kirkby, and Fenton, James

Subjects

*COMMON sense, *ATOMIC nucleus, *COOLING towers, *EVAPORATIVE cooling, *ELECTRIC charge

Abstract

The article from New Scientist features a collection of letters discussing various topics. These include the concept of common sense, the absence of a brain microbiome, the benefits of growing one's own produce, factors contributing to increased rainfall in cities, the need for clarity in physics terminology, potential solutions for keeping the International Space Station in orbit, speculation on the existence of black holes before the big bang, concerns about artificial food production, and a correction regarding a photo caption. The letters come from contributors in the US, Australia, the UK, and France, offering diverse perspectives on scientific and societal issues. [Extracted from the article]

Published

2024

49. How Hot is Too Hot?

Author

Gilles, Nathan

Subjects

*DEAD trees, *SCIENTIFIC literature, *PLANT plasma membranes, *TREE-rings, *EVAPORATIVE cooling, *TREE mortality

Abstract

Scientists are studying the upper thermal limit of trees in response to tree die-offs caused by extreme heatwaves. The 2021 "heat dome" in the Pacific Northwest, attributed to human-caused climate change, resulted in tree deaths. Climate change is increasing the duration, frequency, and intensity of heatwaves, posing a threat to trees and their ability to provide ecosystem services and sequester carbon. Scientists are trying to understand the damage caused by direct heat and sun exposure versus prolonged hot drought. A review of scientific literature found that the thermal tolerances of only 0.31% of land-based plants have been determined, which is concerning given the high confidence predictions for extremely hot temperatures due to climate change. Forests are already experiencing stress from hot drought conditions, and tree die-offs linked to climate change have been observed across various biomes. Limiting global warming is crucial, but extreme heat events can still have profound effects on forests. The loss of culturally important trees like the European beech is already being felt, leading to psychological and ecological instability. Large-scale forest mortality could significantly change the look and structure of forests for generations. The effects of climate change are already impacting individuals like Phil Hunter, a Christmas tree farmer who has seen tree deaths on his farm due to hot-drought conditions. Adapting to the changing climate is necessary to mitigate the effects of extreme heat on plants and ecosystems. [Extracted from the article]

Published

2024

50. An arctic breeding songbird overheats during intense activity even at low air temperatures

Author

O’Connor, Ryan S., Love, Oliver P., Régimbald, Lyette, Le Pogam, Audrey, Gerson, Alexander R., Elliott, Kyle H., Hargreaves, Anna L., and Vézina, François

Published

2024