Optimum Temperature Range Research Articles

Effect of Drying Temperature on Sensory Quality, Flavor Components, and Bioactivity of Lichuan Black Tea Processed by Echa No. 10

Lichuan black tea (LBT) is a well-known congou black tea in China, but there is relatively little research on its processing technology. Echa No. 10 is the main tea tree variety for producing LBT. This study investigated the sensory quality, flavor components, and bioactivity of Echa No. 10 Lichuan black tea (LBT) at different drying temperatures (70, 80, 90, 100, 110, 120, and 130 °C). During 80–120 °C, increasing the drying temperature enabled a higher sweet aroma concentration and enhanced the sweetness in the taste, in contrast to reducing the floral, fruity, and sweet aromas, and increasing the bitterness and astringency, at >120 °C. Additionally, with an increasing drying temperature, the contents of tea polyphenols and total catechins significantly decreased, with the theaflavins decreasing first and then increasing, and the alcohols, aldehydes, esters, and hydrocarbons increasing first and then decreasing. Meanwhile, compounds (including linalool, (Z)-linalool oxide (furanoid), (E)-linalool oxide (furanoid), cis-β-Ocimene, and methyl salicylate) contribute more to the floral and fruity aromas at <110 °C. Furthermore, low-temperature drying favors the antioxidant and inhibitory effects of the α-amylase, α-glucosidase, and glucose absorption activity. Both the tea quality and bioactivity results revealed 80–110 °C as the optimal drying temperature range for LBT.

Operational Flexibility Evaluation and Techno-Economic Analysis on Hot Primary Air Temperature Boosting by Reheated Steam in a Lignite-Fired Power Plant

Abstract Coal-fired power plants are commonly used as adjustable power sources to complement the fluctuating output of wind and solar energy. The investigation is required to determine the flexible peak-shaving capabilities of coal-fired boilers. A modified scheme for a lignite-fired power plant to further improve the primary air temperature using the outlet steam from the low-temperature reheater is studied while increasing the inlet flue gas temperature of the air preheater is considered the conventional scheme. Thermodynamic models of the power plant are constructed using ebsilon software. The operational characteristics of both schemes are compared under 30% turbine heat acceptance (THA)–100%THA conditions and the economic performance of the modified scheme is also evaluated. Results indicate that the modified scheme exhibits superior thermodynamic and economic performances compared to the conventional scheme. The disparity in power generation efficiency between the conventional and modified schemes reaches a maximum of 0.23 percentage points under 75%THA conditions. The net present value of the modified scheme amounts to 4.51 million dollars over the power plant lifespan of 30 years. The modified scheme allows the conventional denitrification catalyst to maintain an optimal temperature range even under 30%THA conditions, resulting in a power generation efficiency only 4.8 percentage points lower than that under 100%THA conditions, thus demonstrating remarkable operational flexibility. This study presents an efficient, cost-effective, and adaptable approach for lignite-fired power plants.

Acclimation, thermal tolerance and aerobic metabolism of narrow-clawed crayfish, Pontastacus leptodactylus (Eschscholtz, 1823).

Ectotherms are considered more susceptible to global warming. Variations in ambient temperature are especially alarming as the majority of animals are ectothermic, with temperature seen as a crucial determinant of their ecology, biogeography, behaviour, and physiology. Ectotherms, which depend on external ambient temperatures to regulate their body temperature, exhibit various physiological and metabolic responses to variations in temperature. These responses are essential for comprehending how these species will acclimatise to changing water temperatures and the consequent alterations in oxygen availability. This study assessed the acclimation ability, temperature tolerance, and metabolic rate of narrow-clawed crayfish (Pontastacus leptodactylus) to elucidate the crayfish's responses to potential climate change. Our study showed that the narrowed clawed crayfish is a species that exhibits high thermal tolerance, with an extensive dynamic (1114 °C2), static thermal polygon area (966 °C2), resistance zone of 103 °C2 and the ability to withstand extreme temperatures (CTmin-CTmax: 1.60-36.8°C). The acclimation temperature has minimal impact on the thermal tolerance of the crayfish (P<0.01). The optimal temperature range for SMR of Pontastacus leptodactylus is 20-25°C, within which a decline in standard metabolic rate (SMR) occurs as temperature rises.

OPTIMIZING HEATED AIR CIRCULATION IN SILO/BIN DESIGN: A PARAMETRIC APPROACH

Aeration is one of the most essential processes after harvest in guaranteeing food security since it is often employed for grain cooling while the physical qualities of the stored grains are sustained. Aiming to address issues of storage inefficiencies, the research reviewed “Optimization of Heated Air Circulation in Silo/Bin Design: A Parametric Approach.” The method adopted for the study was systematic review of journal articles, conference proceedings, books and other relevant materials. Furthermore, the main method used to find relevant publications for the study was keyword searches in electronic databases such as Research Gate, Web of Science, Google Scholar and Scopus. Hence, the study ascertained that at an optimal temperature range between 10 - 15°C, grain storage facilities can effectively mitigate the risks of moisture accumulation, insect infestation, and microbial growth. More so, the study revealed that the rate of airflow ranging from 0.05 to 0.1 m3 min-1 t-1 are usually utilized in tall steel bins and concrete silos containing small grains, again measurements ranges from 0.1 to 0.2 meter cubed per minute per tonne were suggested for horizontal storage for huge grains. However, the study suggests that SSR model seems to be the most suitable model for optimization of heated air circulation in silo/bin among all the reviewed models because it is capable of describing nearly all the systems’ dynamics.

Assessment of sowing dates and spacing for indogangetic plain zone kharif maize(Zea mays) cultivars to achieve higher productivity in Western IGP

An experiment was conducted to study the effect of sowing dates and spacing on the productivity of newly developed maize cultivars at 2 locations, viz. Punjab Agricultural University, Ludhiana, and ICAR-Indian Institute of Maize Research, Ladhowal, Punjab during kharif 2021 and 2022. Results revealed that the optimum range of temperature during the growth period had favourable impact on dry matter accumulation at the silking stage with sowing dates of 15 June and 30 June. At Ludhiana and Ladhowal, maize sown on 15 June and 30 June recorded significantly higher yield attributes such as cob weight, grains/ cob and 1000-grains weight as compared to maize sown on 1 June and 15 July. Sowing dates of 15 June and 30 June recorded at par grain yield of maize in loamy sand soil at Ludhiana in both years. On the other hand, at Ladhowal in sandy loam soil, the maize sowing on 15 June recorded the highest maize grain yield followed by on 30 June in both years. Likewise, a yield penalty of 27.16–28.59% and 21.69–24.43% was registered with maize sown on 15 July as compared to maize sown on 15 June at Ludhiana and Ladhowal, respectively over the years. New cultivars of maize outperformed at various planting densities at both locations. Planting density of 67.5 cm × 15 cm having 98,765 plants/ha gave a higher grain yield compared to 67.5 × 18 cm (82,305 plants/ha) at both locations. Among the different cultivars, ‘JH 19014’ (5.35–5.03 t/ha) and ‘JH 17011’ (5.31–5.17 t/ha) performed superior over ‘PMH 13’ (5.18–4.87 t/ha) at both locations.

Assessment of sowing dates and spacing for indogangetic plain zone kharif maize(Zea mays) cultivars to achieve higher productivity in Western IGP

An experiment was conducted to study the effect of sowing dates and spacing on the productivity of newly developed maize cultivars at 2 locations, viz. Punjab Agricultural University, Ludhiana, and ICAR-Indian Institute of Maize Research, Ladhowal, Punjab during kharif 2021 and 2022. Results revealed that the optimum range of temperature during the growth period had favourable impact on dry matter accumulation at the silking stage with sowing dates of 15 June and 30 June. At Ludhiana and Ladhowal, maize sown on 15 June and 30 June recorded significantly higher yield attributes such as cob weight, grains/ cob and 1000-grains weight as compared to maize sown on 1 June and 15 July. Sowing dates of 15 June and 30 June recorded at par grain yield of maize in loamy sand soil at Ludhiana in both years. On the other hand, at Ladhowal in sandy loam soil, the maize sowing on 15 June recorded the highest maize grain yield followed by on 30 June in both years. Likewise, a yield penalty of 27.16–28.59% and 21.69–24.43% was registered with maize sown on 15 July as compared to maize sown on 15 June at Ludhiana and Ladhowal, respectively over the years. New cultivars of maize outperformed at various planting densities at both locations. Planting density of 67.5 cm × 15 cm having 98,765 plants/ha gave a higher grain yield compared to 67.5 × 18 cm (82,305 plants/ha) at both locations. Among the different cultivars, ‘JH 19014’ (5.35–5.03 t/ha) and ‘JH 17011’ (5.31–5.17 t/ha) performed superior over ‘PMH 13’ (5.18–4.87 t/ha) at both locations.

Influence of Heating Temperature on the Ink Transfer to Polymer Substrates in the Retransfer Printing Process

This study explores the effect of heating temperature on the ink transfer to Poly(vinyl chloride) and Poly(ethylene terephthalate) substrates in a specific retransfer printer. A notable correlation between heating temperature and solid color density was observed. The color density increases with heating temperature until reaching a critical threshold, typically around 140°C. Beyond this threshold, color density begins to decline due to ink penetration into the substrate, reducing ink film thickness on the surface of the substrates. This critical temperature is predominantly influenced by the properties of the ink rather than the characteristics of the substrate. The experimental study also reveals that variations in temperature-dependent ink transfer lead to noticeable color differences compared to standard references. An optimal temperature range of 120°C to 140°C was established, within which the process colors conform to the ISO 12647 standard, achieving DE values below 5. These results highlight the importance of maintaining appropriate ink transfer conditions to ensure precise color reproduction in printing processes.

Production of sterile trout (Triploids) by chromosome set manipulation using thermal shock treatment in rainbow trout (Oncorhynchus mykiss) from Kashmir Himalayas.

Rainbow trout (Oncorhynchus mykiss) is a promising cultivable fish species with significant potential for expansion. As a cold-water fish belonging to the Salmonidae family, it requires an optimal temperature range of 10-15°C for optimal growth. This study explores a method for producing sterile rainbow trout with maximum survival rates by using heat shock treatment to enhance growth characteristics and improve aquaculture practices. A control group and four heat shock treatments were given at 26°C and 28°C for 10 min, applied 15 and 20 min after the mixing of eggs and milt, using a water bath. Among the treated groups, the highest fertilisation, hatching and yolk sac absorption rates were 90.3 ± 0.3%, 81.8 ± 0.8% and 83.9 ± 0.5%, respectively. The highest triploidy rate of 76.6 ± 3.3% was observed with a heat shock at 28°C, 20 min after fertilisation. In contrast, none of the fish from the control group were triploids. The control group demonstrated higher survival rates at fertilisation (93.1 ± 0.4%), hatching (84.2 ± 0.4%) and complete yolk sac absorption (86.2 ± 0.5%) compared to the heat-shocked groups. The diploid and triploid chromosome numbers in rainbow trout were determined to be 2n = 60 and 3n = 91, respectively. This study confirms that heat shock treatment can effectively induce triploidy in rainbow trout, with significant variations in triploidy rates depending on the temperature and timing of the shock. While heat shock can enhance the production of sterile fish, it is essential to balance the treatment parameters to maintain high survival rates. These findings contribute to the optimisation of triploidy induction techniques and support the advancement of aquaculture practices by improving the growth, management and survival rates of rainbow trout which could significantly benefit aquaculture efficiency and sustainability.

Thermal Performance Enhancement of Serpentine Cooling Design Using Branch Modification for Lithium-Ion Batteries

Lithium iron phosphate (LiFePO4) batteries offer advantages such as low cost, safety, environmental compatibility, and stability over repeated cycles. However, when subjected to high currents, this battery generates thermal issues, particularly when arranged in packs. This study aims to maintain the LiFePO4 80Ah battery within an optimal temperature range (20 °C – 40 °C) while minimizing pumping power. The proposed research introduces a serpentine channel with additional branches. The design variations include a gradient in branch spacing and changes in channel width. Each design is evaluated using dimensionless parameters representing maximum temperature, temperature uniformity, pumping power, and cooling efficiency coefficient. The best design from each variation is then compared with the conventional serpentine (CS) channel design, which is well-known for its superior thermal performance. The gradient variation reduces 𝑇𝑚𝑎𝑥∗ and 𝑇𝜎 by 0.07 and by 0.42, respectively, compared to the non-gradient channel design, at a Re 400 and a C-rate 3 C. The design with the largest channel width reduces 𝑇𝑚𝑎𝑥∗ by 0.57 or 11.32 °C compared to the design with the smallest channel width. At a Re 1000 and C-rate 3 C, the reduction in 𝑇𝑚𝑎𝑥∗ for the proposed channel design compared to the CS design is 0.017. In terms of the friction factor (𝑓), the proposed design is 0.0149 lower than the CS design. The results indicate that the thermal performance of the proposed channel design is better than that of the CS design, with reduced pumping power.

Hypothermia During Microsurgical Head and Neck Reconstruction and Incidence of Venous Thromboembolism

Venous thromboembolism (VTE) is a severe complication after microsurgical free tissue transfer (FTT) to the head and neck. Hypothermia during surgery is a modifiable risk factor, and avoiding it may reduce the postoperative VTE rate. To assess the association between hypothermia (temperature <36 °C) and postoperative VTE and free flap pedicle thrombosis rates after head and neck reconstruction with FTT. This retrospective cohort study in a tertiary academic referral center used prospective and retrospective database and medical record data collected for patients who underwent head and neck reconstruction with FTT between January 1, 2012, and August 31, 2023. Temperature over time was classified as normothermia (temperature ≥36 °C), hypothermia (<36 °C) for more than 30 minutes and less than 120 minutes, and hypothermia for 120 minutes or more. Venous thromboembolism. The study outcomes were VTE events and thrombosis of the free flap pedicle that required revision surgery. Univariable and multivariable regressions were used to test the association between the outcomes and clinical factors. A total of 1078 patients (mean [SD] age, 61.3 [12.6] years; 724 males [67.2%]; mean [SD] Caprini score, 6.4 [2.1]) were included. The VTE and pedicle thrombosis rates were 3.2% (35 patients) and 2.2% (24 patients), respectively. In a multivariable model controlled for Caprini score and chemoprophylaxis, VTE was associated with hypothermia of more than 30 minutes and less than 120 minutes (odds ratio [OR], 3.82; 95% CI, 0.99-14.07) and hypothermia of 120 minutes or longer (OR, 3.55; 95% CI, 1.05-11.95). Free flap pedicle thrombosis was not associated with hypothermia (OR, 0.61; 95% CI, 0.26-1.43). These findings suggest that preventing hypothermia during microsurgical FTT to the head and neck may decrease the postoperative rate of VTE. Future studies should explore the optimal intraoperative body temperature range that may prevent the development of VTE without compromising patient safety.

Exploring pyrolysis-based alternatives for the valorization of used diapers through a comprehensive understanding of all generated products

This study provides an in-depth evaluation of a pyrolysis process designed for the valorization of baby diaper waste from the rejected fraction of municipal solid waste treatment facilities. The diapers were separated, identified, and classified into distinct fractions/layers, each subjected to Thermogravimetric Analysis to determine the optimal temperature range for operation. This study identified that hydrogen and methane production is maximized at 575 °C. At this temperature, yields reach up to 7.4 mmol of hydrogen and 6.3 mmol of methane, with a total of 23 mmol of non-condensable gases per gram of diaper waste. The temperature of 525 °C optimized the production of lighter liquid fractions. This temperature yielded compounds with boiling points similar to heavy naphtha and comprised over 63 % of the liquid products. The solid residue resulting from pyrolysis was a partially amorphous carbonaceous material, with a maximum surface area of 9.7 m2/g achieved at 575 °C, which is considered low. The analysis is completed with a study of the degradation of the used diapers by TGA/MS-FTIR and the determination of the effective activation energy as a function of conversion. This study highlights the significant potential of pyrolysis technology for treating diaper waste, which generates several potentially usable or valuable products, including hydrogen, methane, light liquid compounds, and carbonaceous material.

Estimating the burden of temperature-related low birthweight attributable to anthropogenic climate change in low-income and middle-income countries: a retrospective, multicentre, epidemiological study.

Pregnant individuals are particularly susceptible to non-optimal temperatures due to their physiological status. Moreover, pregnancy is a crucial period for programming fetal health. Quantifying the impact of non-optimal temperature exposure and the contribution of anthropogenic climate change is crucial for mitigating and adapting to climate-related health risks. However, this has not been thoroughly studied in pregnant individuals in low-income and middle-income countries (LMICs). Using data from 511 449 births across 31 LMICs from 1990 to 2018, we linked climate simulations (with and without anthropogenic forcing) to spatiotemporally resolved temperature data and birthweight records. We assessed the association between heat and cold exposure (ie, >90th and <10th percentile of temperature by region) during pregnancy and birthweight across different regions. We then used temperature simulations from both historically forced and natural-only forced climate models to estimate changes in exposure due to anthropogenic climate change and to quantify the burden of temperature-related low birthweight (ie, a birthweight <2500 g) attributable to anthropogenic climate change. Heat exposure during pregnancy, compared with the optimal temperature range, was associated with an increased risk of low birthweight in several regions: southern Asia (odds ratio 1·41, 95% CI 1·34-1·48), western Africa (1·12, 1·02-1·24), and eastern Africa (1·40, 1·27-1·55). Cold exposure increased the risk of low birthweight in central Africa (1·31, 1·10-1·56), southern Africa (1·18, 1·02-1·36), and eastern Africa (1·14, 1·02-1·26). Anthropogenic climate change contributed to approximately 59·2% (95% CI 16·6-94·3), 89·0% (51·0-100·0), and 77·3% (27·0-100·0) of heat-related low birthweight cases in southern Asia, western Africa, and eastern Africa, respectively. Conversely, in regions where cold exposure was predominant, anthropogenic climate change reduced the burden of low birthweight. Our study provides quantitative estimates of the contribution of anthropogenic climate change to the low birthweight burden in LMICs. These findings can inform strategies for climate mitigation and adaptation in LMICs and help reduce global health inequalities. National Natural Science Foundation of China.

Earth's Climate History Explains Life's Temperature Optima.

Why does the growth of most life forms exhibit a narrow range of optimal temperatures below 40°C? We hypothesize that the recently identified stable range of oceanic temperatures of ~5 to 37°C for more than two billion years of Earth history tightly constrained the evolution of prokaryotic thermal performance curves to optimal temperatures for growth to less than 40°C. We tested whether competitive mechanisms reproduced the observed upper limits of life's temperature optima using simple Lotka-Volterra models of interspecific competition between organisms with different temperature optima. Model results supported our proposition whereby organisms with temperature optima up to 37°C were most competitive. Model results were highly robust to a wide range of reasonable variations in temperature response curves of modeled species. We further propose that inheritance of prokaryotic genes and subsequent co-evolution with microbial partners may have resulted in eukaryotes also fixing their temperature optima within this narrow temperature range. We hope this hypothesis will motivate considerable discussion and future work to advance our understanding of the remarkable consistency of the temperature dependence of life.

Physiological plasticity and life history traits affect Chamelea gallina acclimatory responses during a marine heatwave.

The striped venus clam (Chamelea gallina) is a relevant economic resource in the Adriatic Sea. This study explored the physiological status of C. gallina at four sites selected along a gradient from high to low incidence of recorded historical mortality events and low to high productivity in the Northwestern Adriatic Sea. Investigations were performed during the marine heatwave in 2022 (from July to November). The optimal temperature range for C. gallina was exceeded in July and September, exacerbating stress conditions and a poor nutritional status, particularly at the low productivity sites. Transcriptional profiles assessed in digestive glands showed that clams from the low productivity sites up-regulated transcripts related to feeding/digestive functions as a possible compensatory mechanism to withstand adverse environmental conditions. Clams from the high productivity sites, that in a previous study showed enrichment of health-promoting microbiome components, displayed a healthier metabolic makeup (IDH up-regulation) and induction of protective antioxidant and immune responses. These features are hallmarks of putative enhanced resilience of the species towards environmental stress. Despite the well-known high sensitivity of C. gallina to environmental variations and its narrow window of acclimatory potential, results highlight that local conditions may influence physiological plasticity of this clam species and shape either positively or negatively its response capabilities to environmental changes. The identification of health-promoting endogenous mechanisms both from the animal (this study) and from its associated microbiome may provide the foundation for developing novel tools and strategies to improve clam health and production in low productivity areas or under adverse environmental conditions.

The effects of temperature and CO2 enrichment on the red seaweed Asparagopsis taxiformis from Southern California with implications for aquaculture.

The red alga Asparagopsis taxiformis has recently been recognized for its unique ability to significantly reduce methane emissions from ruminant animals when fed in small quantities. The main obstacle in using this seaweed as a methane-mitigating feed supplement is the lack of commercially available biomass. Little is known about how best to grow this red alga on a commercial scale, as there are few published studies that have investigated the factors that influence growth, physiology, and overall performance. This study examined the effects of temperature and CO2 enrichment on the growth, photophysiology, and concentration of bromoform, the secondary metabolite largely responsible for methane reduction in A. taxiformis. A series of single and multifactor closed culture experiments were conducted on A. taxiformis collected, isolated, and cultured from populations in Southern California. We identified the optimal temperature range to be between 22 and 26°C, with significant short-term stress observed below 15°C and above 26°C. Carbon dioxide addition resulted in increased performance, when accounting for growth per CO2 use. In general, we observed the highest bromoform concentrations in algae with the highest growth rates, but these results varied among experiments. These findings indicate that through environmental control and by addressing limiting resources, significant increases in biomass production and quality can be achieved.

Determination of Optimum Temperature for Amount Lactic Acid Bacteria and Antioxidant Activity from Pickled Bamboo Betung Boobs (Dendrocalamus asper)

Pickled betung bamboo shoots (Dendrocalamus asper) are a traditionally fermented product and can potentially be a source of probiotics. Pickled bamboo shoots contain good microorganisms, namely LAB, which are bacteria that contribute to the food sector for natural fermentation. Fermentation of bamboo shoots produces antioxidant compounds at an optimum temperature range. The research aims to understand the optimum temperature for the amount of LAB and antioxidant activity in pickled betung bamboo shoots. This research is a laboratory experiment with 3 treatments, namely 100 grams of bamboo shoots fermented with pickled bamboo shoots at a temperature of 15℃ (K1), a temperature of 37℃ (K2), and a temperature of 40℃ (K3). The three treatments were incubated for 72 hours with 4 repetitions. The research stages included processing pickled bamboo shoots, isolating bacteria using the dilution series-pour plate method, and antioxidant testing using the DPPH method. The number of LAB is calculated using the Quebec Colony Counter. Data analysis used Anova and Duncan's test. The results obtained include that temperature influences the amount of BAL in pickled bamboo shoots with a value of p=0.016. The number of LAB at a temperature of 150C was 59.50, at a temperature of 37 129.74, and a temperature of 40 107.57. Temperature also affects antioxidant activity. The average values at temperatures of 15.37, 40℃ are 30.60%, 25.241%, and 16.8782% (% inhibition), 36.3655, 41.6775, 51.0757 (IC50). The optimum temperature for the number of BAL pickled bamboo shoots is 37°C, and the optimum temperature for the number of antioxidants is 15°C.

Germination, seed traits, and seedling vigor of Pilosocereus robinii (Cactaceae) from northwestern Cuba

Studies on the germination of Caribbean cacti are essential for conservation and ecological restoration programs. We evaluated the seed traits and germination response of Pilosocereus robinii under five temperatures and two light conditions and compared the vigor of the seedlings obtained. Seminal traits showed characteristics of orthodox seeds. Pilosocereus robinii seeds showed positive photoblastism and a range of optimal temperatures below 30°C. In all treatments where germination was suboptimal, the seeds demonstrated high recovery percentages when they were exposed to the optimal temperature. The vigor of the seedlings showed a behavior similar to germination. Our study shows that restoration plans for the species' populations are viable from seeds.

Simple and Scalable Manufacturing Process of Raney-Ni Electrode Via Dip-Coating Method for Alkaline Water Electrolysis

Green hydrogen from water electrolysis coupled with renewable energy is important to overcome the climate change crisis and drives the energy paradigm shift from fossil fuels to eco-friendly energy. Water electrolysis technology was first discovered in the 19th century, and hydrogen for ammonia synthesis was produced in a 165 MW water electrolysis system linked to the Aswan Dam in Egypt in the early 20th century. Currently, research is being actively conducted to implement a water electrolysis system using wind and solar power generation. Among water electrolysis technologies, alkaline water electrolysis has a high technological maturity based on its long history and has the advantage of being highly economical as it does not use precious metal catalysts. However renewable energy has intermittent and irregular power production characteristics, the water electrolysis system must include load-following technology that can follow load changes when connected to renewable energy.Most electrode materials used in alkaline water electrolysis are Ni-based catalysts, and Raney-Ni is an advanced catalyst through the enlarged specific surface area by forming an intermetallic compound layer such as combined with Ni, Al, and Zn on the surface of the Ni electrode. Complex structural electrodes including many pores are generally used in order to realize a zero-gap design in alkaline water electrolysis. VPS (vacuum plasma spraying), PVD (physical vapor deposition), and electroplating are generally used to form Raney-Ni on the surface of a complex structural substrate. However, above mentioned methods have a technical issue for scaling up the area of the electrode because certain conditions must be established in the vacuum chamber or plating bath.In this study, high-performance Raney-Ni electrode was manufactured using a dip-coating method which is to soak the Ni substrate in the slurry consisted of Al powder and polymeric binder. Heat treatment condition was adjusted to find the optimal temperature range for forming suitable Ni-Al intermetallic compounds on the Ni foam (NF) surface. As a result, the appropriate heat treatment temperature was 700 oC, and the prepared electrode was evaluated by linear sweep voltammetry (LSV) to confirm the hydrogen generation reaction performance. The ratio of polymer binder and Al was adjusted to confirm the optimal slurry viscosity to determine the optimal Al loading conditions on the surface of the complex structural NF. LSV, electrochemical impedance spectroscopy (EIS), and cyclic voltammetry (CV) were conducted to measure HER performance of prepared Raney-Ni electrodes. Fig. 1a. shows a comparison of HER performance between conventional NF and prepared electrode, and the Raney Ni/NF is achieved for low overpotential of more than 170 mV at the current density of -0.3 A/cm2. In addition, the outstanding kinetics of Raney-Ni were confirmed on the Tafel slope (Fig. 1b). Performance improvement was investigated through CV analysis by improving the electrochemically active area due to the Ni-Al intermetallic compound layer formed on the Ni surface. As shown in 1c, the improvement in surface roughness was confirmed through SEM analysis (Fig. 1c).It is important to respond to load fluctuations from renewable energy and the durability of components in electrolytic stack because the value of alkaline water electrolysis lies in high economy for utilizing surplus energy from renewable energy. Durability and responsiveness were confirmed by repeatedly applying currents from -0.03 to -0.3 mA/cm2 of electrolytic cell equipped with the manufactured Raney-Ni electrode for 100 cycles. The excellent HER performance of the Raney-Ni electrode, which was already confirmed through the previous electrochemical analysis, was also confirmed in repeated current application experiments, and excellent responsiveness and durability were also confirmed (Fig. 1d). It was confirmed that the prepared Raney-Ni electrode showed high responsiveness, with voltage appearing immediately according to the applied current (Fig. 1e). Additionally, there was small or no changes of performance despite repeated load fluctuations during 100 cycles (Fig. 1f).In the previous experiment, HER performance, responsiveness, and durability were confirmed through a half-cell experiment. The water electrolysis efficiency of the prepared electrode was confirmed through in-situ analysis, and durability was confirmed for over 100 hours in a constant current condition. In addition, the electrode corrosion resistance caused by shunt current, which is important in the alkaline water electrolysis stack, was confirmed through the alkaline water electrolysis stack equipped with the prepared electrode and stack was performed on/off test over 100 cycles. As a result, the electrode showed only low performance degradation. Finally, an m2 electrode was manufactured by dip-coating method, and to conduct performance evaluation through the sample which is at a random location with a size of 25 cm2. Samples achieved uniform performance, although efficiency difference was observed. Figure 1

Designing Artificial Laccase Catalysts by Introducing Substrate Oxidation Metals into Oxygen-Reducing Metal-Organic Frameworks: Cu-Doped ZIF-67.

Laccase, a multi-copper oxidase, is limited by its optimal temperature range and isolation costs. To overcome these challenges, we synthesized copper-doped zeolitic imidazolate framework-67 (Cu-doped ZIF-67) with 16 mol % Cu as an artificial laccase catalyst. The introduced Cu site acts as the phenol oxidation site, and Co-based ZIF-67 is the four-electron oxygen reduction site. Laccase also employs this division of oxidation and reduction sites. Cu-doped ZIF-67 demonstrated significant catalytic activity, superior to natural laccase, especially at elevated temperatures, and maintained stability across multiple reaction cycles. These findings suggest that Cu-doped ZIF-67 is a robust, reusable alternative for industrial applications requiring high thermal stability and efficient catalysis.

Study and optimization of the influence of the water tank temperature on the performance of a solar assisted multi-source heat pump drying system

Solar assisted air source heat pump drying (SASHPD) system has been widely studied due to its excellent energy saving and high dried quality of product. To improve system performance, the control logic of a solar assisted multi-source heat pump drying (SMSHPD) system was investigated, and the simulation model and the experimental platform were established in this paper. The seasonal operating characteristics of the air source heat pump drying (ASHPD), the SASHPD and the SMSHPD modes were studied. The energy consumption, coefficient of performance (COP) and specific moisture extraction rate (SMER) of the three drying systems were calculated and analyzed. Additionally, the water tank temperature were also measured to determine the seasonal control logic of the drying system. It was found that compared to the ASHPD system, in summer, the energy consumption of the SASHPD system was reduced by 33.06 %, and COP and SMER was increased by 49.4 % and 49.38 %, respectively. Moreover, because of the high ambient temperature and water tank temperature, the experimental results indicated that only the SASHPD control logic should be implemented in summer. The maximum error of the simulation results was 9.1 % and the accuracy of the simulation model was confirmed. In autumn, the lower water tank temperature after drying illustrated that the solar energy can be more fully utilized, which explained why the performance of the SMSHPD mode was increased by 6.5 % compared to the SASHPD mode. Consequently, it is necessary to implement the SMSHPD control logic in autumn. Moreover, the operating temperature of the water source heat pump drying mode in autumn was optimized and the optimal temperature range was 28–54 °C. The average COP in one week after optimization was 6.21 % higher than that of the original operating temperature. Based on the validated simulation model, the optimal operating temperatures in spring and winter were also calculated and the control logic of the SMSHPD system operating in the four seasons were all obtained. This paper has important guiding significance for the reasonable choice of the control logic of a solar combined air source heat pump drying system.