Unit Surface Area Research Articles

Graphitic Nature Governs CO2 Hydrogenation Reactions on Platinum@Carbon Nanocomposites

In this study, we discuss the influence of carbon support on the performance of platinum nanoparticles (Pt-NPs) in gas-phase CO2 hydrogenation towards industrially demanding CO production. To this end, Pt-supported on graphite oxide, carboHIPE, activated carbon, multiwalled carbon nanotubes (MWCNT), and graphite of different specific surface areas and degree of graphitization were synthesized with identical loading per unit surface area (25 µg Pt/m2 of support) to reveal the contribution of the carbon support. All Pt@carbon nanocomposites were selective to CO at temperatures above 800 K, however, we found an additional correlation between their catalytic performance and the degree of graphitization of the support. Graphite-supported platinum (Pt@Graphite) has the highest TOF and the lowest activation energy among the studied nanocomposites due to the increasing electron donation from the carbon support to the Pt nanoparticles, which facilitates CO2 adsorption on Pt by shifting its d-band centre towards the Fermi level. Our study shows that beside surface area, porosity, thermal stability, a further parameter needs to be taken into consideration, as the Pt/C interface has significant effect at the atomic level on the activity of carbon-supported catalysts in gas-phase CO2 hydrogenation towards CO production.Graphical

Expectation values of conserved charges in integrable quantum field theories out of thermal equilibrium

Abstract In this work we present a computation of the averages of conserved charge densities and currents of (1+1)-dimensional Integrable Quantum Field Theories in Generalised Gibbs Ensembles. Our approach is based on the quasi-particle description provided by the Thermodynamic Bethe Ansatz combined with the principles of Generalised Hydrodynamics, and we focus on Non-Equilibrium Steady State averages. When considering the ultraviolet (i.e. high temperature) limit of such averages, we recover the famous result by Bernard and Doyon (2012) for the energy current and density in Conformal Field Theories, and we extend it to conserved quantities with spin $s > 1$. We show that their averages are proportional to $T_L^{s+1}\pm T_R^{s+1}$, with $T_L$, $T_R$ the temperatures of two asymptotic thermal reservoirs. The same power law is obtained when considering some non-thermal generalised Gibbs states. In Conformal Field Theory, the power law is a consequence of the transformation properties of conserved charge operators, while the proportionality coefficient depends on the spin of the operator and on the central charge of the theory. We present an exact analytic expression for this coefficient in the case of a massive free fermion. At equilibrium, proportionality of spin-$s$ density averages to $T^{s+1}$ can be thought of as a generalisation of Stefan-Boltzmann's law, which states that the energy per unit surface area radiated by a black body scales as $T^4$.

Mango fruit diseases severity estimation based on image segmentation and deep learning

Plant disease severity is the ratio between the surface area of disease symptoms and the total surface area of the plant unit (e.g. fruit, leaf). It is related to plant disease diagnosis and has several advantages for farmers. It is therefore a key element in the protection and management of plant diseases. In the literature, there are three proposed categories of plant disease severity determination solutions: solutions based on segmentation algorithms, solutions based on classical ML algorithms and those based on DL algorithms. Despite their several advantages, these solutions have a number of limitations, including i) subjectivity in data labeling, ii) loss of information on disease lesion contours during (manual) data labeling, and iii) the proposed solutions have focused on estimating plant disease severity from leaves, although diseases can also affect other parts of the plant, such as fruits. In this paper, we present a solution for estimating the severity of four mango fruit diseases, namely Alternariose, Anthracnose, Aspergillus rot and Stem rot. This solution is based on ResNet50 CNN and uses a dataset automatically labeled by a proposed algorithm based on two segmentation algorithms such as image color space segmentation and image thresholding. The solution has achieved an accuracy, a precision and a F1_score of 97.82%, 97.09% and 97.79%, respectively, on test data It is then deployed in a mobile application with a diagnostic solution we previously proposed. This mobile application will help mango growers, particularly those in Sahelian countries like Senegal, to manage their mango diseases earlier.

Investigation of Reaction Dynamics of Methane Reforming on Nickel Clusters Using Molecular Dynamics Simulations

This study employed molecular dynamics simulations utilizing the ReaxFF force field to elucidate the mechanisms underlying methane decomposition and hydrogen generation on nickel clusters (Ni37, Ni55, and Ni80). The transformation of methane into valuable products, including carbon species and hydrogen molecules, is of considerable significance owing to the abundance of methane and its potential role as an atmospheric pollutant. The findings suggest that Ni37 clusters had the highest initial reactivity, although they deactivated swiftly; conversely, Ni55 and Ni80 exhibited more consistent reaction rates. The highest efficiency of hydrogen production per unit surface area was displayed by Ni55 clusters within 100,000 fs, demonstrating a balance between reactivity and stability. Methane dissociation on the Ni55 clusters occurred in multiple stages. Two distinct mechanisms for hydrogen formation were identified: simultaneous dissociation from methane and migration and the combination of hydrogen atoms on the cluster surface. Ni55 showed a substantially lower activation energy for methane dissociation at 0.5 eV than bulk nickel, suggesting a higher degree of reactivity. Conversely, the activation energy for hydrogen formation was 1.1 eV. These results highlight the potential of the Ni55 clusters as effective catalysts for hydrogen production and methane conversion

Unveiling the Adsorption‐Desorption Mechanism in Phosphorus‐Doped Activated Carbon for Enhanced Double‐Layer Pouch‐Cell Supercapacitors

AbstractActivated carbon (AC) suffers from low energy density in the organic system of electric double‐layer capacitors (EDLCs). Currently, the research spotlight for enhancing the specific capacitance of AC in EDLC is to optimize the pore size distribution and enhance the specific surface area, but the increase of porosity in turn decreases the conductivity of AC. The surface modification is an effective strategy to improve the surface properties of carbon electrodes and enhance electrochemical performance. However, little attention has been paid to the interaction between AC surface and organic electrolyte. In this work, we have developed a phosphorus doping aimed at modulation of adsorption/desorption dynamics of organic electrolytes on the AC electrode. It was found that the phosphorus‐carbon bonding increases the adsorbed amounts of TEA+/BF4− per unit surface area, altering the charge storage mechanism and leading to improved specific capacitance. Furthermore, we fabricated a symmetrical pouch‐cell supercapacitor with an energy density of 36.2 Wh kg−1. The capacitance retention of 93.7 % was maintained after 30,000 cycles at a current density of 10 A g−1. These findings significantly advance our understanding of the charge storage dynamics in phosphorus‐doped AC and will guide the design of improved carbon‐based supercapacitors.

Mobilisation and replenishment of phosphorus reserves in Bos indicus cows. 2. Mature lactating cows fed diets deficient or adequate in phosphorus

Context Pastures growing on low phosphorus (P) soils are often P deficient, particularly for lactating cows. Aim To examine the effects of P-deficient diets on the performance of lactating multiparous cows. Methods From parturition, mature Bos indicus cross cows (n = 32, initially 474 kg liveweight (LW) and body condition score 3.5) were fed ad libitum for 14 weeks one of four diets: (i) high P (HP-HCa), (ii) low P with low calcium (LP-LCa), (iii) low P with high Ca (LP-HCa), or (iv) the LP-LCa diet with ammonium chloride (LP-LCa+ac). Results Voluntary feed intakes were higher for cows fed the HP-HCa than the three LP diets (23.1 vs 17.4–19.6 g DM/kg LW.day; P < 0.001). The HP-HCa cows gained 0.15 kg LW/day, whereas LP cows lost 0.14–0.51 kg LW/day; P < 0.05). The cows fed LP diets generally maintained milk production and calf growth comparable to that of HP-HCa cows (5.8 kg/day and 0.70 kg/day). The HP-HCa cows retained 6.0–6.4 g P/day from weeks 1–8, but P retention was negligible at week 14. The LP cows mobilised 4.9–9.1 g body P/day. Rib cortical bone shortly after parturition was 634 ± 127 (337–848) μg P/mm2 in the 12th rib, and indicated that the bone P reserves were deficient, marginal and adequate in 27, 37 and 37% of the cows, respectively. During lactation, rib bone P increased 23% in HP-HCa cows, changed little in the LP-LCa and LP-HCa cows (−4 and +7%), and decreased 13% (P < 0.05) in LP-LCa+ac cows. The change in rib cortical bone P during lactation was correlated with this measurement at parturition; the P per unit surface area of rib cortical bone of cows with low bone P at parturition did not change, but in cows with high bone P it decreased up to 16%. Plasma inorganic P averaged 1.49 mmol/L in the HP-HCa cows and <0.8 mmol/L in the LP cows. Plasma Ca, Ca/inorganic P ratio, 1,25-dihydroxy vitamin D3, bone alkaline phosphatase, and carboxy-terminal telepeptides of type 1 collagen increased during lactation (P < 0.05 to P < 0.001) in the LP cows. Conclusions When fed acutely P-deficient diets, mature cows of moderate LW and with body condition scores at parturition generally maintained milk secretion and calf growth by mobilisation of body reserves. Implications The capacity of beef cows to maintain lactation when ingesting P-deficient diets provides opportunities for improved herd management.

The effect of hot corrosion on mechanical properties of the tin-doped titanium aluminide alloy

This work investigates the hot corrosion behaviour of Ti-48Al-2Nb-0.3Si and Ti-48Al-2Nb-0.3Si-1Sn alloys under 25 wt.% NaCl and 75 wt.% Na2SO4 molten salt mixture at 900 °C. The alloys were developed through vacuum arc melting and casting. The corrosion kinetics of the alloys were measured by mass change per unit surface area. The results revealed that both alloys experienced hot corrosion attacks; however, Ti-48Al-2Nb-0.3Si-1Sn alloy demonstrated superior corrosion resistance and retained good mechanical properties compared to the Ti-48Al-2Nb-0.3Si.

Understanding how the structures of surfactants in hybrid nanoparticles affect the compaction of ct-DNA for cellular uptake: presenting a highly efficient surfactant.

Compaction of calf thymus DNA (ct-DNA) by two single-head-double-tailed surfactants with variable tail lengths i.e., Dihexadecyldimethylammonium bromide (DDAB16) and Dioctadecyldimethylammonium bromide (DDAB18), and one triple-head-double-tailed surfactant N1-dodecyl-N2-(2-(dodecyldimethylammonio)ethyl)-N1,N1,N2,N2-tetramethylethane-1,2-diaminium (MQAS12) has been studied. DDAB18 is found to be the most efficient, while MQAS12 is the least efficient for cellular uptake. Hybrid materials of surfactants and silica nanoparticles have better compaction efficiency due to the cooperative binding. Silica nanoparticles (∼100 nm)-DDAB18 hybrid materials can compact ct-DNA at a much lower concentration than a conventional surfactant, addressing the cytotoxicity issues. Hybrid materials formed with smaller silica nanoparticles (∼40 nm) have also been studied. The results obtained have been used to understand whether Coulombic and/or hydrophobic interactions are responsible for DNA compaction. The hydrophobicity per unit surface area (P) of hybrid nanoparticles has a significant role in DNA compaction. The P largely depends on the surfactants' structures and nanoparticles' sizes. Single-head-double-tailed surfactants with a comparatively smaller headgroup exhibit a large amount of adsorption on the nanoparticles' surfaces, producing a large P. DDAB18 appears to be a DNA intercalative binder. Fluorescence anisotropy decay data of 4,6-diamidino-2-phenylindole (DAPI) reveal the dynamics of ct-DNA at different stages of compaction. Cell viability of mouse mammary gland adenocarcinoma cells (4T1) and human embryonic kidney (HEK) 293 cell lines and in vitro cellular uptake of the gene to 4T1 cells have been investigated. This study provides ideas for designing efficient non-viral vectors. Overall, DDAB18-coated silica nanoparticles appear to be safe and effective DNA compaction agents that can carry nucleic acids for biomedical applications.

COMPARISON BIOFILM CHARACTERISTICS ON DIFFERENT TYPES OF CARRIERS FOR WASTEWATER TREATMENT

Enhancing the operational efficiency of wastewater treatment plant can be achieved by increasing the biomass concentration within the reactor volume. For this purpose, the use of immobilized microorganisms on carriers has become progressively prevalent in wastewater biological treatment technologies, aiming to enhance the quality of treated water. The analysis of the characteristics biofilms on spherical, disc-shaped and wheel-shaped on carriers under the same conditions was carried out. All investigated carriers are classified as dispersed, distributed throughout the volume of the air tank. The following characteristics of four biofilm carrier samples were investigated: the concentration of biomass immobilized on the surface of the carrier and the specific biomass per unit area of surface for different types of loading for the treatment of domestic wastewater. It has been determined that the biomass concentration immobilized on the surfaces of four distinct carriers, varying in shape and size, spans from 5425 mg/dm3 to 138 mg/dm3. The study showed that the carriers with a diameter of Ø 9.95 mm had the highest biomass concentration immobilized on the surface, and such carrier can be effectively used in MMBR systems for wastewater treatment, as well as to improve the performance of aeration tanks by upgrading them. The choice of biofilm carrier is a critical factor as it influences the optimal thickness of the biofilm, biomass growth, and the efficiency of various natures pollutants biodegradation.

Ice nucleating ability of mineral particles from subtropical South American deserts

Ice nucleating ability of mineral particles from subtropical South American deserts

Adsorption of fulvic acid on clay subfractions isolated from mineral horizons of peat-podzol-gley soil

We studied the adsorption of fulvic acid (FA) obtained from the H horizon of peaty-podzolic-gleyic soil on sludge subfractions isolated from the ELG and Ecng horizons of the same soil: 0–0.2 µm (I), 0.2–0.06 µm (II) , 0.06–0.02 µm (III) and <0.02 µm (IV). It has been established that, in terms of unit mass, more FAs are sorbed by subfractions III and IV, which have a larger surface area. In terms of per unit surface area, an inverse relationship is observed: the larger the fraction, the more FA is sorbed on it. All subfractions of sludge isolated from both horizons sorb predominantly hydrophobic components of FA, but in the finer subfractions, which practically do not contain kaolinite, the contribution of hydrophilic components in total sorption increases. Under the experimental conditions, FA molecules with a molecular weight of 20 kDa were not adsorbed in micropores with an average size of ≈ 3.7 nm. The main mechanism of FA sorption on sludge subfractions is hydrophobic interactions. The hydrophilic components of FA are sorbed through electrostatic interactions, through ligand exchange on lateral cleaved clay minerals and with the formation of bridging bonds with the Ca2+ ion occupying exchange positions in clays.

Dry powder inhaler deposition in the larynx and the risk of steroid inhaler laryngitis: A computational fluid dynamics study

Dry powder inhaler deposition in the larynx and the risk of steroid inhaler laryngitis: A computational fluid dynamics study

Microstructural Evaluation and Linkage to the Engineering Properties of Metal-Ion-Contaminated Clay.

The rapid progress of urbanization and industrialization has led to the accumulation of large amounts of metal ions in the environment. These metal ions are adsorbed onto the negatively charged surfaces of clay particles, altering the total surface charge, double-layer thickness, and chemical bonds between the particles, which in turn affects the interactions between them. This causes changes in the microstructure, such as particle rearrangement and pore morphology adjustments, ultimately altering the mechanical behavior of the soil and reducing its stability. This study explores the effects of four common metal ions, including monovalent alkali metal ions (Na+, K+) and divalent heavy metal ions (Pb2+, Zn2+), with a focus on how ion valence and concentration impact the soil's microstructure and mechanical properties. Microstructural tests show that metal ion incorporation reduces particle size, increases clay content, and transforms the structure from layered to honeycomb-like. Small pores decrease while large pores dominate, reducing the specific surface area and pore volume, while the average pore size increases. Although cation exchange capacity decreases, cation adsorption density per unit surface area increases. Monovalent ions primarily disperse the soil structure, while divalent ions induce coagulation. Macro-mechanical tests reveal that metal ion contamination reduces porosity under loading, with compressibility rises as the ion concentration increases. Soils contaminated with alkali metal ions shows higher compression coefficients at all loads, while heavy metal ions cause higher compression under lower loads. Shear strength, the internal friction angle, and cohesion in metal-ion-contaminated clay decrease compared to uncontaminated field-state clay, with greater declines at higher ion concentrations. The Micropore Morphology Index and hydro-pore structural parameter effectively characterize both micro- and macrostructural properties, establishing a quantitative relationship between HPSP and the engineering properties of metal-ion-contaminated clay.

Exploring the impact of nanoshaped ceria in the methanol decomposition reaction pathway for clean energy production

Exploring the impact of nanoshaped ceria in the methanol decomposition reaction pathway for clean energy production

Enhanced adsorption of tylosin by ordered multistage porous carbon and efficient in-situ regeneration of saturated adsorbents by activated persulfate oxidation: Performance, mechanism and multiple cycles

Enhanced adsorption of tylosin by ordered multistage porous carbon and efficient in-situ regeneration of saturated adsorbents by activated persulfate oxidation: Performance, mechanism and multiple cycles

A Comparative Study on the Corrosion Performance of A7, A36 and A588 Alloys at Different NaCl Concentration Exposure

Corrosion can significantly impact the performance of structures, and corrosion-related maintenance is a primary contribution to annual transportation infrastructure costs. The current NBI data reports that the poor condition of the bridges around US have increased by 10%, and 50% of the bridges in Connecticut are either in poor or fair condition. Bridges in the US share approximately 37% of the total annual cost due to corrosion. Bridges are primarily constructed of A7, A36, A588, and A242 steel. ASTM A7 steel was used in bridge construction until 1967. Major limitations of A7 steel include poor corrosion resistance and mechanical properties, which ultimately led to the replacement of A7 steel by A36 steel after 1967. Though A36 steel shows better mechanical properties, it does not possess improved corrosion performance compared to A7. A588 and A242, which are also called weathering steels, display significantly higher corrosion resistance paired with desired mechanical properties, but the cost of these so-called weathering steels is also higher. The present study aims at characterizing the corrosion performance of bridge steels A7, A36 and A588 under a wide range of chloride-rich environments so that we may improve our predictions for bridge longevity.A major portion of the existing literature on steel corrosion mechanisms considers the study of plain carbon steel. Plain carbon steels form corrosion products such as Goethite, Akageneite, Lepidocrocite, and Magnetite, having the chemical formulas α-FeOOH, β-FeOOH and γ-FeOOH and Fe3O4 respectively. γ-FeOOH forms during the initial stages of corrosion formation where Magnetite being the final product. β-FeOOH is an intermediate product but is detrimental for the performance of the bridge since the oxide formed is not protective.The addition of specific alloying elements in the bridge steel grades (including Cu) can heavily influence the corrosion mechanisms at work and subsequently the corrosion rates. Further, the exposure to various environmental conditions such as rain, snow, hail, wind, and thermal cycles will lead to successive wetting and drying conditions. Bridges in colder climates are exposed to de-icing salts that can accumulate on horizontal surfaces or within the corrosion products that form. Each of these factors makes accurate prediction of corrosion rates on specific bridge components difficult.The current study compares the corrosion performance of A7, A36 and A588 alloys at different NaCl concentration exposure (1 wt.%, 2 wt.%, 3.5 wt.% and 5 wt.%) for difference steel surface conditions (oxidized and polished). Corrosion studies on these alloys were performed using wet-dry cyclic exposure to obtain corrosion at an accelerated pace. Each wet-dry cycle consisted of 15 minutes of wetting and 1 hour drying period. Test coupons were in the size of 50 mm×25 mm×4.76 mm. A total of 400 wet/dry cycles were performed to determine the effect of longer exposure to salt environments. Batches of samples of each alloy were collected at 25, 50,75, 100, 150, 200, 250, 300, 350, 400 cycles to observe corrosion trends with increase in cycles. Further, the samples were photographed, and the surfaces were compared. Corrosion samples retrieved from bridges in Connecticut were compared to the lab-tested coupons. The phases present in the corrosion products were characterized using XRD and SEM. The results showed lower magnetite compared to the field samples, and the presence of detrimental β – FeO(OH,Cl) was significantly higher at the higher [Cl-] concentrations. Mass gain studies were performed by measuring the weight of each test coupon at regular intervals throughout the wet-dry cyclic testing. The mass gain per unit surface area of the sample was calculated for the different conditions. Cross-sections of the corroded samples were examined using optical light microscopy and SEM-EDS. These results will be used to build and validate a prediction tool for field evaluation of bridge corrosion.

Prediction and Prevention of Bridge Performance Degradation Due to Corrosion, Material Loss, and Microstructural Changes

Corrosion can significantly impact the performance of structures, and corrosion-related maintenance is a primary contribution to annual transportation infrastructure costs. The current NBI data reports that the poor condition of the bridges around US have increased by 10%, and 50% of the bridges in Connecticut are either in poor or fair condition. Bridges in the US share approximately 37% of the total annual cost due to corrosion. Bridges are primarily constructed of A7, A36, A588, and A242 steel. ASTM A7 steel was used in bridge construction until 1967. Major limitations of A7 steel include poor corrosion resistance and mechanical properties, which ultimately led to the replacement of A7 steel by A36 steel after 1967. Though A36 steel shows better mechanical properties, it does not possess improved corrosion performance compared to A7. A588 and A242, which are also called weathering steels, display significantly higher corrosion resistance paired with desired mechanical properties, but the cost of these so-called weathering steels is also higher. The present study aims at characterizing the corrosion performance of bridge steels A7, A36 and A588 under a wide range of chloride-rich environments so that we may improve our predictions for bridge longevity.A major portion of the existing literature on steel corrosion mechanisms considers the study of plain carbon steel. Plain carbon steels form corrosion products such as Goethite, Akageneite, Lepidocrocite, and Magnetite, having the chemical formulas α-FeOOH, β-FeOOH and γ-FeOOH and Fe3O4 respectively. γ-FeOOH forms during the initial stages of corrosion formation where Magnetite being the final product. β-FeOOH is an intermediate product but is detrimental for the performance of the bridge since the oxide formed is not protective.The addition of specific alloying elements in the bridge steel grades (including Cu) can heavily influence the corrosion mechanisms at work and subsequently the corrosion rates. Further, the exposure to various environmental conditions such as rain, snow, hail, wind, and thermal cycles will lead to successive wetting and drying conditions. Bridges in colder climates are exposed to de-icing salts that can accumulate on horizontal surfaces or within the corrosion products that form. Each of these factors makes accurate prediction of corrosion rates on specific bridge components difficult.The current study compares the corrosion performance of A7, A36 and A588 alloys at different NaCl concentration exposure (1 wt.%, 2 wt.%, 3.5 wt.% and 5 wt.%) for difference steel surface conditions (oxidized and polished). Corrosion studies on these alloys were performed using wet-dry cyclic exposure to obtain corrosion at an accelerated pace. Each wet-dry cycle consisted of 15 minutes of wetting and 1 hour drying period. Test coupons were in the size of 50 mm×25 mm×4.76 mm. A total of 400 wet/dry cycles were performed to determine the effect of longer exposure to salt environments. Batches of samples of each alloy were collected at 25, 50,75, 100, 150, 200, 250, 300, 350, 400 cycles to observe corrosion trends with increase in cycles. Further, the samples were photographed, and the surfaces were compared. Corrosion samples retrieved from bridges in Connecticut were compared to the lab-tested coupons. The phases present in the corrosion products were characterized using XRD and SEM. The results showed lower magnetite compared to the field samples, and the presence of detrimental β – FeO(OH,Cl) was significantly higher at the higher [Cl-] concentrations. Mass gain studies were performed by measuring the weight of each test coupon at regular intervals throughout the wet-dry cyclic testing. The mass gain per unit surface area of the sample was calculated for the different conditions. Cross-sections of the corroded samples were examined using optical light microscopy and SEM-EDS. These results will be used to build and validate a prediction tool for field evaluation of bridge corrosion.

Measuring the fire growth potential of combustible solids using a cone calorimeter

The fire growth rate of interior linings, furnishings, and construction materials is measured in full-scale fire tests such as the ASTM E84 Steiner Tunnel, the ISO 9705 room fire, and a passenger aircraft fuselage as the flame-spread rate, time-to-flashover, or time to incapacitation, respectively. The results are used to indicate the level of passive fire protection afforded by the combustible material or product in the test without providing any insight into the burning process. These large-scale tests require many square meters of product, are very expensive to conduct, and can exhibit poor repeatability–making them unsuitable for product development, quality control, product surveillance, or regulatory compliance. For this reason, smaller (0.01 m2) samples are tested in bench-scale fire calorimeters under controlled conditions, and these one-dimensional burning histories are correlated with the results of the two- and three-dimensional burning histories in full-scale fire tests by a variety of empirical and semi-empirical fire propagation indices, as well as analytic and computer models specific to the full-scale fire test. The approach described here defines the potential of a material to grow a fire in terms of cone calorimeter data obtained under standard conditions. The fire growth potential, λ (m2/J), is the coupled process of surface flame spread and in-depth burning that is defined as the product of ignitability (1/ E ign) and combustibility (Δ Q/Δ E) obtained from a combustion energy diagram measured in a cone calorimeter at an external radiant energy flux [Formula: see text] (W/m2) above the critical flux for burning, [Formula: see text]. However, the potential for fire growth, λ≡ (1/ Ei gn)(Δ Q/Δ E) is only realized as a hazard when the heat of combustion of the product per unit surface area, Hc (J/m2), is sufficient to grow the fire. The dimensionless fire hazard of a combustible product of thickness b is therefore, Π = λ Hc, while the fire hazard of the component materials is an average over the product thickness, π = Π/ b. The measurement of λ, Π, and π from combustion energy diagrams of heat release Q (J/m2) versus incident energy E (J/m2) is described, as well as a physical basis for a fire growth potential that provides simple analytic forms for λ in terms of the parameters reported in cone calorimeter tests. Experimental data from the literature show that rapid fire growth in full-scale fire tests of combustible materials occurs above a value of Π determined by the severity of the fire test.

Ecological investigations of giant Phaeocystis colonies in Viet Nam: I. Cell abundance and elemental composition.

Phaeocystis globosa is an important bloom-forming marine phytoplankton species that often accumulates to large levels in temperate and tropical waters and has significant impacts on food webs and biogeochemical cycles. It can form "giant" colonies that reach 3 cm in diameter. Microscopic observations, colony elemental composition, and pigment composition were analyzed to assess the characteristics of colonies as a function of colony size. Particulate organic carbon (POC) per unit surface area, colonial cell density, and chlorophyll a per unit surface area all increased with colony size, in contrast to results from temperate waters. Cellular chl a averaged 0.85 pg chl · cell-1. Colonies had both photosynthetic and protective pigments, with fucoxanthin being the dominant accessory pigment. Based on chl a and pigment levels, it appears colonies were acclimated to relatively low irradiances, likely due to their life cycle and the extremely turbulent environment in which they grew. Mucous carbon ranged from 16.2% to 79.2% of the total POC, and mucous carbon per unit surface area increased with colony size, suggesting that the mucous envelope did not thin as the colony grew. Based on elemental composition, nitrogen did not appear to limit growth, but phosphorus:carbon ratios were similar to those of P-limited cultures. Giant colonies represent an extreme response to the environment, but they do not appear to have greatly different characteristics than other tropical strains.

Design and study of the flow section of a variable microchannel reformer based on the coupling law of reforming with flow, heat and mass transfer

Design and study of the flow section of a variable microchannel reformer based on the coupling law of reforming with flow, heat and mass transfer