A Theory of Renewable Energy from Natural Evaporation

Cavusoglu, Ahmet-Hamdi

January 2017

About 50% of the solar energy absorbed at the Earth’s surface is used to drive evaporation, a powerful form of energy dissipation due to water’s large latent heat of vaporization. Evaporation powers the water cycle that affects global water resources and climate. Critically, the evaporation driven water cycle impacts various renewable energy resources, such as wind and hydropower. While recent advances in water responsive materials and devices demonstrate the possibility of converting energy from evaporation into work, we have little understanding to-date about the potential of directly harvesting energy from evaporation. Here, we develop a theory of the energy available from natural evaporation to predict the potential of this ubiquitous resource. We use meteorological data from locations across the USA to estimate the power available from natural evaporation, its intermittency on varying timescales, and the changes in evaporation rates imposed by the energy conversion process. We find that harvesting energy from natural evaporation could provide power densities up to 10 W m-2 (triple that of present US wind power) along with evaporative losses reduced by 50%. When restricted to existing lakes and reservoirs larger than 0.1 km2 in the contiguous United States (excluding the Great Lakes), we estimate the total power available to be 325 GW. Strikingly, we also find that the large heat capacity of water bodies is sufficient to control power output by storing excess energy when demand is low. Taken together, our results show how this energy resource could provide nearly continuous renewable energy at power densities comparable to current wind and solar technologies – while saving water by cutting evaporative losses. Consequently, this work provides added motivation for exploring materials and devices that harness energy from evaporation.

Chemical engineering

Renewable energy sources

Power resources

Evaporation

Evaporative power

Analysis of Pump Oil and Alkanes Evaporation

Waldstein, Nathaniel A

19 November 2008

There are many products, including hard drives, which require trace amounts, on the order of several mg, of lubricants for proper operation. The following study investigated the evaporation rates of pump oil and several alkanes, which have a wide range of applications, using a thermogravimetric machine. Both static and dynamic temperature tests were conducted. The rate of evaporation of the test specimen was determined as the percentage of mass loss per unit time. Using the Arrhenius Equation, the activation energy of the evaporation process, Ea, can be calculated as the slope of the best fit line for a plot of the ln(k) vs. 1/T (where k represents the rate of the evaporation). These values were shown to have good agreement with the enthalpy of vaporization calculated from the Clausius Clapeyron Equation and with the activation energy calculated using the Freeman and Carroll Method. The alkanes were compared using the rate of evaporation and the amount of activation energy required for evaporation as model systems. Further investigations were conducted to determine the relationship of surface area of the evaporating liquid and the rate of evaporation. It is suggested that the surface area is a function that depends on the activation, bonding, and interfacial energies of the liquid. However, the wetting angle, which aids in the description of the surface area, depends on the surface energy. Subsequent modeling was conducted in an attempt to predict the evaporation characteristics of other lubricants for the purpose of comparison.

Arrhenius Equation

Activation energy

Evaporation rates

American Studies

Arts and Humanities

Développement de méthodes instrumentales en vue de l'étude Lagrangienne de l'évaporation dans une turbulence homogène isotrope.

Chareyron, Delphine

16 December 2009

Cette thèse est centrée sur le développement d'outils expérimentaux permettant de mieux caractériser l'étude du couplage entre l'évaporation de gouttelettes et un écoulement turbulent gazeux environnant. Dans notre étude on cherche à se placer dans un régime de couplage fort entre les gouttelettes évaporantes et la turbulence. Dans ce régime peu renseigné dans la littérature, les gouttelettes se trouvent dans un régime intermédiaire entre le régime de traceur et le régime inertiel. Dans un premier temps nous présentons un dispositif expérimental capable de générer une turbulence homogène isotrope avec de fortes fluctuations de vitesse, ainsi que la réalisation de l'injection de gouttelettes initialement monodisperses. Puis, l'instrumentation Lagrangienne développée (en collaboration avec le laboratoire Hubert Curien de St-Etienne) : l'holographie numérique en ligne, est ensuite testée et validée pour un fluide non évaporant. Une méthode de tracking des gouttelettes a été mise au point afin de reconstruire les trajectoires des gouttelettes dans le volume turbulent homogène isotrope. La précision obtenue sur les diamètres (2% pour des gouttes de 60 μm) vient complètement valider cette métrologie pour l'étude de l'évaporation. Les premiers résultats obtenus avec des gouttelettes évaporantes de fréon R114 font apparaître la visualisation, à notre connaissance inédite, des sillages évaporants. Une première reconstruction de trajectoire avec l'évolution du diamètre de la goutte au cours du temps est enfin présentée.

[PHYS] Physics

Métrologie

Holographie numérique

ILIDS

Turbulence

Evaporation

Lagrangien

Diphasique

Preparation and characterization of Cu(In,Al)Se2 thin film

Wu, Wei-Jung

13 August 2010

Polycrystalline Cu(In,Al)Se2 films were deposited by four-source evaporation of Cu, In, Al, and Se using Knudsen type sources in which the elemental fluxes were coincident onto soda lime glass substrates. The single-phase films with composition of Cu:In:Al:Se = 28:15:9:48 which were confirmed by X-ray diffraction and micro-Raman spectroscopy were deposited at substrate temperature of 560¢J. Secondary phases were observed when temperature of substrate is below 560¢J due to incompletely reaction. Under fixed effusion flux, the value of Cu/(In+Al) becomes larger as temperature of substrate increase. However, the value of Al/(In+Al) keeps nearly constant as temperature increase. The band gap is 1.53 eV derived from the result of spectrophotometer. The room temperature resistivity, Hall mobility and carrier concentration of the films are 0.28 £[cm, 24.63 cm2V-1s-1 and 1.27x1019 cm-3 respectively. And the conductive type is p-type. By the way, we try to grow Cu(In,Al)Se2 film in the presence of an Sb beam at substrate temperature of 440¢J. After the addition of an Sb beam, surface morphology become smooth and compact, but there is no significant grain growth. No matter an Sb beam adds or not, secondary phases were observed in both case due to the low temperature of substrate.

thin film

evaporation

solar cell

Sb

Cu(InAl)Se2

A study of transverse moisture distribution and movement during hot-surface drying of paper

Dreshfield, Arthur Charles,

January 1956

Thesis (Ph. D.)--Institute of Paper Chemistry, 1956. / Includes bibliographical references (p. 95-97).

Fuel reformation and hydrogen generation in variable volume membrane batch reactors with dynamic liquid fuel introduction

Yun, Thomas

08 June 2015

In recent years, the need for high performance power sources has increased dramatically with the proliferation of ultra-compact electronic systems for mobile communication, man-portable and versatile military equipment, and electric vehicles. Volume- and mass- based power density are two of the most important performance metrics for portable power sources, including hydrogen generating fuel reforming systems (onboard) for hydrogen fuel cells. Two innovative multifunctional reactor concepts, CO2/H2 Active Membrane Piston (CHAMP) and Direct Droplet Impingement Reactor (DDIR), are combined for the purpose of hydrogen generating fuel reforming system (onboard) for fuel cells. In CHAMP-DDIR, a liquid fuel mixture is pulse-injected onto the heated catalyst surface for rapid flash volatilization and on-the-spot reaction, and a hydrogen selective membrane is collocated with the catalyst to reduce the diffusion distance for hydrogen transport from the reaction zone to the separation site. CHAMP-DDIR allows dynamic variation of the reactor volume to optimally control the residence time and reactor conditions, such as pressure and temperature, thus improving both the reaction and separation processes. A comprehensive CHAMP-DDIR model, which couples key physical processes including 1) catalytic chemical reactions, 2) hydrogen separation/permeation at membrane, 3) liquid fuel evaporation, and 4) heat and mass transport, has been developed to investigate the behavior of this novel reactor system, aiming at maximizing the volumetric power density of hydrogen generation from methanol/water liquid fuel. The relationships between system design parameters and the rate-limiting process(es), i.e., reaction, permeation, and transport, which govern reactor output, have identified. Experimental characterization of the prototype reactor has been performed for laboratory demonstration of the concept and model validation. Both model predictions and experiments successfully demonstrate the unique practical performance improvements of CHAMP-DDIR through combining time-modulated fuel introduction and the active change of reactor volume/pressure. This work has led to a number of fundamental insights and development of engineering guidelines for design and operation of CHAMP-DDIR class of reactors, which can be extended to a broad range of fuels and diverse practical applications.

Hydrogen

Reformation

Reactor

Droplet evaporation

Catalytic reaction

Membrane

Passive pumping, evaporation based system for multiscale thermal management

Crawford, Robert Vincent

16 October 2013

Drawing from the lessons of plant transpiration, this dissertation explores a biomimiced system for fluid transport and thermal regulation. This system utilizes evaporation and benefits from the associated passive pumping with an application of a rooftop solar radiation barrier in mind. By directing the incoming energy towards the phase change of water, lower surface temperatures can be maintained thus reducing heat transfer into the structure by conduction. In order to design and construct such a bio-inspired system, several parameters, i.e., the evaporation surface, the delivery path and the working fluid, must be understood as to how they affect and limit operations. Performance factors such as evaporation rate and suction pressure were monitored for the various design constraints of feeding tube length and diameter, membrane area, and working fluid. Additionally, as a heat flux was imposed on the membrane from above and below, the substrate temperature became important. Over the range of parameters tested, hydrodynamic resistances of the delivery path were shown to affect pumping height but not the evaporation rate. Instead, the evaporation rate was controlled by the substrate temperature. Furthermore, the normalized evaporation rate was found to be inversely related to the evaporation surface area. Under contaminated working fluid conditions, particles deposited in the membrane caused decreases in evaporation rates. When applied to a simulated roof situation, the evaporation system was successful at maintaining considerably lower surface temperatures than other conventional and unconventional roof albedos, which, in turn, would reduce heat flux into the interior by conduction. Lastly, in estimating the water consumption, on a typical August day in Austin, TX, the system could use up to 2 gallons/m² while providing enhanced cooling. When the system's resources were compared to being purposed in other ways, they were arguably better utilized in providing evaporative cooling. / text

Bio-inspired

Evaporation

Evaporative pumping

Heat removal

Porous membrane

Suppression of matrix interferences in electrothermal atomic absorption spectrometry using a fast-heated ballast atomiser

Banda, Maria Fenzile

January 2008

Thesis (MTech. degree in Chemistry)--Tshwane University of Technology, 2008. / This work is aimed at experimental verification of the theory about the advantages of the two-step sample vapour release in a fast-heated ballast furnace. The term “ballast” was introduced earlier in electrothermal atomic absorption spectrometry, as an alternative to a platform to describe a compact body of refractive material loosely located on the bottom of a tube furnace atomiser. The thermal behaviour of the ballast furnace is similar to that of the platform, but without restriction created by the platform area. Compared with the flat or concave platform, a compact ballast of similar mass to the platform should have less impact on gas temperature because of the smaller surface area. The theoretical predictions concerning atomisation efficiency in the fast-heated ballast furnace were examined by the determination of metals in organic and inorganic matrices using a Quantum Z.ETA atomic absorption spectrometer. The instrument provided fast heating of the tube atomizer, 10 K ms-1. It is shown that in the employed ballast furnace the vapour released into the gas phase occurs after interim condensation on the ballast. For the samples of tetraethyllead, base oil and aqueous solutions of various metals, analytical signals are observed after stabilisation of tube temperature, independent of volatility of the analyte and level of temperature setting. For those samples, a high gas phase temperature provides complete recovery of the analyte without involvement of chemical modifiers and the reduction of spectral interferences from chloride matrices.

Atomizers.

Furnaces -- Thermodynamics.

Furnace atomic absorption spectroscopy.

Condensation.

Evaporation.

Evaporation from streambed materials in the Tucson area

Sorey, M. L.

January 1967

No description available.

Bi-Sr-Ca-Cu-O thin films grown by flash evaporation and pulsed laser deposition

Ganapathy Subramanian, Santhana

30 September 2004

Bismuth-Strontium-Calcium-Copper-Oxide (BSCCO) compounds are an important family of compounds that have one of the highest transition temperatures among all high-temperature superconductors. The compound is known to exist in three distinct phases, commonly referred to as the 2201, 2212 and 2223 phases. Of these three phases, the 2212 and 2223 phases are the most important, as their transition temperature is higher than the boiling point of liquid nitrogen. It is desirable to produce the compound in thin film form, as the bulk samples are normally polycrystalline. This thesis compares thin films produced by two techniques for depositing BSCCO in order to understand the effect of various processing parameters on the final quality of the thin films. Thin films were grown by flash evaporation at Texas A&M University, and by pulsed laser deposition (PLD) at the University of Wollongong, Australia. The latter of these techniques is widely used for growing thin films of various compounds. Single-phase 2212 films were grown on a MgO substrate using the pulsed laser deposition technique from commercially available 2212 powder. The effect of annealing on the thin films was also studied.

BSCCO

High Temperature Superconductors

Flash Evaporation

Pulsed Laser Deposition