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Thermal energies

Nonmechanical introduction of energy (Thermal shock, explosive shattering, electrohydraulic)... [Pg.1840]

See also Energy Intensity Trends Geography and Energy Use Geothermal Energy Thermal En-ergy. [Pg.1042]

Whereas heat capacity is a measure of energy, thermal diffusivity is a measure of the rate at which energy is transmitted through a given plastic. It relates directly to processability. In contrast, metals have values hundreds of times larger than those of plastics. Thermal diffusivity determines plastics rate of change with time. Although this function depends on thermal conductivity, specific heat at constant pressure, and density, all of which vary with temperature, thermal diffusivity is relatively constant. [Pg.398]

S 17.3 million Renewables - direct water splitting using solar energy thermal processes using biomass advanced electrolysis from wind power. [Pg.62]

It is also necessary to note that the success of TSR techniques to obtain information on trapping states in the gap depends on whether or not the experiment can be performed under conditions that justify equation (1.2) to be reduced to simple expressions for the kinetic process. Usually, the kinetic theory of TSR phenomena in bulk semiconductors—such as thermoluminescence, thermally stimulated current, polarization, and depolarization— has been interpreted by simple kinetic equations that were arrived at for reasons of mathematical simplicity only and that had no justified physical basis. The hope was to determine the most important parameters of traps— namely, the activation energies, thermal release probabilities, and capture cross section— by fitting experimental cnrves to those oversimplified kinetic descriptions. The success of such an approach seems to be only marginal. This situation changed after it was reahzed that TSR experiments can indeed be performed under conditions that justify the use of simple theoretical approaches for the determination of trapping parameters ... [Pg.5]

One of the most promising applications of polyboron hydride chemistry is boron neutron capture therapy (BNCT) for the treatment of cancers (253). Boron-10 is unique among the light elements in that it possesses an unusually high neutron capture nuclear cross section (3.8 x 10-25 m2,0.02—0.05 eV neutron). The nuclear reaction between 10B and low energy thermal neutrons yields alpha particles and recoiling lithium-7 nuclei ... [Pg.253]

Effects of Thermal Energy Thermal conductivity Melting and boiling point determinations Ice point-humidity instrumentation, among others Dew point-humidity instrumentation, among others Vapor pressure Fractionation C liro matography Tliermal expansion... [Pg.95]

Calcium is used in refining battery-grade lead lor removing bismuth. Calcium is also used as an electrode material in high-energy thermal batteries. [Pg.268]

Merzhanov et al (Ref 3) also made an investigation of the thermal explosion of Dinitrohy-droxydiethylnitramine (mp 52.5°) and of Tetryl (mp 130°) in the liq phase under conditions where the reaction zone was free of temp distribution and the entire thermal gradient was at the walls of the container. The method exptl setup were the same as previously used by the authors (Ref 1). The activation energy, thermal effect critical temp were reported for both expls (Ref 6)... [Pg.280]

Classify the following properties of a system as extensive or intensive volume, pressure, energy, thermal expansion coefficient, and viscosity. [Pg.44]

Most processes include some form of capacitance or storage capability. These capacitance elements can provide storage for materials (gas, liquid, or solids) or storage for energy (thermal, chemical, etc.). Thermal capacitance is directly analogous to electric capacitance and can be calculated by multiplying the mass of the object (W) with the specific heat of the material it is made of (Cp). The gas capacitance of a tank is constant and is analogous to electric capacitance. The liquid capacitance equals the cross-sectional area of the tank at the liquid surface, and if the cross-sectional area is constant, the capacitance of the process is also constant at any head. [Pg.171]

GSS(Z Ri, R2) orGcc(Z Ri, R2) or Gim/2m(Z Ri, R2) h U Ti=—,h 2 x k kT kTIQQni P Used between spheres or cylinders of constant radii Ri, R2 of materials 1, 2. Planck s constant. Boltzmann s constant. Thermal energy. Thermal energy at room temperature. Pressure, negative spatial derivative of G per unit area between parallel planar surfaces negative pressure denotes attraction (a convention contrary to that in which pressure on a surface is defined in the direction of its outward normal... [Pg.102]

Thermal treatment processes use energy to destroy or decontaminate waste. These technologies include low or high energy thermal processes. Several types of thermal processes include flame combustion, fluidized bed combustion, infrared incineration, pyrolysis and plasma heat systems. [Pg.171]


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Acceptors thermal activation energy

Activation energies for thermal degradation

Activation energy of thermal decomposition

Activation energy of thermal degradation

Activation energy thermal

Agricultural thermal energy from

Apparatus for Mass Spectrometric Studies of Ion-Molecule Reactions at Pressures Above 1 Torr and Thermal Energies

Aquifer Thermal Energy Storage (ATES)

Aquifer thermal energy storage

Available energy thermal transport

Bond energy thermally unstable complexes

Borehole thermal energy storage

Catalysts thermal energy balance

Catalytic combustion thermal energy generation

Charge-transfer reactions thermal energy

Chemiluminescence detectors thermal energy analyzer

Cogeneration thermal energy

Contraction thermal energy-driven

Corrosion thermal activation energy

Defect level spectroscopy - thermal emission energies

Defects thermal emission energies

Detectors thermal energy analyzer

Determination of Bond Dissociation Energies by Thermal Equilibrium Methods

Development of Microscopic Thermal Energy Balance and Its Application

Effects of Thermal, Photochemical and High-energy Radiation

Electrical energy from thermal

Electrical energy from thermal conversion

Electricity ocean thermal energy conversion

Energy British thermal unit

Energy Density and Intensity of Thermal Radiation

Energy Intake (Thermal or Photochemical)

Energy barrier thermal activation

Energy conversion thermal

Energy converter, thermal

Energy converter, thermal activation potential

Energy converter, thermal efficiency

Energy converter, thermal heat engines. Carnot cycle

Energy diagram illustrating the relationship between thermal and photochemical reactions

Energy landscape thermal equilibrium

Energy level and thermal agitation

Energy ocean thermal

Energy rotational, 7, 94-------------------thermal

Energy saving, thermal separation

Energy storage cool thermal

Energy thermal transport

Energy, barrier thermal

Energy, units thermal expansion, coefficient

Energy-efficient thermal recovery

Equation of thermal energy

Exergy of Any Energy Except Thermal

Gas chromatography-thermal energy

Gas chromatography-thermal energy analysis

Heal generation thermal energy

History of Thermal Energy Storage

How molecules take up thermal energy

INDEX thermal energy

Industry sector, thermal energy from

Instrumentation thermal energy analyzer

Ionization energy thermal

Latent thermal energy storage

Liquid thermal energy conducted

Mechanical work thermal energy-produced

Melting thermal energy requirements

Molecular flux thermal energy

Motion thermal energy production

Nitrosamines thermal energy analyzer

Ocean thermal energy conversion OTEC)

Ocean thermal energy conversion systems

Ocean-Thermal Energy Conversion

Oceans ocean thermal energy conversion

Photoconductive polymers produced by thermal or high-energy radiation treatment

Postscript Energy Terms in Optical and Thermal Electron Transfer

Quantum and Thermal Corrections to the Ground-State Potential Energy

Radiant thermal energy

Reaction thermal energy

Recoil Energy Loss in Free Atoms and Thermal Broadening of Transition Lines

Renewable ocean thermal energy

Residue thermal energy

Section 3.2 Thermal Energy Furnaces

Shallow donors thermal activation energy

Solar power thermal energy conversion

Solar thermal energy

Solid thermal energy

Spin thermal energy

Systems thermal energy storage

Temperature thermal energy

Temperature thermal energy calculation

Thermal Effects and Energy Balances

Thermal Energy Conservation

Thermal Energy Storage

Thermal Energy Storage (TES)

Thermal Stability Atomic Cohesive Energy

Thermal activation energies for

Thermal activation energies, determination

Thermal analysis, activation energy

Thermal aspects energy equations

Thermal conductivity energy concept

Thermal degradation bond energies

Thermal energies and the structures of molecules

Thermal energy analyser

Thermal energy analysis

Thermal energy analysis detection

Thermal energy analyzer

Thermal energy analyzer analysis

Thermal energy analyzer chemiluminescent detection with

Thermal energy analyzer schematic

Thermal energy atom scattering

Thermal energy atom scattering (TEAS)

Thermal energy balance

Thermal energy balance batch reactor

Thermal energy balance differential reactor

Thermal energy balance steady state conduction

Thermal energy basics

Thermal energy calculating

Thermal energy calculation magnitude

Thermal energy charge-transfer

Thermal energy conservation equation

Thermal energy contraction

Thermal energy correction

Thermal energy correction components

Thermal energy correction scaling

Thermal energy density

Thermal energy detector , HPLC

Thermal energy determination

Thermal energy determination levels

Thermal energy dispersal

Thermal energy dissipation

Thermal energy distribution

Thermal energy effects

Thermal energy endothermic reactions

Thermal energy equation

Thermal energy equation cylindrical

Thermal energy equation derivation

Thermal energy equation enthalpy form

Thermal energy equation incompressible

Thermal energy equation single component

Thermal energy exothermic reactions

Thermal energy fluid heat exchangers

Thermal energy from agricultural residues

Thermal energy from wood

Thermal energy furnaces

Thermal energy generation

Thermal energy generation parameter

Thermal energy harvesting

Thermal energy heat engines

Thermal energy losses

Thermal energy motion produced

Thermal energy properties related

Thermal energy refrigeration

Thermal energy removal

Thermal energy steam generation

Thermal energy storage materials

Thermal energy translational

Thermal energy, average

Thermal energy, lipid hydrocarbon chain

Thermal energy, sources

Thermal energy, sources spectroscopy

Thermal energy, transfer

Thermal energy-efficient

Thermal energy/ies

Thermal energy/motion

Thermal equilibrium determination dissociation energies

Thermal equilibrium spin energies

Thermal neutrons energy

Thermal reactions energy profiles

Thermal to electrical energy

Thermal transport general energy equation

Thermalization path length energy dependence

Thermally stimulated energy transfer

Thermodynamics thermal energy

Underground thermal energy storage

Weathering properties thermal energy

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