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High energy

In order to maintain high energy efficiency and ensure a long service life of the materials of construction in the combustion chamber, turbine and jet nozzle, a clean burning flame must be obtained that minimizes the heat exchange by radiation and limits the formation of carbon deposits. These qualities are determined by two procedures that determine respectively the smoke point and the luminometer index. [Pg.226]

On-Site or Field Usage of High Energy X-Ray Systems. [Pg.429]

The advent of a portable source of very high energy x-rays has opened up x-ray inspection possibilities in a wide range of environments. Applications include such fields as nuclear waste containers, bridges, nuclear and fossil power plants, surface and airborne transportation systems, space launch systems and other thick section NDT and other inspection problems that cannot be solved imaged using other NDT methods. [Pg.429]

In this paper a new design for a high-energy 3D-CT scanner equipped with a linear accelerator as radiation source and an area high-energy x-ray detector is presented. This system is the extension of a 2D system which is installed at present time [3,4]. [Pg.492]

The setup as seen in Figure 1 mainly consists of a Varian Linatron 3000A linear accelerator (LINAC) as radiation source, a rotational stage for sample manipulation, and a two-dimensional high-energy x-ray detector array consisting of four amorphous silicon area detectors Heimann RIS 256. The source to detector distance is 3.7 m. [Pg.492]

The first release of the high-energy 3D-CT will only deal with circular trajectories. Therefor the Ftldkamp algorithm has been implemented. Figure 3 shows the reconstruction of an ellipse phantom. From its design other trajectories should be possible and will be taken into account in further stages of development. [Pg.494]

O. Gunnewig, W. Nuding, C. Sauerwein High-Energy 3D-Tomography in NDT... [Pg.586]

Existing electronic imaging systems currently used for high energy inspection applications are often based on the combination of the following elements ... [Pg.595]

A proximity focused image intensifier appears therefore as a good solution for both low and high energy applications it combines a sufficient gain to avoid noisy images due to a the quantum sink without some drawbacks of standard image intensifier. [Pg.596]

The 85 mm proximity focused Intensifier designed for high energy includes the following ... [Pg.596]

This Is still under development with the following characteristics compared to the high energy version ... [Pg.597]

A unique high-energy radiation laboratory is functioning at the Institute, in which studies Can be performed and thick items can be controlled using powerful X-ray units and betatrons. [Pg.969]

A Practical Approach to Inspection of Concrete Structures using High Energy Radiography and other Advanced NDE-Methods. [Pg.987]

Ultrasonic wave speed and Impact Echo High-Energy Radiography... [Pg.999]

Combining High Energy Radiography with the Covermeter and Radar to determine reinforcing details... [Pg.1000]

HEED High-energy electron diffraction [104] Diffraction of elastically back-scattered electrons (-20 keV, grazing incidence) Surface structure... [Pg.313]

RHEED Reflection high-energy electron diffraction [78, 106] Similar to HEED Surface structure, composition... [Pg.313]

SHEED Scanning high-energy electron diffraction [106] Scanning version of HEED Surface heterogeneity... [Pg.313]

AES ARABS Auger electron spectroscopy [77, 112-114, 117] Angle-resolved AES [85, 115] An incident high-energy electron ejects an inner electron from an atom an outer electron (e.g., L) falls into the vacancy and the released energy is given to an ejected Auger electron Surface composition... [Pg.314]


See other pages where High energy is mentioned: [Pg.335]    [Pg.15]    [Pg.47]    [Pg.65]    [Pg.175]    [Pg.176]    [Pg.208]    [Pg.255]    [Pg.340]    [Pg.342]    [Pg.402]    [Pg.230]    [Pg.364]    [Pg.429]    [Pg.473]    [Pg.492]    [Pg.496]    [Pg.539]    [Pg.540]    [Pg.541]    [Pg.594]    [Pg.595]    [Pg.596]    [Pg.596]    [Pg.597]    [Pg.997]    [Pg.998]    [Pg.999]    [Pg.1000]    [Pg.302]   
See also in sourсe #XX -- [ Pg.139 , Pg.140 , Pg.193 , Pg.194 , Pg.247 ]

See also in sourсe #XX -- [ Pg.32 ]




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Abrasion treatments high-energy surfaces

Acceleration, high energy

Accelerator mass spectrometry high energy analysis

Accelerators, high energy particle

Acetyl phosphate high energy bond

Adenosine 5 -triphosphate high-energy compound

Adenosine high energy phosphate bonds

Anthracene high vibrational energy

Applications of High-Energy Radiation in Polymer Physics

Azide-containing High Energy Materials

Baer and W.-D. Schneider, High-energy spectroscopy of lanthanide materials - An overview

Ball mill high-energy

Ball milling, high-energy

Barsukov and V. S. Tverdokhleb omposite Anode Materials for High Energy Density ithium-Ion Batteries

Battery systems, high energy

Bombardment high-energy radiation sources

Bombardment of nuclei by high-energy a-particles and neutrons

Bonds high-energy

Calorimeter high-energy particle

Carbocations high-energy

Centrifugal pumps high-energy

Chemical Reactions Induced by High-Energy Radiation

Chemical properties high-energy radiation

Chemical treatments high-energy surfaces

Chemiluminescence high-energy intermediate

Chemistry without potential energy surfaces Highly quasi-degenerate electronic states

Collider, high-energy

Collision induced dissociation high-energy

Combustion high-energy

Cornell high-energy synchrotron source

Cornell high-energy synchrotron source CHESS)

Correlation-exchange energy high-density expression

Crosslinking by high energy radiation

Cure with high energy

Cure with high energy radiation

Curing high energy

Curing system high-energy radiation

Degradation by High-energy Radiation

Degradation high-energy radiation

Diffraction high-energy electron

Diffraction reflection high-energy electron

Diffraction scanning high-energy electron

Direct models at high energies

Doses and Temperatures to Initiate Explosives by Pulsed High-Energy Electrons

Effects induced by irradiation with high-energy photons or particles

Effects of Thermal, Photochemical and High-energy Radiation

Electrochemical energy conversion, high temperature fuel cell

Electromagnetic radiation high energy electron interaction

Electron high-energy, concentration

Electronic stopping high energy

Electrons secondary from high energy radiation

Electrons, high-energy secondary

Electrons, high-energy spin-polarized

Electrons, high-energy transmission

Electrons, high-energy, irradiation, starch

Energy high-pressure reactions

Energy high-temperature fuel cells molten

Energy high-temperature fuel cells solid

Energy level diagrams for other high-symmetry environments

Energy recovery from high-pressure streams

Energy recovery from high-temperature reactors

Environment high energy

Exchange reactions, high energy

Excitation with High Energy Particles

Exciton band high energy

Extension to the high energy spectrum

Extruders high speed energy input

Flame high-energy

Flow in high surface energy dies

Fuel Cells Are Highly Efficient Sources of Electrical Energy

Gamma radiation High-energy photons emitted

Gamma ray A high-energy photon produced in radioactive decay

Gamma ray High-energy electromagnetic

Gamma ray High-energy electromagnetic radiation

Gamma rays High-energy

Gamma rays High-energy electromagnetic radiation emitted

Gelled high energy oxidizers

Generation of high-energy chemiluminophores in ambient light

Gibbs energy of formation high temperature

Glycosidic high-energy

Grafting high-energy radiation

HEF = „high energy fuel

HEIS (high-energy ion scattering

HIGH-ENERGY PROCESSES IN ORGANOMETALLIC CHEMISTRY

HREELS (high resolution electron energy

HREELS (high resolution electron energy Spectroscopy

HREELS (high-resolution electron-energy-loss

High Accuracy Energy Models

High Energy (GeV to TeV, and above)

High Energy Accelerator Research

High Energy Accelerator Research Organization

High Energy Collection

High Energy Density Crevice Reactor

High Energy Exposure

High Energy Materials: Propellants, Explosives and Pyrotechnics. Jai Prakash Agrawal

High Energy Physics Research

High Energy Radiation Effects

High Energy Secondary Ions

High Energy method

High Pressure in Renewable Energy Processes

High Resolution Energy Microscopy

High Specific Capacity and Energy

High activation energy

High energy X-ray diffraction

High energy accelerators

High energy additive

High energy approximation

High energy beamlines

High energy binding sites

High energy collisions

High energy compound

High energy consumption

High energy density

High energy density batteries

High energy density materials

High energy density materials (HEDMs

High energy explosive

High energy fragmentation

High energy fuels

High energy implantation

High energy irradiation

High energy level waste

High energy light

High energy loss spectroscopy

High energy machines

High energy neutral beams

High energy neutrals

High energy propellants

High energy radiation imaging

High energy radiation of textiles

High energy radiation, production

High energy resolution array

High energy signals

High energy sites

High energy solid surfaces

High energy surface

High energy surfaces definition

High energy surfaces wetting

High energy toward

High energy-resolution fluorescence detection

High energy-resolution fluorescence detection HERFD)

High free energy

High kinetic energy penetrators

High resolution electron energy loss electronic study

High resolution electron energy loss spectroscopy, described

High resolution electron energy loss surface studies

High resolution electron energy loss vibrational studies

High spins energy matrix

High-Energy Mixtures

High-Energy Nuclear Reactions

High-Energy Organic Molecules Caught in Frozen Matrices and Some Surprises

High-Energy Phosphate Bond

High-Resolution Electron Energy Loss Spectroscopy, HREELS

High-activation-energy resists

High-dimensional neural network potential-energy surfaces

High-energy Reactions

High-energy adsorption sites

High-energy antibonding orbital

High-energy areas

High-energy beams

High-energy bombardment

High-energy collision (keV)

High-energy collision dissociation

High-energy collision induced

High-energy colloids

High-energy conformation

High-energy electron beam

High-energy electron transfer

High-energy electron transfer products

High-energy electrons

High-energy electrons, generation using

High-energy emissions

High-energy emulsification methods

High-energy excimer

High-energy excited state emission

High-energy fission

High-energy fission neutrons

High-energy fission reactions

High-energy intermediate

High-energy intermediate activators

High-energy intermediate peroxyoxalates

High-energy intermediate structure

High-energy ion scattering

High-energy ion scattering spectroscopy

High-energy ionizing radiation

High-energy mechanical milling

High-energy metabolites

High-energy milling

High-energy mixing

High-energy neutrons

High-energy particle

High-energy phosphate depletion

High-energy phosphate metabolism

High-energy phosphates

High-energy phosphates inhibition

High-energy photon radiations

High-energy photon radiations denotations

High-energy physics

High-energy physics , application

High-energy point bars

High-energy processes

High-energy processes alkyl radicals

High-energy processes atoms

High-energy processes definition

High-energy processes development

High-energy processes future role

High-energy processing

High-energy protons

High-energy pumps

High-energy radiation

High-energy radiation and matter

High-energy radiation polymer degradation

High-energy radiation techniques

High-energy radiation, initiation

High-energy radio-frequency

High-energy radioactivity

High-energy scans

High-energy shearing

High-energy spinless fermion model

High-energy substance identification

High-energy surfaces free energies

High-energy surfaces humidity effects

High-energy transition

High-energy usage

High-energy waters

High-energy-product magnets

High-energy-radiation-induced cationic

High-energy-radiation-induced cationic polymerization

High-pressure streams, energy

High-resolution electron energy loss

High-resolution electron energy loss advantages

High-resolution electron energy loss intermediates

High-resolution electron energy loss single-crystal surfaces

High-resolution electron energy loss spectra

High-resolution electron energy loss spectroscopy

High-resolution electron energy loss surface structure

High-resolution electron energy-loss water

High-resolution energy-loss

High-resolution energy-loss spectroscopy spectra

High-resolution low-energy electron

High-spatial-resolution energy dispersive

High-spatial-resolution energy dispersive spectroscopy

High-temperature reactors, energy

High-temperature water splitting nuclear energy

Hydrocarbon fuels, high energy density

Initiation by high-energy radiation

Initiators, high-energy radiation-induced

Inorganic high energy oxidizers

Interaction of high-energy radiation with matter

Interfacial free energies high-energy surfaces

Ionization high-energy electrons

Irradiation with High-Energy Light

Lithium high energy

Materials high energy

Maximum Efficiency for High Energy Excitation

Measurement of high-energy beta-or gamma-radiation

Mechanical properties high-energy radiation

Medical applications high-energy radiation

Metastable, high energy

Modeling of process systems with high energy throughput

Models at High Energies

Molecular beam epitaxy reflection high energy electron

Molecule high-energy

Neutron fast’/high-energy, bombardment

Neutron high-energy, bombardment

OLUME 10 High energy spectroscopy 8 ISBN

Other high energy nucleotides

Oxidative phosphorylation high energy intermediates

Pair production, from high energy radiation

Phenyl cation, high energy

Phosphate esters high energy bonds

Phosphates/phosphorus high-energy

Phosphorescent OLED device high-energy efficiency

Photoconductive polymers produced by thermal or high-energy radiation treatment

Photoluminescence, high energy

Photoluminescence, high energy emission spectra

Photons high energy

Plasma treatments high-energy surfaces

Plasticizers high energy oxidizing

Polyethylene high-energy oxidation

Polymer degradation by high-energy radiation

Polymorphism of high energy materials

Potential energy surfaces determination from high resolution

Preparation of High-Energy Mixtures

Process systems with high energy throughput

Properties, after high-energy electron

Properties, after high-energy electron irradiation

Pyruvate to Phosphoenolpyruvate Requires Two High Energy Phosphates

RHEED (reflection high-energy electron

Radiation sources, high energy

Radiation, high-energy, types

Radiation-induced grafting high-energy

Radioactive aerosols associated with the operation of high-energy accelerators

Range, of high energy particles

Reaction energies thermodynamics high-accuracy

Reactions with high-energy light

Recoil high energy, kinetics

Reflectance high-energy electron diffraction

Reflected high energy neutrals

Reflection high energy

Reflection high energy diffraction

Reflection high energy electron diffraction, molecular beam epitaxy

Reflection high energy electron spectroscopy

Reflection high-energy electron

Reflection high-energy electron diffraction RHEED

Reflection high-energy electron diffraction surface structure

Requirements for a Good High-Energy Mixture

Resist high activation-energy

Resistance to high-energy radiation

Rutherford High Energy Laboratory

Schizophrenia high-energy phosphates

Scrubber systems, high-energy

Selected values of high-angle grain-boundary energies

Siloxane bond high energy

Spectra under high energy collision

Spectroscopy high-energy

Spurs produced by high-energy radiation

Standard high-energy conformations

Starch with high-energy electrons

Start by High-Energy Radiation

Subject high-energy intermediate

Substrate types high-energy surfaces

Surface free energies high-energy surfaces

Surface graft polymerization high-energy radiation

Surface high-resolution electron energy loss

Surface pretreatments high-energy surfaces

Surfaces reflection high-energy electron diffraction

Synthesis of High-Energy Nucleotides

Tactical High Energy Laser

The High-Energy Character of Phosphoanhydride Bonds

The High-Energy Milling Process

The alphabet of high energy molecular materials

Theoretical concepts useful for high energy reactions

Traditional design of a high-energy EB unit

Transparent Silica Aerogel Blocks for High-Energy Physics Research

Unimolecular Reactions and Energy Transfer of Highly Excited Molecules

Use of High-Energy Phosphate Bonds During Translation

Use of high-energy radiation in polymer blends technology

Utilizing High Energy Photons

Vibrational spectroscopy high-resolution electron-energy-loss

Vulcanization cure with high energy

Zero-energy high-temperature reactor

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