A5102028148- Nuclear Physics and Applications
- Particle accelerators and beam dynamics
- Advanced Chemical Sensor Technologies
- Mass Spectrometry Techniques and Applications
- Atomic and Subatomic Physics Research
- Analytical Chemistry and Chromatography
- Nuclear reactor physics and engineering
- Radiation Detection and Scintillator Technologies
- Nuclear physics research studies
- Advanced NMR Techniques and Applications
- Air Quality and Health Impacts
- Muscle metabolism and nutrition
- Graphite, nuclear technology, radiation studies
- Fatty Acid Research and Health
- Muon and positron interactions and applications
- Advanced Combustion Engine Technologies
- Astro and Planetary Science
- Magnetic confinement fusion research
- Analytical Chemistry and Sensors
- Fusion materials and technologies
- Analytical chemistry methods development
- Hormonal and reproductive studies
- Vehicle emissions and performance
European Spallation Source
2017-2018
Stockholm University
1999-2006
Swedish Defence Research Agency
2002-2003
Lund University
1997-1998
A complete method for sampling and analyzing of energetic compounds in the atmosphere is described. The consists hyphenation several techniques: active air using a solid-phase extraction cartridge to collect analytes, sorbed analytes by toluene/methyl tert-butyl ether modified supercritical fluid (SFE), analysis extract large-volume injection GC-nitrogen/phosphorus detection. GC system equipped with loop-type interface an early solvent vapor exit, utilizing concurrent evaporation technique....
The exhaust emissions from two heavy duty diesel vehicles running on eight different fuel compositions were investigated regarding their content of high molecular weight (≥ C12) aliphatic/ olefinic hydrocarbons. It was concluded that the emitted amount semi‐volatile associated aliphatic hydrocarbons (range C12‐C22) depend used in engines and these mainly consisted uncombusted components. also found engine lubrication oil main constituent particulate (C17‐C40). These constituted between 58%...
The goal for the ESS facility is to construct an accelerator with ability deliver a 5 MW proton beam on tungsten target. Most of power deposited as heat in fluids and structures around To be able run nuclear heating from spallation process need cooled safe reliable way. target itself helium cooled, but this system turn water there are several other cooling systems, e.g. moderators, reflectors structural components. In paper systems described what challenges requirements needs deal with.
At ESS water is used both as thermal moderators and to cool the beryllium-and steel reflectors, shielding plugs.This means that water, in separate loops, will be subject a significant proton neutron irradiation which activate water.After irradiation, led delay tanks situated one of triangular rooms downstream from target.This paper aims at determining required ensure biological dose-rate requirements target building instrument halls are met during operation facility.
ESS utilises water both for moderating neutrons to thermal energies, as well cool beryllium- and steel reflectors, the shielding plugs. This means that water, in separate loops, will be subject a significant proton neutron irradiation causing activate. After irradiation, is led delay tanks situated inside target building. Before returned monolith ∼ 10% ion exchanger.