Spårmängdsanalys av explosivämnen

Sammanfattning: There is an alarming increase of explosions with devastating consequences, the ultimate being loss of life. Furthermore, these kinds of substances have a toxic effect on animals, nature and humans if they are incorrectly disposed. In order to counteract the rising trend and increase the feeling of security within the society, the Swedish Defense Research Agency (FOI) has started a new project which in the future might be used by the police in order to prevent possible terrorist attacks. The aim with this new project is to perform trace analysis of explosives in wastewater in order to receive an indication of where illegal production of explosives takes place. This method has the potential to be used for other matrixes, such as soil instead of wastewater or other water matrixes, thereby exposing possible harmful and contaminated places.   The aim with this thesis was to develop a method for an Ultra-High-Performance Liquid Chromatography (UHPLC) instrument in order to perform trace analysis of explosives in wastewater. Furthermore, the aim was also to develop a method for an automated solid phase extraction (SPE) instrument for sample clean-up. Lastly mass spectrometry was performed with a triple-quadrupole. A performance analysis was made for the developed UHPLC-method which resulted in a good repeatability. Furthermore, several experiments were conducted on the SPE-instrument in order to receive a yield close to 100%. The different experiments included comparison between the most beneficial eluent, volume of eluent and evaporation step. The highest yield was received with 3 ml acetonitrile without any evaporation step. A performance analysis was made of the developed method for the SPE-robot, which resulted in a good accuracy and precision. In hopes of lowering the detection limit, mass spectrometry was conducted by a preciously validated instrument based at FOI. A lower detection limit was received for all substances; R-salt 0,025 µg/ml, TNT 0,094 µg/ml and PETN 0,103 µg/ml.