A method of determining directionality of radiation is disclosed which comprises dividing the tensioned metastable fluid liquid volume adjacent to a radioactive source into a plurality of sectors, determining the opposing sector ratio of the respective sector and determining the direction of the radiation based on the opposing sector ratios of the plurality of sectors. The method further comprising determining directionality of incoming radiation from the tension pressure assisted elongation of bubble shapes pointing towards direction of radiation particles that interacted with nuclei of tensioned metastable fluid detector system. A device capable of carrying out these methods is also disclosed.

Alpha particle detecting devices are disclosed that have a chamber that can hold a fluid in a tensioned metastable state. The chamber is tuned with a suitable fluid and tension such that alpha emitting materials such as radon and one or more of its decay products can be detected. The devices can be portable and can be placed in areas, such as rooms in dwellings or laboratories and used to measure radon in these areas, in situ and in real time. The disclosed detectors can detect radon at and below 4 pCi/L in air; also, at and below 4,000 pCi/L or 300 pCi/L in water.

Alpha particle detecting devices are disclosed that have a chamber that can hold a fluid in a tensioned metastable state. The chamber is tuned with a suitable fluid and tension such that alpha emitting materials such as radon and one or more of its decay products can be detected. The devices can be portable and can be placed in areas, such as rooms in dwellings or laboratories and used to measure radon in these areas, in situ and in real time. The disclosed detectors can detect radon at and below 4 pCi/L in air; also, at and below 4,000 pCi/L or 300 pCi/L in water.

Systems and methods for measuring trajectories of charged particles and for charged particle radiography and charged particle tomography are presented, comprising one or more directional particle detectors (DPDs). A DPD produces a directional measurement of a charged particle by determining the transit distance of the charged particle through a detector medium which is elongated is a single spatial dimension, or by determining the amount of energy deposited by the charged particle in a detector medium which is elongated is a single spatial dimension. Also presented are charged particle transmission imaging systems, charged particle scattering imaging systems, composite DPDs of various geometries, embodiments allowing for the monitoring of a plurality of detector medium columns by as few as one optical sensor, various shapes and compositions of detector medium columns, DPDs elongated in two spatial dimensions, fields of application, and discussions about the fundamental advantages of DPD over coincidence-based charged particle velocimetry.

Systems and methods for measuring trajectories of charged particles and for charged particle radiography and charged particle tomography are presented, comprising one or more directional particle detectors (DPDs). A DPD produces a directional measurement of a charged particle by determining the transit distance of the charged particle through a detector medium which is elongated is a single spatial dimension, or by determining the amount of energy deposited by the charged particle in a detector medium which is elongated is a single spatial dimension. Also presented are charged particle transmission imaging systems, charged particle scattering imaging systems, composite DPDs of various geometries, embodiments allowing for the monitoring of a plurality of detector medium columns by as few as one optical sensor, various shapes and compositions of detector medium columns, DPDs elongated in two spatial dimensions, fields of application, and discussions about the fundamental advantages of DPD over coincidence-based charged particle velocimetry.