Abstract: A hybrid radiation detector is described comprising a first energy discriminating detector element selected to be sensitive to incident radiation of a lower energy range and a second detector element selected to be sensitive to incident radiation of a higher energy rage and a second detector element. In embodiments, a first detector element comprises a semiconductor detector; and a second detector element comprises a scintillator detector. The first detector element may thus be suitable to be more responsive to radiation in a first, lower energy range and/or configured and arranged to collect incident radiation emergent from a target of such energy that the photoelectric effect predominates as an attenuation mode in the target; and the second detector element may thus be suitable to be more responsive to radiation in a second, higher energy range and/or configured and arranged to collect incident radiation of a generally higher energy.

Abstract: A radiation detector assembly is described comprising: a scintillator; a photodetector; a hermetic enclosure surrounding and defining an enclosure volume that contains the scintillator and the photodetector; wherein the enclosure comprises a wall of plastics material coated with a metal layer. A method of assembly of a radiation detector assembly is also provided.

Abstract: A method of fabricating a semiconductor detector device to exhibit a target sensitivity to incident radiation in a predetermined energy range is described, the method comprising: providing a semiconductor detector; defining on a detector surface of the semiconductor detector a large plurality of pixels; wherein the detector is geometry is controlled with reference to the size of the said pixels such that a single interaction event in the predetermined energy range will produce a detectable signal in each of a plurality of adjacent pixels making up a cluster of at least three pixels. A detector fabricated by such a method and a method of obtaining spectral information about incident radiation using such a detector are also described.

Abstract: A conveyor system is described for use with a scanning apparatus (49) for the scanning of objects (43), such as bottles. The system comprises a transverse conveyor having a conveyor surface (45); a plurality of object support modules (41), each object support module (41) comprising a lower surface that sits upon the conveyor surface (45) of the conveyor and an upper part in which an object receiving recessed portion is defined, wherein the object receiving recessed portion defines an elongate recess having a constant transverse profile. A scanning system comprising the conveyor system in combination with an object scanner and a method of scanning embodying the principles of such a scanner are also described.

Abstract: A method for the inspection of contained flowable materials within containers, such as detecting an explosive liquid in a luggage, and an apparatus for performing the method are described.

Abstract: A method of operation of a scintillator detector includes a scintillator and a photodetector is described, together with a device embodying the method. The method includes the steps of: periodically producing a light pulse; impinging at least some of the light from a successive plurality of such light pulses onto a light-receptive part of the photodetector; measuring the electrical response of the photodetector; processing the electrical response of the photodetector to determine a pulse height and a variance of pulse height; numerically processing the pulse height and variance of pulse height so determined to obtain at least a first data item characteristic of the response of the photodetector.

Abstract: A method of radiological examination of an object for the identification and detection of the composition the object comprising the steps of: irradiating an object under test with high energy radiation such as x-rays or gamma-rays and collecting radiation emergent from the object at a suitable detector system in such manner that emergent radiation intensity data is collected for the entire volume of the object under test; numerically processing the radiation intensity data to obtain a first data item correlated to the total number of electrons within the sample; applying an alternative method to obtain a second data item correlated to another property of the sample; using the first and second data items to derive an indication of the material content of the sample.

Abstract: A method is for the deconvolution of a statistically noisy spectral dataset is described comprising the steps of: a. obtaining a spectroscopically resolved dataset of measured flux from a sample that has been collected using a suitable detector radiation system; b. generating an initial estimate of the true spectrum; c. modifying the estimate of the true spectrum by a response function of the detector used to collect the measured flux dataset so as to generate an estimate flux dataset; d. computing a merit value for statistical fit between the measured flux dataset and the estimate flux dataset; e. applying a perturbation to a value of the estimate of the true spectrum; f.

Abstract: A method of operation of a scintillator detector comprising a scintillator and a photodetector is described, together with a device embodying the method. The method comprises the steps of: periodically producing a light pulse; impinging at least some of the light from a successive plurality of such light pulses onto a light-receptive part of the photodetector; measuring the electrical response of the photodetector; processing the electrical response of the photodetector to determine a pulse height and a variance of pulse height; numerically processing the pulse height and variance of pulse height so determined to obtain at least a first data item characteristic of the response of the photodetector.

Abstract: A method of examination of an object comprising the steps of: applying a Nuclear Magnetic Resonance technique to obtain a data item correlated to the relative nuclear susceptibility within the sample; obtaining a further data item correlated to another measure of the object under examination; determining therefrom a ratio.

Abstract: A conveyor system for use with a scanning apparatus for scanning of contained materials such as liquids within containers such as bottles. The system includes a transverse conveyor having a conveyor surface, a plurality of container support modules each adapted to seat on the conveyor surface. Each container support module includes a lower surface that sits upon the conveyor surface of the conveyor and upper part in which a container-receiving recessed portion is defined.

Abstract: A vapor conduit for use in an apparatus for bulk vapor phase crystal growth, an apparatus for bulk vapor phase crystal growth, and a process for bulk vapor phase crystal growth are described. The vapor conduit is a flow conduit defining a passage means adapted for transport of vapor from a source volume to a growth volume, wherein a flow restrictor is provided in the passage means between the source volume and the growth volume and wherein the flow conduit further comprises a flow director structured to direct vapor flow downstream of the flow restrictor away from a longitudinal center line of the conduit and for example towards an edge of the conduit.

Abstract: A conveyor system for use with a scanning apparatus for the scanning of contained materials such as liquids and the like, especially within containers such as bottles, is described, comprising a transverse conveyor having a conveyor surface; a plurality of container support modules each adapted to seat on the conveyor surface; wherein each container support module comprises a lower surface that sits upon the conveyor surface of the conveyor and upper part in which a container-receiving recessed portion is defined. A method of conveying bottles using such a system is also described.

Abstract: A method of and device for processing a radiation pulse are described based on: detecting an event at the detector; producing a pulse; determining for the pulse: a pulse height measurement representative of pulse magnitude; a pulse width measurement representative of pulse duration; assigning the pulse to one of at least two classes based on the determined pulse height/pulse width; applying to each pulse an algorithm specific to its particular class to produce an output pulse height/pulse width profile.

Abstract: A method of identifying the material content of an object comprises: providing a radiation source and a radiation detector; irradiating a test object with radiation from the source; collecting at the detector system intensity data for radiation emergent from the test object; resolving the intensity data spectroscopically between a plural set of energy bands; numerically processing the spectroscopically resolved intensity data via the following steps: considering a material attenuation coefficient as a plural set of energy dependent polynomial equations in atomic number with a set of energy dependent coefficients across the said plural set of energy bands; determining a measured attenuation coefficient at each said energy band; calculating therefrom one or more orders of Compound Proton Number and/or effective mass thickness and/or density and for example a Compound Proton Number Set comprising plural order powers and preferably plural higher order powers of weighted compound atomic number.

Abstract: A method processing an image dataset of radiation emergent from a test object after its irradiation by a suitable radiation source is described which comprises the steps of: generating an image dataset comprising a spatially resolved map of items of intensity data from the radiation emergent from the test object; further, resolving the intensity data items spectroscopically between at least two energy bands across the spectrum of the source; numerically processing the spectroscopically resolved intensity data items to determine a further spatially resolved dataset of data items representative of one or more orders of Compound Proton Number and/or effective mass thickness and/or a density; generating a segmented image dataset using the said dataset of data items representative of one or more orders of Compound Proton Number and/or effective mass thickness and/or a density. The method applied as part of a method for the radiological examination of an object and an apparatus for the same are also described.

Abstract: A method for monitoring objects for example for facilitating the identification and/or authentication of objects comprises: in a first recording phase: irradiating an object with a suitable source of radiation, collecting intensity information about radiation emergent from the object, resolving the intensity information spectroscopically between at least two energy bands, and storing the resultant dataset as a reference dataset; and in a second verification phase: irradiating an object with a suitable source of radiation, collecting intensity information about radiation emergent from the object, resolving the intensity information spectroscopically between at least two energy bands, and using the resultant dataset as a test dataset; identifying the object and retrieving its corresponding reference dataset; comparing the test dataset and the reference dataset within predetermined tolerance limits, and: in the event that the reference dataset and the test dataset correspond within the predetermined tolerance li

Abstract: A method for the inspection of contained flowable materials within containers, such as detecting an explosive liquid in a luggage, and an apparatus for performing the method are described.

Abstract: The present invention relates to an apparatus for vapour phase crystal growth to produce multiple single crystals in one growth cycle comprising one central source chamber, a plurality of growth chambers, a plurality of passage means adapted for transport of vapour from the source chamber to the growth chambers, wherein the source chamber is thermally decoupled from the growth chambers.

Abstract: A semiconductor detector device comprising: a detector element comprising at least one active detector layer of piezoelectric semiconductor material; a stress inducing element arranged to act in use on the detector element to generate therein a predetermined pattern of stress, and consequently a predetermined electrical field via the piezoelectric effect. A method of fabrication and of operation of a semiconductor detector device embodying these principles are also described.