On-site inspection techniques
Initial Period Techniques
In the initial period until the progress inspection report is submitted, i.e. not later than 25 days after the Executive Council approves the inspection, the inspection team can apply the following techniques:
Visual observation, video and still photography, and multi-spectral imaging (including infrared measurements);
Measurement of level of radioactivity using gamma radiation monitoring and image resolution analysis;
Environmental sampling and analysis;
Passive seismological monitoring of aftershocks.
Position finding activities are particularly important at the outset of an on-site inspection as they help confirm the location and boundaries of the inspection area. They are also conducted at various times during an inspection since they facilitate the orientation and navigation of the inspection team within the inspection area.
The equipment to be used is listed in the inspection mandate and may include satellite- based positioning devices, such as GPS, and surveying equipment. When carrying out position finding activities, the inspection team will use some reference system based either on a geographical projection (using latitude and longitude projection) or a grid. Position finding may also include the mapping of landmarks or man-made changes on the surface, in order to help with the general orientation in the inspection area.
By visually observing the natural environment in the inspection area, a skilled observer can detect anomalies in geological features or disturbances of vegetation that may point to a possible underground nuclear explosion. Visual observation can help the inspection team narrow down the inspection area or identify specific inspection activities that may be warranted.
The inspection team can use digital still and video photography to record their observations and findings. Ground based visual observation should be carried out in close coordination with overflights and should start immediately at the beginning of an on-site inspection. Visual observation and photographic recording will continue throughout the entire inspection.
There are strict procedures for securing photographic evidence and records. Both the inspection team and the inspected State Party are responsible for meeting these requirements. All related information, such as date, time, location and subject of each photograph or video recording, needs to be recorded in logs. Any further handling of images, including their processing and examination, is also strictly regulated.
In case additional overflights are agreed upon, the inspection team can proceed to perform multi-spectral imaging including infrared measurements and gamma spectroscopy.
Multi-spectral imaging (including infrared measurements)
This technology measures light at wavelengths around the spectra of visible light. The resulting images are then combined and may provide additional information about changes in surface, near-surface and sub-surface features.
Gamma radiation monitoring, energy resolution analysis and environmental sampling and analysis
In conjunction with visual observations, initial gamma radiation surveys help to select regions within the inspection area for detailed investigation. These surveys help to identify gamma radiation that appears to be anomalous, in contrast to natural background radiation. During this phase, the inspection team uses predominantly vehicle- mounted equipment, but may also use handheld devices.
The inspection team collects environmental samples, such as soil, vegetation and water, for later analysis in a specialized laboratory. Air sampling to detect radioactive particulates and radioactive gases is very important. This is not only restricted to the surface air, but also extends to shallow underground layers in order to sample gases that may have been trapped in the upper layers of the soil. This sampling has to be done as soon as possible to ensure that elements with a short half-life can still be detected.
Preferably, all sample analysis is performed in an on-site inspection field laboratory at the base of operations. When necessary, because equipment for some analysis activities is not available in the field, samples may be sent to laboratories that have been designated prior to the inspection.
In some cases, the presence of radionuclides relevant for an on-site inspection can be identified immediately in-situ using a portable instrument. The use of mobile equipment gives the inspectors more flexibility in the field, and measurements can be taken immediately and at several locations.
As with photographic material, the inspection team must be meticulous when recording its findings and storing samples. As with other procedures, representatives of the inspected State Party can be present during all inspection activities and have the right to receive copies of all data collected in the inspection area and retain portions of the samples.
Seismological monitoring of aftershocks
This technology is used preferably in the beginning of an on-site inspection as the number of seismic aftershocks after a nuclear explosion decreases rapidly. An underground nuclear explosion would create a cavity and changes in the geological surroundings. Following a nuclear explosion, geological structures at the site of the explosion will settle, causing minute seismic events with distinct seismic signatures that can be detected by what is called passive seismological monitoring.
Seismic field equipment is placed at several locations throughout the inspection area, creating a seismic network. The network is comprised of approximately 40 mini-arrays, each consisting of four seismometers and one digitizer. For a rapid analysis of the incoming seismic data, an on-site inspection will have a seismological centre at the base of operations.
The inspection team has also the right to conduct an initial overflight of the inspection area as soon as possible, to help the team get oriented in the area. It helps to narrow down the number of locations on the ground that need further inspection and to facilitate the collection of factual evidence. The initial overflight is limited to a maximum of 12 hours. The Treaty identifies the equipment that can be used during the initial overflight, including field glasses, passive location-finding equipment (e.g. maps and theodolites), video cameras and hand-held digital photo cameras.
Additional overflights can only be conducted with the inspected State Party’s approval. The inspected State Party has the right to impose restrictions on the parameters of an overflight, such as altitude, in-flight procedures like circling and hovering, the number of inspectors on board or the type of measurements and observations. Subject to approval by the State Party, the inspection team may perform different activities during the additional overflights, including multi-spectral imaging, gamma spectroscopy and magnetic field mapping.
Used during additional overflights, gamma spectroscopy helps identify gamma radiation-emitting substances by measuring their energy and intensity. Elevated radiation can be caused by geological phenomena but also by man-made activities, and may thus point to a possible nuclear explosion.
Continuation Period Techniques
In addition to the techniques that can be used during the initial period, several other techniques - mainly geophysical seismic and non-seismic techniques, can be used during the continuation period. Typically, they can be applied in those areas where findings indicate the need for further examinations and site characterisation.
The use of geophysical techniques is meant to detect, from the surface, changes in the geological structures, and may reveal relevant findings. These techniques include:
Magnetic and gravitational field mapping;
Ground penetrating radar;
Electrical conductivity measurements;
Active seismic surveys.
Magnetic field mapping
Magnetic field mapping measures anomalies in the Earth’s magnetic fields that can be caused by different iron-containing objects in the ground. The presence of such objects can point to infrastructure elements of an underground nuclear explosion, such as pipes and cables. Magnetometers can also help identify man-made structures in the ground, such as foundations or shafts.
Gravitational field mapping
Gravitational field mapping looks for microgravity changes in Earth’s gravitational field and can potentially help locate the cavity created by an underground nuclear explosion, tunel entracies and/or other voids. A cavity, or a void, represents a change in the density of the rock compared within surrounding rocks. The size of the cavity depends on various factors, such as the yield of the explosion, the depth and the surrounding geology. Depending on the rock type, a one kiloton explosion at a depth of 200 metres could cause a cavity of approximately 17 metres in diameter.
Ground penetrating radar
Ground penetrating radar uses electromagnetic waves to locate objects in the shallow underground by reflecting off them. The reflected waves then allow for the identification of these objects and their location. Higher frequencies correspond to shorter waves, and the shorter the wave, the smaller the buried objects that can be detected. This technology is used to identify parts of an underground explosion infrastructure.
Electrical conductivity measurements
There are two distinct purposes of electrical conductivity measurements during an on-site inspection. Shallow measurements of underground electrical properties, up to few metres depth, can help identify metallic objects belonging to the infrastructure of a possible nuclear explosion. Deeper measurements will lead the inspectors to identify disturbances in the underground geological structures, such as cavities or changes in the water table, which, in both cases, may result from an underground nuclear explosion.
Active seismic survey
Active seismic surveys are used to search for and locate underground anomalies, including cavities and rubble zones, to detect and characterize the observables identified, and to interpret what the presence of those observables means. The primary targets for an active seismic survey are the cavity and possible associated fracture and rubble zones, including their characteristics, created by a UNE.
In general, other inspection techniques will have been used to identify other area(s) for applying active seismic techniques such as refraction, reflection and tomography. In some cases, active seismic techniques may be used to survey larger areas for underground velocity anomalies associated with voids, rubble zones and/or fracture zones. Techniques such as refraction fan shooting may be employed over larger areas to identify potential targets for other active seismic techniques such as 2D seismic reflection profiles or 3D seismic reflection mapping.
Resonance is an important physical phenomenon that can be defined in a very general way as the increase in the amplitude of oscillation in a system exposed to a specific force with frequency equal or very close to the natural frequency of the system. Resonance seismometry techniques include both active and passive methods to search for and locate underground anomalies, including cavities and rubble zones; to detect and characterize the observables identified; and to interpret what the presence of those observables means in the light of other OSI techniques. The technique relies on the seismic signals produced by underground features that resonate when seismic energy from other sources, either natural or man-made, passes through them or on changes in the velocity of propagation or signal attenuation by such underground features.
Based on findings derived from inspection activities already conducted, the inspection team may propose drilling. The Treaty spells out how a request for drilling is dealt with. The inspection team passes the request to the Director-General, who in turn submits the request to the Executive Council. The inspection team shall only conduct drilling after approval of the Executive Council.
Drilling is the final technique employed to ascertain whether a nuclear explosion has taken place. Typically, this technique is applied when other techniques have located a potential explosion cavity that needs to be examined for its nuclear nature.
As drilling is about obtaining radioactive samples from the site of the actual explosion, and therefore carries potentially great health risks, the procedure to allow the use of this technique is rather complex.
Strict health and safety precautions must be observed, since it has to be assumed that solid or molten material extracted from the actual location of an explosion or its vicinity is highly radioactive. The samples obtained are then sent for further analysis.