Patent Description:
Moderated neutron detectors are known in the art. Most commonly, thermal neutron detectors are surrounded by a moderating material having a high hydrogen content, such as water, paraffin, HDPE, or ultra-high molecular weight plastic (UHMW). The hydrogen in the moderating material causes neutrons having a broad range of energies to elastically scatter from interactions with hydrogen nuclei, losing kinetic energy in the process. The scattering process is highly efficient, and it may rapidly slow fast or epithermal neutrons such that they are slow enough to be measured by a thermal neutron detector. Moderator thicknesses are commonly in the range of about <NUM> inches to about <NUM> inches.

Typical moderator design dictates that the moderator just surrounds the neutron detector, giving the moderator roughly the same size and shape as the detector. This allows the moderator to be small and light. Moderator weight and size can be a concern for certain applications, as moderating material is typically dense compared to the other aspects of the neutron detector. In some applications, the size and weight of the moderator may be constrained by necessity. For example, a moderated neutron detector in a portal monitor may be constrained in size by government regulations. As another example, the weight of a neutron detector deployed on an unmanned aerial vehicle (UAV) may be payload limited based on the aircraft's range and capabilities.

To increase the sensitivity of a neutron detector without a subsequent increase in size or weight, it is common to employ a neutron detector with a higher inherent sensitivity. At a fixed size, the sensitivity of a detector can be increased based on the amount or type of active material utilized in the detector. For example, high pressure Helium-<NUM> (He3) detectors are more sensitive than low pressure He3 detectors. He3 detectors are more sensitive than boron trifluoride (BF3) gas detectors. The four most common neutron proportional counters are He3, BF3, lithium-<NUM> (Li-<NUM>) foil, and boron-<NUM> (B10) powder. While He3 is the most sensitive detection material, it may cost as much as five times the other common proportional counter materials. Therefore, it can be costly to increase a neutron detector's sensitivity by using highly sensitive detection material.

Neutron detector sensitivity can also be increased by building a larger detector. For example, the volume or number of detection elements may be increased in order to ensure that the neutron detector interacts with more neutrons in the region of neutron flux. This volume or number increase naturally results in higher cost and higher weight, as the detector material used is increased. Additionally, this increase results in an increase in moderating material, which results in a larger increase in the weight of the neutron detector. As a result, building a larger detector may be unfeasible or impractical for many applications.

Thus, a heretofore unaddressed need exists in the industry to address the aforementioned deficiencies and inadequacies.

The invention provides a moderated neutron sensor as defined in claim <NUM>.

Embodiments of the present disclosure provide an apparatus for detecting neutrons. Briefly described, in architecture, one embodiment of the apparatus, among others, can be implemented as follows. A moderated neutron sensor includes a neutron detector having a first volume. A moderating enclosure is positioned around the neutron detector and encloses a second volume. The second volume is between <NUM> and <NUM> times larger than the first volume.

Embodiments of the present disclosure can also be viewed as providing an apparatus for detecting neutrons. Briefly described, in architecture, one embodiment of the apparatus, among others, can be implemented as follows. A moderated neutron sensor includes a neutron detector having an exterior surface. A moderating enclosure is positioned around the neutron detector. The moderating enclosure has an interior surface positioned a spaced distance away from the exterior surface of the neutron detector by at least one half inch.

The present disclosure can also be viewed as providing methods for increased neutron detection. In this regard, one embodiment of such a method, among others, can be broadly summarized by the following steps: positioning a neutron detector within a moderating enclosure, wherein the neutron detector has a first volume, wherein the moderating enclosure encloses a second volume, and wherein the second volume is between <NUM> and <NUM> times larger than the first volume; increasing a quantity of neutrons impingent upon the neutron detector; and measuring the quantity of neutrons impinging upon the neutron detector.

The neutron detectors shown in <FIG> are exemplary only. The present disclosure is not limited to any particular shape, form factor, or embodiment of neutron detector, and may be utilized with any suitable neutron detector.

<FIG> is a top-view illustration of the neutron detector <NUM> of <FIG> within a field of neutron flux <NUM>. In the example shown in <FIG>, a tube neutron detector <NUM> is oriented vertically so that the length of the tube is not visible in the illustration. The tube neutron detector <NUM> may be surrounded by a close fit moderator, creating a moderated neutron detector known in the prior art ("prior art detector") <NUM>. Neutrons <NUM> within a field of neutron flux <NUM> may propagate in relatively straight lines for distances of about <NUM> meters. Neutrons <NUM> that propagate in a direction outside of the path of the prior art detector <NUM> may not impinge upon the tube neutron detector <NUM> and thus, may not be counted. As shown in <FIG>, only a very small portion of neutrons <NUM> within the field of neutron flux <NUM> may reach the detector <NUM>.

Embodiments corresponding to <FIG> are not encompassed by the wording of the claims but are considered as useful for understanding the invention.

<FIG> is a cross-sectional illustration of a tube form factor moderated neutron sensor ("moderated neutron sensor") <NUM>, in accordance with a first exemplary embodiment of the present disclosure. The moderated neutron sensor <NUM> may include a neutron detector <NUM> having a first volume. A moderating enclosure <NUM> is positioned around the neutron detector <NUM> and encloses a second volume. The second volume is between <NUM> and <NUM> times larger than the first volume.

The neutron detector ("neutron detector") <NUM> may be any type, shape, or form of neutron detector suitable for detecting thermal and epithermal neutrons. Detectors of this type may include gas-proportional detectors, scintillation neutron detectors, semiconductor neutron detectors, and the like. The neutron detector <NUM> may be sized and shaped to detect neutrons over a desired area, within size or weight constraints, or with a desired sensitivity. <FIG> shows a cross-section of a tube form factor neutron detector <NUM>. The volume of the neutron detector <NUM> may be calculated as discussed relative to <FIG>, above, using the diameter <NUM> and length of the neutron detector. The volume of the neutron detector <NUM> may be called a first volume.

A moderating enclosure <NUM> may be positioned around the neutron detector <NUM>. The moderating enclosure <NUM> may be made from a moderating material capable of interacting with neutrons of a desired energy range. In the example of a hydrogen-sensitive neutron detector <NUM>, the moderating enclosure <NUM> may be made from a moderating material having a high hydrogen content, such as water, paraffin, HDPE, ultra-high molecular weight plastic (UHMW), or any combination thereof. The moderating enclosure <NUM> may surround and enclose the entire neutron detector <NUM>. In one example, the thickness <NUM> of the moderating enclosure <NUM> may be between <NUM> inches and <NUM> inches. In another example, the thickness <NUM> of the moderating enclosure <NUM> may be greater than <NUM> inches. For example, in applications with higher energy, more monoenergetic neutrons, such as a 5MeV neutron source, the thickness <NUM> of the moderating enclosure <NUM> may be about <NUM> inches. The moderating enclosure <NUM> may enclose a volume, called the second volume. The second volume may be determined from the interior width <NUM>, interior depth <NUM>, and interior length of the moderating enclosure (not shown due to perspective). The interior width <NUM>, interior depth <NUM>, and interior length may be the distance between opposing interior surfaces <NUM> of the moderating enclosure <NUM>.

The second volume enclosed by the moderating enclosure <NUM> may be between <NUM> and <NUM> times larger than the first volume occupied by the neutron detector <NUM>. In particular, the second volume may be between <NUM> and <NUM> times larger than the first volume. More particularly, the second volume may be between <NUM> and <NUM> times larger than the first volume. In one example, the ratio of the second volume to the first volume may correlate with an increase in the sensitivity of the moderated neutron sensor <NUM> up to a maximum value. Thereafter, the second volume enclosed by the moderating enclosure <NUM> may be too large relative to the first volume of the neutron detector <NUM> to effectively direct neutrons to the neutron detector <NUM>. The neutrons may actually be directed away from the neutron detector <NUM> due to the geometry of the moderating enclosure <NUM> at volume ratios larger than <NUM> times larger.

In one example, the second volume may be larger than the first volume due primarily to a difference between the depth <NUM> of the neutron detector <NUM> (shown in <FIG>) and the depth <NUM> of the moderating enclosure <NUM>. Thus, the difference between the depth <NUM> of the neutron detector <NUM> and the interior depth <NUM> of the moderating enclosure <NUM> may be larger than the difference between the length <NUM> of the neutron detector <NUM> and the length of the moderating enclosure <NUM>. In other words, the moderating enclosure <NUM> may be spaced a greater distance from the neutron detector <NUM> along the depth direction than along the length direction. The depth direction may have a more pronounced effect on the moderated neutron sensor <NUM>'s sensitivity than the length direction. Thus, a moderated neutron sensor <NUM> with a deeper moderating enclosure <NUM> may be more sensitive to neutrons than a moderated neutron sensor <NUM> with a longer moderating enclosure <NUM>. This effect may depend on the shapes of the neutron detector <NUM> and the moderating enclosure <NUM>. For instance, a tube-shaped neutron detector <NUM> may detect more neutrons with a deeper or wider moderating enclosure <NUM>, assuming the neutron detector <NUM> is located centrally within the moderating enclosure <NUM>. A sheet-shaped neutron detector <NUM> (shown in <FIG>) may detect more neutrons with a deeper moderating enclosure <NUM>.

In one example, the neutron detector <NUM> may be located centrally within the moderating enclosure <NUM>, meaning that the neutron detector <NUM> is located substantially at and along the center of the interior <NUM> of the moderating enclosure <NUM>. This may be particularly true when the moderated neutron sensor <NUM> includes a single neutron detector <NUM>. When the moderated neutron sensor <NUM> includes two or more neutron detectors <NUM>, the neutron detectors <NUM> may not be located centrally.

The moderated neutron sensor <NUM> may measure neutrons in the 1eV to 2MeV range, including all neutrons between epithermal and fast neutrons. Thus, the moderated neutron sensor <NUM> may be considered a fast or epithermal neutron sensor. By way of example, the moderated neutron sensors shown in this disclosure may be hydrogen-sensitive neutron sensors, although the disclosure is not so limited. Hydrogen-sensitive neutron sensors may detect neutrons having an energy range of <NUM>-<NUM> MeV, which may include cosmogenic neutrons useful for cosmogenic neutron-based soil moisture measurement. The moderating enclosure <NUM> may generally have a thickness between <NUM> and <NUM> inches, which may allow the hydrogen-sensitive neutron sensor to measure neutrons in the range from <NUM>-2MeV, and particularly in the range of 1eV-2MeV. Other types of neutron sensors may be used for environmental neutron monitoring, radioactive waste monitoring, area or perimeter monitoring around nuclear power plants or uranium mines, portal monitoring, and the like. For example, a sensor for measuring fast neutrons propagating from nuclear waste may have a moderating enclosure <NUM> thick enough to thermalize neutrons in the energy band around 5MeV. The thickness <NUM> of the moderating enclosure <NUM> may be appropriate for its intended application in conjunction with the neutron detector <NUM>. In one example, the relationship between the neutron detector <NUM> and the moderating enclosure <NUM> may be understood as a function of the distance <NUM> between an exterior surface <NUM> of the neutron detector <NUM> and an interior surface <NUM> of the moderating enclosure <NUM> ("spaced distance" <NUM>). A moderated neutron detector <NUM> includes a neutron detector <NUM> having an exterior surface <NUM>. A moderating enclosure <NUM> is positioned around the neutron detector <NUM>. The moderating enclosure <NUM> has an interior surface <NUM> positioned a spaced distance <NUM> away from the exterior surface <NUM> of the neutron detector <NUM> by at least one half inch. Thus, for any given thickness <NUM> of the moderating enclosure <NUM>, the moderating enclosure <NUM> and the neutron detector <NUM> may be positioned a spaced distance apart. In one example, the spaced distance <NUM> may be at least <NUM> inches. In another example, the spaced distance may be at least <NUM> inches. In another example the spaced distance may be at least <NUM> inches. When the neutron detector <NUM> and moderating enclosure <NUM> have different shapes, as shown in <FIG>, the spaced distance <NUM> may not be constant at every point between the exterior surface <NUM> of the neutron detector <NUM> and the interior surface of the moderating enclosure <NUM>. The spaced distance <NUM> may be considered to be the minimum distance between any two points on the exterior surface <NUM> and interior surface <NUM>. In this case, the minimum distance between any two points on the exterior surface <NUM> and the interior surface <NUM> may be at least <NUM> inches. In another example, the spaced distance <NUM> may be measured along the length <NUM> of the neutron detector <NUM>, but not from an end surface <NUM> of the neutron detector <NUM>. For instance, when the neutron detector <NUM> is a tube shape, the ends at either extreme of the tube may form an end surface <NUM>, depicted in <FIG> as a circle. In one example, the spaced distance <NUM> may not be measured from the plane of the end surface <NUM>, but may only be considered from the exterior surface <NUM> in an orthogonal plane.

The interior <NUM> between the neutron detector <NUM> and the moderating enclosure <NUM> may include anything that is substantially transparent to the passage of neutrons. In one example, the interior <NUM> may be a vacuum. In another, the interior <NUM> may be filled with air or another substantially transparent gas. In another example, the interior <NUM> may be filled with a substantially transparent liquid or solid. Substantially transparent solids may support the neutron detector <NUM>, holding it in place within the moderating enclosure <NUM>.

The moderated neutron sensor <NUM> may include additional electronic components, such as a power source, communications interface, control hardware, and the like. For portable detectors <NUM>, the power source may be a battery or solar power. The communications interface may allow a user to collect and retrieve neutron data from the moderated neutron detector <NUM>. The communications interface may include communications hardware, such as data ports, antennas, and the like, and may be accessed by wired or wireless communication. The control hardware may allow a user to operate and troubleshoot the device.

<FIG> is a top-view illustration of the moderated neutron sensor <NUM> of <FIG> within a field of neutron flux <NUM>, in accordance with the first exemplary embodiment of the present disclosure. The moderated neutron sensor <NUM> includes the neutron detector <NUM> and the moderating enclosure <NUM>. Just like in <FIG>, above, the neutrons <NUM> in the field of neutron flux <NUM> propagate in a straight line toward and near the moderated neutron sensor <NUM>. However, unlike in <FIG>, a greater number of neutrons <NUM> interact with the moderating enclosure <NUM> and are directed toward the neutron detector <NUM>. Neutrons <NUM> that would have otherwise missed the neutron detector <NUM> may now be read by the moderated neutron sensor <NUM>. It should be noted that not all neutrons <NUM> that interact with the moderating enclosure <NUM> will be directed to the neutron detector <NUM>. However, a greater portion of the neutron flux <NUM> may be directed to the neutron detector <NUM>, resulting in an overall increase in sensitivity.

<FIG> is a cross-sectional illustration of a sheet form factor moderated neutron sensor ("moderated neutron sensor") <NUM>, in accordance with the presently claimed invention. The sheet form factor moderated neutron sensor <NUM> is generally similar to the tube form factor moderated neutron sensor <NUM> of <FIG>, above. The sheet form factor is shown for purposes of illustration.

The moderated neutron sensor <NUM> includes a neutron detector <NUM> having a first volume. A moderating enclosure <NUM> is positioned around the neutron detector <NUM> and encloses a second volume. The second volume is between <NUM> and <NUM> times larger than the first volume. In one example, the second volume is between <NUM> and <NUM> times larger than the first volume. In another example, the second volume is between <NUM> and <NUM> times larger than the first volume.

The moderating enclosure <NUM> is positioned around the neutron detector <NUM> and surrounds and encloses the entire neutron detector <NUM>. In one example, the thickness <NUM> of the moderating enclosure <NUM> may be between about <NUM> inches and <NUM> inches. In another example, the thickness <NUM> of the moderating enclosure <NUM> may be greater than <NUM> inches. For example, in applications with higher energy, more monoenergetic neutrons, such as a 5MeV neutron source, the thickness <NUM> of the moderating enclosure <NUM> may be about <NUM> inches. The moderating enclosure <NUM> encloses a second volume, which is determined from the interior width <NUM>, interior depth <NUM>, and interior length of the moderating enclosure (not shown due to perspective). The interior width <NUM>, interior depth <NUM>, and interior length is the distance between opposing interior surfaces <NUM> of the moderating enclosure <NUM>.

In the presently claimed invention, the second volume is larger than the first volume due to a difference between the depth <NUM> of the neutron detector <NUM> (shown in <FIG>) and the depth <NUM> of the moderating enclosure <NUM>. Thus, the difference between the depth <NUM> of the neutron detector <NUM> and the interior depth <NUM> of the moderating enclosure <NUM> is larger than the difference between the length <NUM> of the neutron detector <NUM> and the length of the moderating enclosure <NUM>. In other words, the moderating enclosure <NUM> is spaced a greater distance from the neutron detector <NUM> along the depth direction than along the length direction.

In one example, the neutron detector <NUM> may be located centrally within the moderating enclosure <NUM>.

In the presently claimed invention, the relationship between the neutron detector <NUM> and the moderating enclosure <NUM> is a function of the distance <NUM> between an exterior surface <NUM> of the neutron detector <NUM> and an interior surface <NUM> of the moderating enclosure <NUM> ("spaced distance" <NUM>). A moderated neutron detector <NUM> includes a neutron detector <NUM> having an exterior surface <NUM>. A moderating enclosure <NUM> is positioned around the neutron detector <NUM>. The moderating enclosure <NUM> has an interior surface <NUM> positioned a spaced distance <NUM> away from the exterior surface <NUM> of the neutron detector <NUM> by at least one half inch. Thus, for any given thickness <NUM> of the moderating enclosure <NUM>, the moderating enclosure <NUM> and the neutron detector <NUM> is positioned a spaced distance apart. In one example, the spaced distance <NUM> may be at least <NUM> inches. In another example, the spaced distance may be at least <NUM> inches. In another example the spaced distance may be at least <NUM> inches. When the neutron detector <NUM> and moderating enclosure <NUM> have different widths <NUM>, <NUM> and depths <NUM>, <NUM>, as shown in <FIG>, the spaced distance <NUM> may not be constant at every point between the exterior surface <NUM> of the neutron detector <NUM> and the interior surface of the moderating enclosure <NUM>. The spaced distance <NUM> is considered to be the minimum distance between any two points on the exterior surface <NUM> and interior surface <NUM>. In this case, the minimum distance between any two points on the exterior surface <NUM> and the interior surface <NUM> may be at least <NUM> inches. In another example, the spaced distance <NUM> may be measured along the length <NUM> of the neutron detector <NUM>, but not from an end surface <NUM> of the neutron detector <NUM>. In one example, the spaced distance <NUM> may not be measured from the plane of the end surface <NUM>, but may only be considered from the exterior surface <NUM> in an orthogonal plane.

The interior <NUM> between the neutron detector <NUM> and the moderating enclosure <NUM> may include anything that is substantially transparent to the passage of neutrons, as discussed relative to <FIG>, above.

<FIG> is an exemplary graph <NUM> showing neutron sensor sensitivity as a function of moderator depth for a lithium-<NUM> panel detector, in accordance with the first exemplary embodiment of the present disclosure. A moderated neutron sensor was constructed according to the disclosure in <FIG>, above. A Li-<NUM> detector was positioned in a moderating enclosure having about <NUM> inch thickness. The length and width of the moderating enclosure were fixed during each measurement, but the depth of the moderating enclosure was increased during each measurement. The neutron count was measured for each iteration of the moderating enclosure depth. The depth values used and resultant sensitivity counts are shown in Table <NUM>, below.

The data from the graph <NUM> in <FIG> seems to indicate that, for this type and shape of moderated neutron sensor, a deeper moderating enclosure correlates with an increase in moderated neutron sensor sensitivity. At a depth of <NUM> inches, the moderated neutron sensor counted about <NUM>% more neutrons per second than the sensor with a moderating enclosure at a depth of <NUM> inches.

In another operating example, the moderating enclosure described in <FIG> and <FIG> was built having interior dimensions of <NUM>"x10"x8" (length x width x depth) and a thickness of <NUM>". A number of neutron detectors were sequentially positioned within the moderating enclosure and used to measure neutrons detected per hour. The neutron detectors were <NUM> inch diameter He3 detectors of <NUM> inch and <NUM> inch lengths, <NUM> inch, <NUM> inch, and <NUM> inch BF3 detectors of <NUM> inch lengths, and a <NUM> inch Li6 panel. The neutron detectors were also positioned within prior art close-fit moderators and used to measure neutrons detected per hour under similar conditions. In another aspect of this example, multiple detectors were positioned within the moderating enclosure, and measurements were taken. The data is shown in Table <NUM>, below.

Table <NUM> shows that each neutron detector saw an increased count over the measurement period when a moderating enclosure was added instead of a close fit moderator. The detector count values from Table <NUM> were then normalized using the detector count values for each neutron detector with a close fit moderator. The normalized results are shown in Table <NUM>, below as detector sensitivity vs. moderator size. The detector count values in Table <NUM> are expressed as a ratio of the actual count rate to the count rate of the detectors using close fit moderators. The sensitivity for each detector with a close-fit moderator is set to <NUM>, while the sensitivity for each detector with a moderating enclosure is set as a ratio.

The data from Table <NUM> shows improvement in sensitivity for each of the detectors in a moderating enclosure. For example, the <NUM>"OD x <NUM>" BF3 detector goes from <NUM> to <NUM>, a significant sensitivity enhancement. For the <NUM>"ODx40" He3 tube the enhancement is nearly <NUM>. For BF3, the biggest increase going from a close fitted (cylindrical or rectangular) moderator to the moderating enclosure is realized with the <NUM>"OD tube. The size of the moderating enclosure (42x12x10) is just such that it best enhances the <NUM>"OD tube. For any given tube diameter, going from a close fit moderator to larger sizes must create a count rate graph that increases at first but which may eventually decrease. During initial increase of moderating enclosure size, more neutrons are captured, and the additional flux increases the count rate; as the moderator continues to increase, more flux is captured, but the interior volume is large enough that the tube samples an increasingly small fraction of that volume. So, the count increase may actually reach a maximum at some particular size, then decrease with increased size. The count increases of <NUM>, <NUM> and <NUM> for the <NUM>", <NUM>" and <NUM>" tubes, respectively, indicate that that <NUM>" tube may already be past its maximum; the <NUM>" tube may be near a maximum; and the <NUM>" tube has not yet achieved a maximum - the moderating enclosure is not large enough. Given the chosen moderating enclosure size, the <NUM>"OD BF3 tube has the best enhancement, with a volume ratio of <NUM>:<NUM> between detector and moderating enclosure. The volume ratios for the <NUM>", <NUM>" and <NUM>" OD detectors are: <NUM>:<NUM>, <NUM>:<NUM> and <NUM>:<NUM>, respectively.

It is noted that the He3 (<NUM>"OD x <NUM>") detector has the largest sensitivity enhancement, which is nearly <NUM>. This may be due to the He3 neutron detector itself, which is more sensitive per unit of volume than the other neutron detectors tested. It is worth noting this enhancement. For mobile detectors using He3, larger moderating enclosures may result in a significant sensitivity enhancement, which in turn may result in a much less costly moderated neutron sensor.

<FIG> is a flow chart <NUM> showing a method for increased neutron detection, in accordance with a second exemplary embodiment of the present disclosure. It should be noted that any process descriptions or blocks in flow charts should be understood as representing modules, segments, or steps that include one or more instructions for implementing specific logical functions in the process, and alternate implementations are included within the scope of the present disclosure in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present disclosure.

Step <NUM> includes positioning a neutron detector within a moderating enclosure, wherein the neutron detector has a first volume, wherein the moderating enclosure encloses a second volume, and wherein the second volume is between <NUM> and <NUM> times larger than the first volume.

The neutron detector ("neutron detector") may be any neutron detector discussed relative to <FIG>, above. The volume of the neutron detector may be the volume occupied by the detector and any tube, sheet, or other structure that holds, contains, or supports the active elements within the neutron detector. The moderating enclosure may be any moderating enclosure discussed relative to <FIG>, above. The second volume enclosed by the moderating enclosure may be the interior volume determined by the interior length, interior width, and interior depth of the moderating enclosure. In one example, the second volume may be between <NUM> and <NUM> times larger than the first volume. In another example, the second volume may be between <NUM> and <NUM> times larger than the first volume. In another example, the second volume may be between <NUM> and <NUM> times larger than the first volume.

In the presently claimed invention, the second volume is larger than the first volume due to a difference between the depth of the neutron detector and the depth of the moderating enclosure. Thus, the difference between the depth of the neutron detector and the interior depth of the moderating enclosure is larger than the difference between the length of the neutron detector and the length of the moderating enclosure. In other words, the moderating enclosure is spaced a greater distance from the neutron detector along the depth direction than along the length direction.

There is a spaced distance between an exterior surface of the neutron detector and an interior surface of the moderating enclosure. The spaced distance creates an interior volume. The interior volume may include anything substantially transparent to the passage of neutrons, including a vacuum, gases such as air, liquids, or solid materials.

In one example, the neutron detector may be centrally located within the moderating enclosure.

In one example, the thickness of the moderating enclosure may be between <NUM> and <NUM> inches. In another example, the thickness of the moderating enclosure may be greater than <NUM> inches. For example, in applications with higher energy, more monoenergetic neutrons, such as a 5MeV neutron source, the thickness of the moderating enclosure may be about <NUM> inches.

Step <NUM> includes measuring a quantity of neutrons impinging upon the neutron detector, whereby the measured quantity of neutrons is increased by the moderating enclosure directing an increased quantity of neutrons toward the neutron detector.

Depending on the intended use and type of neutron detector, measuring a quantity of neutrons may be implemented in a number of ways. For instance, the moderated neutron sensor, which can be considered the neutron detector, moderating enclosure, and associated components, may be positioned above a measurement surface or proximate to a measurement area. The position of the moderated neutron sensor may be located in the path of a field of neutron flux. Neutrons may impinge upon the neutron detector. The moderated neutron sensor may record the quantity of neutrons impinging upon the detector over a desired period of time. This number may be stored in memory, transmitted via a network, or further processed for analysis.

The moderated neutron sensor may be implemented in a number of forms. For example, the moderated neutron sensor may be part of a portal monitor searching for nuclear material passing through an area. In another example, the moderated neutron sensor may be deployed on a vehicle such as an automobile, airplane, unmanned aerial vehicle, and the like. In another example, the moderated neutron sensor may be deployed on a tower, tall building, or satellite.

The measured quantity of neutrons may be increased by the moderating enclosure directing an increased quantity of neutrons toward the neutron detector. This increase may be relative to a bare neutron detector or a neutron detector having a prior art close fit moderator. In one example, the measured quantity of neutrons may be increased by a factor greater than <NUM>. In another example, the measured quantity of neutrons may be increased by a factor greater than <NUM>. In a particular example, the measured quantity of neutrons may be increased by a factor greater than <NUM>.

The method may further include any other features, components, or functions disclosed relative to any other figure of this disclosure.

Claim 1:
A moderated neutron sensor (<NUM>), comprising:
a single, sheet form neutron detector (<NUM>) having a first volume; and
a moderating enclosure (<NUM>) surrounding and enclosing the single, sheet form neutron detector (<NUM>),
wherein the moderating enclosure (<NUM>) encloses a second volume, the second volume determined from an interior width (<NUM>), interior depth (<NUM>), and interior length of the moderating enclosure (<NUM>),
characterized in that:
a difference in a depth (<NUM>) direction between the first volume and the second volume is larger than a difference in length (<NUM>) between the first volume and the second volume, wherein the depth (<NUM>) direction is measured orthogonally across an end face of the single, sheet form neutron detector (<NUM>), wherein a spaced distance (<NUM>), as measured between an exterior surface (<NUM>) of the single, sheet form neutron detector (<NUM>) and an interior surface (<NUM>) of the moderating enclosure (<NUM>), is larger in the depth (<NUM>) direction than a length direction, and wherein the spaced distance (<NUM>) is at least <NUM> (<NUM> inch),
wherein a sensitivity of the single, sheet form neutron detector (<NUM>) is a function of moderating enclosure (<NUM>) depth (<NUM>) measurement relative to the single, sheet form neutron detector (<NUM>),
wherein the sensitivity of the single, sheet form neutron detector (<NUM>) increases as the moderating enclosure (<NUM>) depth (<NUM>) measurement increases.