Patent Publication Number: US-11029429-B2

Title: Pseudogas neutron detector

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation-in-part of U.S. patent application Ser. No. 16/041,379 filed Jul. 20, 2018 titled “PSEUDOGAS NEUTRON DETECTOR,” now U.S. Pat. No. 10,502,849, issued Dec. 10, 2019, the full disclosure of which is incorporated herein by reference in its entirety. 
    
    
     BACKGROUND 
     1. Field of the Invention 
     The present disclosure relates to downhole measurement devices. More particularly, the present disclosure relates to neutron detectors that may be used in downhole environments. 
     2. Description of Related Art 
     During oil and gas operations, various measurements may be acquired downhole in order to evaluate one or more formation properties. In certain situations, nuclear interrogation techniques may be used downhole where a radiation source is emitted into the formation and subsequent radiation (e.g., backscatter, prompt gamma-ray, neutrons, etc.) is measured via a detector located on the tool string. For neutron detection, gas filled helium (He) detectors may be used. Often, the He in these detectors is Helium-3, which may be expensive or difficult to obtain. Alternative neutron detectors are also expensive, toxic, or may be unsuitable for downhole environments. 
     SUMMARY 
     Applicant recognized the problems noted above herein and conceived and developed embodiments of systems and methods, according to the present disclosure, for neutron detectors. 
     In an embodiment, a system for detecting neutrons includes a housing, a gas chamber at least partially defined by the housing, an anode extending through at least a portion of the gas chamber, and a pseudogas arranged within the gas chamber, wherein the pseudogas comprises a mixture of a gas and solid particles. 
     In an embodiment, a method for forming a neutron detector includes forming a gas chamber, determining a gas to particle ratio for a pseudogas, filling the gas chamber with the pseudogas, and sealing the gas chamber. 
     In an embodiment, a system for detecting neutrons includes a housing forming a cathode of a proportional gas counter, a gas chamber formed at least partially by the housing, and an anode extending partially through the gas chamber. The system also includes a pseudogas formed from a combination of dense gas and Boron-containing particles positioned within the gas chamber, wherein the Boron-containing particles are arranged to capture incoming neutrons and increase a current at the anode via the production of charged particles from neutron capture. 
     In an embodiment, a system for detecting neutrons includes a housing forming a cathode of a proportional gas counter, a gas chamber formed at least partially by the housing, and an anode extending partially through the gas chamber. The system also includes a pseudogas formed from a combination of dense gas and Lithium-containing particles positioned within the gas chamber, wherein the Boron-containing particles are arranged to capture incoming neutrons and increase a current at the anode via the production of charged particles from neutron capture. 
     In an embodiment, a system for detecting neutrons includes a housing forming a cathode of a proportional gas counter, a gas chamber formed at least partially by the housing, and an anode extending partially through the gas chamber. The system also includes a pseudogas formed from a combination of dense gas and Uranium-containing particles positioned within the gas chamber, wherein the Boron-containing particles are arranged to capture incoming neutrons and increase a current at the anode via the production of charged particles from neutron capture. 
     In an embodiment, a system for detecting neutrons includes a housing, a gas chamber at least partially defined by the housing, an anode extending through at least a portion of the gas chamber, and a pseudogas arranged within the gas chamber. The pseudogas comprises a mixture of gas and solid particles. In an embodiment, the solid particles are hollow and the pressure of the gas is increased to achieve neutral buoyancy of the hollow particles as they float in the gas. 
     In another embodiment, a system for detecting neutrons includes a housing, a gas chamber at least partially defined by the housing, and an anode extending through at least a portion of the gas chamber. The system also includes a pseudogas arranged within the gas chamber, wherein the pseudogas comprises a mixture of a gas and solid particles, the solid particles containing an element that generates a charged particle after absorbing a thermal neutron. 
     In another embodiment, a method for forming a neutron detector includes forming a gas chamber, determining a gas to particle ratio for a pseudogas, filling the gas chamber with the pseudogas, and sealing the gas chamber. In another embodiment, the particles are nanoparticles which can stay afloat for days or weeks in a gas (very long settling times that depend on particle size and gas density) just from Brownian motion alone without the need for neutral buoyancy. 
     In an embodiment, a system for detecting neutrons includes a housing forming a cathode of a proportional gas counter. The system also includes a gas chamber formed at least partially by the housing. The system further includes an anode extending partially through the gas chamber. The system also includes a pseudogas formed from a combination of a dense gas and particles having high thermal neutron cross sections positioned within the gas chamber, wherein the particles are substantially uniformly distributed within the gas and they capture incoming thermal neutrons and thereby increase a current at the anode via the production of charged particles from neutron capture. For this disclosure, a dense gas is a gas or a supercritical fluid whose density can be increased with pressure at room temperature so as to match the particle density. In various embodiments, the dense gas is nontoxic and chemically nonreactive, such as the inert gases, Xe or Ar, whose critical temperatures are below room temperature so that they never condense to a liquid at any pressure, no matter how high, whenever that temperature is room temperature or above. Although there are other dense gases, such Sulfur Hexafluoride (critical temperature 45.6 C), SF 6  will, at 343 psi, condense to a liquid at 25 C, whose liquid density then changes very little with any further increases in pressure making it hard to match the particle density. The isotope, He-3, has only 0.00014% natural abundance, which is one factor that makes it expensive, and it has a thermal neutron cross section of 5333 barns. In this disclosure, isotopes, which may be used in the solid particles include B-10 (19.9% abundance, 3835 barns), Eu-151 (47.8% abundance, 9100 barns), Cd-113 (12.22% abundance, 20600 barns), Sm-149 (13.9% abundance, 42080 barns), Gd-155 (14.8% abundance, 61100 barns), and Gd-157 (15.7% abundance, 259000 barns), Li-6 (7.5% abundance, 936 barns), U-235 (0.72% abundance, 690 barns). Boron&#39;s low atomic weight permits lower density particles either as elemental boron or, in various embodiments, as chemically bonded to another light element such as carbon, nitrogen, or oxygen thereby making lightweight particles for which it is easier to achieve neutral buoyancy (e.g., substantially infinite settling time) in a pressurized gas, especially if the particle is hollow. Another advantage of Boron is that the energy released when it captures a neutron is high (2310 keV). It exceeds the 765 keV released when He-3 captures a neutron and it far exceeds the 105 keV released when Gd captures a neutron. Also, B-10 has very low sensitivity to interfering gamma rays. That is why Boron Tetrafluoride (BF 3 ) gas neutron detectors are a common alternative to He-3 gas neutron detectors. Unfortunately, BF 3  is both toxic and corrosive and B-10 enriched BF 3  is expensive. The number of B-10 nuclei per unit volume of 100% B-10 enriched BF 3  at the typical 1.0 atmosphere of BF 3  gas pressure that is used can be a factor of 1900 times less than that achieved by embodiments of the present disclosure&#39;s natural-abundance, boron-containing-particle pseudogas at the maximum particle concentration. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
       The foregoing aspects, features, and advantages of the present disclosure will be further appreciated when considered with reference to the following description of embodiments and accompanying drawings. In describing the embodiments of the disclosure illustrated in the appended drawings, specific terminology will be used for the sake of clarity. However, the disclosure is not intended to be limited to the specific terms used, and it is to be understood that each specific term includes equivalents that operate in a similar manner to accomplish a similar purpose. 
         FIG. 1  is a schematic side view of an embodiment of a drilling system, in accordance with embodiments of the present disclosure; 
         FIG. 2  is a schematic cross-sectional view of an embodiment of a neutron detector, in accordance with embodiments of the present disclosure; 
         FIG. 3  is a schematic cross-sectional view of an embodiment of a gas chamber with a pseudogas, in accordance with embodiments of the present disclosure; 
         FIG. 4  is a schematic cross-sectional view of an embodiment of a gas chamber with a pseudogas, in accordance with embodiments of the present disclosure; 
         FIG. 5  is a flow chart of an embodiment of a method for forming a neutron detector with a pseudogas, in accordance with embodiments of the present disclosure; and 
         FIG. 6  is a flow chart of an embodiment of a method for performing neutron detection, in accordance with embodiments of the present disclosure. 
     
    
    
     DETAILED DESCRIPTION 
     The foregoing aspects, features, and advantages of the present disclosure will be further appreciated when considered with reference to the following description of embodiments and accompanying drawings. In describing the embodiments of the disclosure illustrated in the appended drawings, specific terminology will be used for the sake of clarity. However, the disclosure is not intended to be limited to the specific terms used, and it is to be understood that each specific term includes equivalents that operate in a similar manner to accomplish a similar purpose. 
     When introducing elements of various embodiments of the present disclosure, the articles “a”, “an”, “the”, and “said” are intended to mean that there are one or more of the elements. The terms “comprising”, “including”, and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. Any examples of operating parameters and/or environmental conditions are not exclusive of other parameters/conditions of the disclosed embodiments. Additionally, it should be understood that references to “one embodiment”, “an embodiment”, “certain embodiments”, or “other embodiments” of the present disclosure are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features. Furthermore, reference to terms such as “above”, “below”, “upper”, “lower”, “side”, “front”, “back”, or other terms regarding orientation or direction are made with reference to the illustrated embodiments and are not intended to be limiting or exclude other orientations or directions. 
     Embodiments of the present disclosure include systems and methods for detecting radiation in a downhole environment, such as neutrons within a proportional gas counter. In various embodiments, a neutron detector includes a gas chamber that is filled with a pseudogas containing a combination of gas and solid particles, such as substantially hollow particles. In various embodiments, the particles contain Boron and the surrounding gas is Xenon, an inert gas whose high atomic weight permits significant mass density at moderate pressures. In various embodiments, a mass density of the Boron-containing particles may be substantially equal to the Xenon mass density so that the Boron particles can substantially “float” or be suspended within the Xenon gas. As a result, neutrons entering the gas chamber may interact with the substantially uniformly-distributed Boron at a variety of different locations. In various embodiments, the Boron utilized to produce the pseudogas is naturally occurring Boron, which as described herein may be easier to obtain and cheaper than enriched Boron. Furthermore, in various embodiments, the quantity of Boron utilized to create the pseudogas may be particularly selected based on desired properties of the detector, which may be compared to other neutron detectors. 
     It should be appreciated that Boron is provided as an example only, and that in other embodiments, different elements may be utilized to form the substantially hollow particles. For example, Lithium or Uranium containing particles may also be utilized with embodiments of the present disclosure. Utilizing isotopes of Lithium and Uranium, such as Li-6 and U-235, may provide advantage such as avoiding enrichment processes. While the identified isotopes may be relatively rare, as noted above, eliminating the enrichment processes may be sufficient to cost-effectively develop the substantially hollow particles (e.g., solid particles). Furthermore, because elemental Uranium is very dense (19.1 g/cc), various compounds of Uranium may be utilized. For example, Uranyl acetate dehydrate (2.893 g/cc) and Uranyl nitrate hexahydrate (2.81 g/cc) may have low enough densities for utilization with embodiments of the present disclosure. Additionally, compounds including Cadmium and Gadolinium may also be utilized. For example, Cadmium(II) acetate, anhydrous 99% (2.34 g/cc), Cadmium acetate dehydrate (2.01 g/cc), and Gadolinium(III) acetate tetrahydrate (1.611 g/cc) may also be potential candidates for formulation of the solid particles. 
       FIG. 1  is a schematic side view of an embodiment of a downhole drilling system  10  (e.g., drilling system) that includes a rig  12  and a drill string  14  coupled to the rig  12 . The drill string  14  includes a drill bit  16  at a distal end that may be rotated to engage a formation and form a wellbore  18 . In various embodiments, the drill string  14  is formed from one or more tubulars that are mechanically coupled together (e.g., via threads, specialty couplings, or the like). As shown, the wellbore  18  includes a borehole sidewall  20  (e.g., sidewall) and an annulus  22  between the wellbore  18  and the drill string  14 . Moreover, a bottom hole assembly (BHA)  24  is positioned at the bottom of the wellbore  18 . The BHA  24  may include a drill collar  26 , stabilizers  28 , or the like. 
     In operation, drilling mud or drilling fluid is pumped through the drill string  14  and out of the drill bit  16 . The drilling mud flows into the annulus  22  and removes cuttings from the face of the drill bit  16 . Moreover, the drilling mud may cool the drill bit  16  during drilling operations and further provide pressure stabilization in the wellbore  18 . In the illustrated embodiment, the drilling system  10  includes a logging tool  30  that may conduct downhole loggings operations to obtain various measurements. The illustration embodiment further includes a measurement module  32 . As will be described below, in various embodiments, the measurement module  32  may include one or more nuclear sources or detectors for interrogation of the formation. For example, the measurement module  32  may include a neutron or gamma ray (e.g., gamma) source that emits radioactive energy into the formation. The radioactive energy may interact with various components of the formation, such as rocks, dirt, hydrocarbon, water, etc. and thereafter facilitate reactions, such as capture, scattering, and the like. The measurement module  32  may further include a radiation detector, which may be sufficiently shielded from the radiation source to enable detection of radioactivity substantially from the formation and not from the source. In various embodiments, as will be described below, the radiation detector may be a neutron detector. However, it should be appreciated that gamma detectors, such as spectroscopy detectors, may also be used. Furthermore, while the illustrated embodiment includes the measurement module  32  on the drill string  14 , it should be appreciated that, in various embodiments, the measurement module  32  may be incorporated into a wireline system, a coiled tubing system, or any other downhole investigation system. 
       FIG. 2  is a schematic diagram of an embodiment of a neutron detector  50  (e.g., detector), which may be a proportional fill detector or proportional counter. In operation, the detector  50  measures particles of ionizing radiation. For example, a neutron may enter a chamber filled with a gas, collide with an atom of the gas, and ionize it to produce an electron and a positively charged ion. An anode extending through the chamber may be supplied with electrical current, which will increase due to the electric current flow produced by the resulting electron and positively charged ion. Detecting the increase in current flow may be correlated to detection of radiation within the chamber. 
     In the illustrated embodiment, the neutron detector  50  may be a high pressure Xenon (Xe) detector (e.g., HPXe detector). As will be appreciated, HPXe detectors provide a variety of unique benefits such as high stopping power, a low Fano-factor, mechanical and chemical stability, and low energy for the production of electron-ion pairs. Additionally, HPXe detectors are relatively low cost when compared to comparable detectors, such as High Purity Germanium (HPGe) and Cadmium Zinc Telluride (CZT). Furthermore, HPXe detectors provide the significant benefit over HPGe detectors in that HPXe do not use a supply of cryogenic gas to cool the detector. It should be appreciated that, in various embodiments, HPXe detectors may be used in gamma ray spectroscopy. However, in various embodiments described herein, the HPXe detector may be modified to enable detection of neutrons. Gamma ray shielding may be provided to selectively transmit impinging neutrons and to reject impinging gamma rays. 
     As will be described below, the addition of a material, or combinations of materials, having a high thermal neutron cross section may be added to the gas chamber to enable detection of thermal neutrons. It should be appreciated that various materials have a high thermal neutron cross section, and as a result, in various embodiments the material added to the detector may have a thermal neutron cross section above a pre-determined threshold. For simplicity, various embodiments described herein will use Boron as the material having the high thermal neutron cross section. Accordingly, it should be appreciated that Boron (or in various embodiments Boron-10) has a thermal neutron cross section at least greater than the threshold. However, as noted above, other elements and isotopes may be utilized that have a thermal neutron cross section greater than the threshold. In various embodiments, Boron (which includes a proportion of Boron-10) may be added to the gas chamber to enable detection of thermal neutrons. The illustrated detector  50  includes a housing  52 , which may act as a cathode during operation. The housing  52  encloses a gas chamber  54 , which as will be described below may include a pseudogas. The pseudogas may be a combination of Xe gas and Boron-containing particles suspended within the Xe gas. Extending through the gas chamber  54  is an anode  56 , which receives electrical energy from a power supply  58 . The illustrated embodiment further includes a Frisch grid  60  arranged proximate the anode, but it should be appreciated that the Frisch grid  60  is optional and may be omitted in certain embodiments. It should be appreciated that various features of the detector  50  have been omitted for clarity and will not be described herein, such as various insulators, valves, supports, filters, electrical components, and the like. 
     Naturally occurring Boron (B) has two different forms, Boron-11 (B-11) and Boron-10 (B-10). B-11 occurs with approximately 80.1 percent natural abundance, while B-10 occurs with approximately 19.9 percent natural abundance. B-10 has a substantially higher thermal neutron cross-section, which is directly related to its ability to capture thermal neutrons. That is, a larger neutron cross section is associated with a higher likelihood of neutron capture. Accordingly, B-10 is preferred for neutron detection because the thermal neutron cross section is greater than the cross section for B-11. Certain radiation detectors may utilize enriched quantities of B that have a greater percentage of B-10 than the naturally occurring levels. However, enriching natural B to high percentage of B-10 may be prohibitively expensive. 
     Furthermore, as described above, in order to provide the cascading reaction for detection within the detector  50 , particles for interaction with the ion pairs are required within the gas chamber  54 . That is, filling the detector  50  with only B-10 will capture neutrons, but it will not produce the associated ionizing particles utilized for detection with proportional gas counters. Some neutron detectors may include Boron Trifluoride (BF 3 ) consisting of a gas chamber filled with BF 3  gas at approximately 0.5 to 1 atmosphere. BF 3  is a toxic and/or corrosive gas, and BF 3  detectors utilize high voltage requirements (e.g., 1500 to 2000 volts) to detect neutrons. Furthermore, in various embodiments of enriched BF 3  may be subject to export controls, further increasing costs because of the costs of compliance. 
       FIG. 3  is a schematic cross-sectional view of an embodiment of the gas chamber  54  comprising a pseudogas  70  formed at least in part by a combination of a gas  72  and solid particles  74 . In various embodiments, the solid particles  74  may be nanoparticles, which are particles having a diameter between 1 and 100 nm. However, it should be appreciated that the particles  74  may not be nanoparticles in various embodiments. It should be appreciated that the particle density, dispersion, size, and general arrangement is for illustrative purposes only and is not intended to limit the disclosure. For example, the particle density and/or ratio of solid particles to gas may be particularly selected based on a variety of factors, such as detector size, operating conditions, costs, and the like. In various embodiments, the solid particles  74  may be Boron-containing and also substantially hollow, spherical particles that “float” or are otherwise suspended within the gas chamber  54 . However, as noted herein, the substantially hollow solid particles  74  may contain other elements and/or isotopes. One method of production of Boron-containing nanoparticles  74  is discussed in “Controlled Fabrication of Ultrathin-shell BN Hollow Spheres with Excellent Performance in Hydrogen Storage and Wastewater Treatment” by Lian et al. in Energy &amp; Environmental Science, Issue 5, 2012, which is hereby incorporated by reference. This paper describes 50 nm diameter Boron Nitride microspheres having 2 nm wall thickness so that only 22% of the sphere&#39;s total volume is Boron Nitride, which, if solidly-packed, would have 1900 times the Boron per unit volume as the typical BF 3  detector. By way of example, the density of solid Boron Nitride is 2.100 g/cc, so the density of these hollow Boron Nitride microspheres is 0.465 g/cc, which, according to the online NIST Chemistry WebBook, equals the density of Xe gas at 783 psi and 25 C or the density of Ar gas at 4120 psi and 25 C. A solid Boron Nitride particle would float in Xe gas at 2800 psi and 25 C or in Ar gas at greater than 145,000 psi and 25 C. The density of pure Boron is 2.46 g/cc so it would float in Xe gas at 7300 psi and 25 C. In various embodiments, particles of low toxicity and low enough mass density (e.g., below a threshold amount) enable gas pressures within reasonable values while still maximizing a number of moles of Boron per unit volume. 
     The Boron molar density (mol/cc) is the compound&#39;s molar density multiplied by the number of Boron atoms in that compound. A compound&#39;s molar density (mol/cc) is its mass density (g/cc) divided by its molecular weight (g/mol). The properties of Boron, B, are 2.46 g/cc, 10.811 g/mol, with 0.228 mol/cc of Boron. The properties of Boron Carbide, B 4 C, are 2.52 g/cc, 55.255 g/mol, with 0.182 mol/cc of Boron. The properties of Boron Nitride, BN, are 2.10 g/cc, 24.817 g/mol, with 0.085 mol/cc of Boron. The properties of Boron Oxide, B 2 O 3 , are 2.46 g/cc, 69.618 g/mol, with 0.071 mol/cc of Boron. Boron Carbide and Boron Nitride have low toxicity but Boron Carbide has the higher molar density of Boron. Hollow spheres of Boron Carbide have been made (J. L. Wang et al., “Boron Carbide Hollow Microspheres Prepared by Polymer Derived Method”, Key Engineering Materials, Vol. 726, pp. 159-163, 2017), which are 8.7% solid corresponding to a density of 0.22 g/cc, which would float in Xe at 480 psi at 25 C or in Ar at 1880 psi at 25 C. If the walls of these hollow Boron Carbon spheres were made thicker to equal 22% of the sphere&#39;s volume (as was the case for the earlier example of Boron Nitride hollow spheres) then the density would be 0.56 g/cc corresponding to Xe at 845 psi and 25 C and a solidly-packed detector using such Boron Carbide hollow particles would have approximately 4090 times more B-10 than an equivalent BF 3  detector. 
     As used herein, the pseudogas  70  refers to a mixture of gas atoms  72  and solid particles  74 , such as the Boron-containing particles. In certain embodiments, properties of the gas atoms  72  and particles  74  may be particularly selected to suspend the particles  74  among the gas atoms  72 . In various embodiments, the illustrated gas atoms  72  are Xe atoms, but it should be appreciated that other gases, such as Ar and the like, may be utilized. Xe gas provides the advantage of being non-radioactive, having the highest density of any non-radioactive inert gas, and providing ample atoms for ionization in a proportional gas tube. 
     In the illustrated embodiment, the Boron-containing particles  74  may be formed such that they have substantially neutral buoyancy relative to the Xe gas  72 . That is, the Boron-containing particles  74  may be said to “float” or otherwise settle very slowly within the gas chamber  54 , for example over a period of several days or longer. In other words, the density of the Boron-containing particles  74  may be calculated to be approximately equal to the density of the Xe gas  72 . Once filled, the volume of the chamber is fixed, which means that the number of moles of trapped gas is fixed and the corresponding mass density of the trapped gas is also fixed. Any increase in temperature will increase the pressure but it will not change the mass density. As will be appreciated, the mass density of the Boron-containing particles  74  may be calculated to be substantially equal to the density of the Xe such that the Boron-containing particles  74  will have neutral buoyancy within the gas chamber  54 . 
     The fraction of solid material in the hollow (or substantially hollow) particles may be calculated from their diameter and wall thickness. Assuming negligible mass density of any gas that may have been trapped inside of the hollow during fabrication, the hollow particle&#39;s mass density is the solid fraction multiplied by the mass density of that solid. The number of B-10 nuclei per unit volume may be calculated from the total number of B nuclei per unit volume multiplied by the 19.9% natural abundance of B-10. In this manner, the volume of the Boron-containing particles  74  may be calculated to provide for manufacturing and filling of the gas chamber  54 . 
     As described above, BF 3  detectors may be utilized despite the various drawbacks. Accordingly, when designing embodiments of the present disclosure, various properties of B within the BF 3  detector may be evaluated. For example, BF 3  detectors may have a particular weight fraction of B-10 or B-10 mole density. Accordingly, the same values for the Boron-containing particles  74  may be calculated and compared to BF 3  detectors. In various embodiments, utilizing Boron-containing particles  74  may enable significantly more B-10 within the gas chamber  54  than by utilizing BF 3  detectors. Furthermore, the Boron-containing particles  74  may be formed from naturally occurring B, rather than enriched B-10, which decreases the cost. In various embodiments, a solidly-packed detector using the Boron-containing particles  74  may have approximately 1900 times more B-10 than an equivalent BF 3  detector. As such, the detector  50  of the illustrated embodiment need not be solidly-packed to have adequate B-10 for interaction with neutrons. However, as described above, it should be appreciated that other configurations of Boron-containing particles  74  may have approximately 4000 times more B-10 than an equivalent BF 3  detector. 
     As described above, in various embodiments the gas chamber  54  includes the pseudogas  70  comprising a mixture of both the Xe atoms  72  (e.g., Xe gas, gas) and the Boron-containing particles  74 . The Boron-containing particles  74  may be dispersed throughout the gas chamber  54 , and need not “fully pack” the gas chamber  54  so as to enable sufficient Xe gas particles  74  for interaction with the ion pairs generated through neutron capture. Accordingly, the Boron-containing particles  74  may be dispersed throughout the Xe gas particles  72  within the gas chamber  54 , as shown in the embodiment illustrated in  FIG. 3 . In various embodiments, the gas chamber  54  may be pressurized to a particular pressure, such as approximately 1000 psi. 
     It should be appreciated that, when the Boron-containing particles are nanoparticles, then, due to their small size and weight, the settling and collection of the Boron nanoparticles  74  may be significantly reduced or adjusted for. Because particle settling under gravity is a function of aerodynamic size, very small particles (e.g., Aerodynamic Equivalent Diameter, AED, less than 100 nm) can take up to one month to settle out of completely still air. Additionally, gas density may also influence settling time. Accordingly, settling within the gas chamber  54  may be inconsequential for anticipated operations, which are usually completed within a few days. Furthermore, it should be appreciated that the long settling time enables the detector  50  to be remixed automatically by shakes or external forces due to tripping into and out of the wellbore. 
     As noted above, Boron-containing particles are described as an example, but embodiments of the present disclosure are not limited to Boron-containing particles. For example, the particles may be formed from other isotopes, such as Li-6 and/or U-235 and/or compounds thereof. For example, light-weight compounds of Lithium and Uranium may be utilized due to the maximum practical density of Xenon being approximately 2.5 g/cc. As noted above, Uranyl acetate dehydrate (2.893 g/cc) and Uranyl nitrate hexahydrate (2.81 g/cc) may be utilized in embodiments of the present disclosure. Other non-limiting examples include LiF (2.635 g/cc), Li 2 CO 3  (2.11 g/cc), and Li 3 PO 4  (2.40 g/cc). Furthermore, lightweight compounds of Cadmium and/or Gadolinium may also be used, including as non-limiting examples Cadmium(II) acetate, anhydrous 99% (2.34 g/cc), Cadmium acetate dehydrate (2.01 g/cc), and Gadolinium(III) acetate tetrahydrate (1.611 g/cc). 
       FIG. 4  is a schematic cross-sectional view of an embodiment of the gas chamber  54  comprising the pseudogas  70 . In the illustrated embodiment, a neutron particle  80  interacts with a Boron-containing particle  74  (which may be a particle of any element having a thermal neutron cross section above the threshold) to produce an alpha particle  82 . It should be appreciated that a Lithium-7 particle may also be produced due to the capture of the neutron particle  80 , but this has been omitted for clarity in the discussion. The energy from the alpha particle  82  interacts with the Xe particles  72  to energize the anode  56 , thereby enabling detection of the neutron capture within the detector  50 . As described above, by reducing the packing of the Boron-containing particles within the gas chamber  54 , additional Xe particles  72  may be included, thereby increasing the available particles for ionization by the release of the alpha particle  82 . Accordingly, the detector  50  may be utilized to detect neutrons with reduced costs compared to traditional detectors, such as He-3 or BF 3  because the illustrated detector  50  uses solid particles that contain Boron and, generally, the number of moles per unit volume of an element that is part of a solid is far greater than the number of moles per unit volume of that same element if it had existed in the form of a gas. Because the molar density of Boron in a solid is so high compared to a gas, it becomes possible to use unenriched, naturally-occurring Boron, which is less costly than both He-3 and enriched B-10. 
       FIG. 5  is a flow chart of an embodiment of a method  100  for preparing a neutron detector. It should be understood that, for any process or method described herein, that there can be additional, alternative, or fewer steps performed in similar or alternative orders, or concurrently, within the scope of the various embodiments unless otherwise specifically stated. The method  100  may begin by forming a gas chamber having at least an anode and cathode (block  102 ), such as the gas chamber  54 , anode  56 , and the housing  52  (which may act as a cathode). In other words, a proportional gas counter may be formed using various materials, as will be appreciated by one skilled in the art. The method may continue by calculating the desired boron ratio within the gas chamber (block  104 ). For example, as described above, the gas chamber may be compared to an equivalent BF 3  detector and thereafter a ratio between the two may be calculated. In various embodiments, the ratio of a gas chamber packed solidly to maximum number of Boron-containing particles may be significantly greater than the equivalent BF 3  detector, thereby enabling the gas chamber of the embodiments herein to not need to be packed solid with Boron-containing particles and, thereby, provide more than ample space for ionization of the gas in the chamber. While the method is described with respect to Boron-containing particles, as noted herein, other elements and isotopes may be utilized. As a result, the calculation may be with respect to other isotopes, such as Li-6, U-235, Cd-113, Gd-157. Thereafter, the Boron-containing particles (or other particles) may be formed (block  106 ). The gas chamber is then filled with a gas, such as Xenon, and the Boron-containing particles (or other particles) (block  108 ). In various embodiments, the size of the Boron-containing particles may be small enough that settling may not be significant over short periods of time, although neutral buoyancy may be obtained in various embodiments to insure that that distribution of suspended solid particles is uniform or substantially uniform in the chamber. Furthermore, a calculated density of the Boron-containing particles may be substantially equal to the gas, thereby enabling the nanoparticles to “float” or otherwise be suspended within the gas to generate a pseudogas. These desirable characteristics may also be calculated and formed with respect to other isotopes utilized with embodiments of the present disclosure. Next, the gas chamber is sealed (block  110 ) to form the gas detector. 
       FIG. 6  is a flow chart of a method  120  for performing downhole operations using a gas detector. In the illustrated embodiment, the method  120  begins with forming a pseudogas gas comprising gas and solid particles (block  122 ). In various embodiments, the pseudogas may be formed between Xe gas and Boron-containing particles, which in various embodiments may be hollow, but other isotopes may be utilized. It should be appreciated that the density of the Boron-containing particles may be substantially equal to the density of the Xe gas such that the Boron-containing particles are substantially suspended or “float” within the Xe gas. In various embodiments, the Boron-containing particles may be have neutral buoyancy within the Xe gas. Next, a proportional gas counter is formed using the pseudogas (block  124 ). The detector may be arranged on a drill string for conducting downhole operations, such as drilling, logging, measurements, and the like (block  126 ). The drill string may be lowered into a wellbore (block  128 ) and the formation may be interrogated with radioactive energy, in certain embodiments. Thereafter, the detector may be used to detect neutron particles emitted from the formation. It should be appreciated that, in other embodiments, the formation may not be interrogated with radioactive energy. The detector may receive information (block  130 ) corresponding to the neutron activity of the formation. This information may be utilized to analyze and determine various properties of the formation, such as the composition of the formation. In this manner, downhole operations may be performed using a gas detector including a pseudogas. 
     While various embodiments of the instant application may be directed to oil and gas technologies, for example formation evaluation, it should be appreciated that embodiments of the present disclosure may be deployed in a variety of industries and technology sectors. For example, security and defense industries may utilize embodiments of the present disclosure for screening purposes, for example at international borders, transit centers, shipping areas, and the like. Additionally, in various embodiments, medical devices such as PET/CT and SPECT/MRI instruments may utilize neutron detector technologies. Moreover, scientific research applications, such as neutron scatting beam lines, may benefit from the use of the disclosed neutron detectors. Other potential applications also include industrial monitoring (e.g., personnel, soil, water, etc.), nuclear decommission and inspection, aerospace, and energy. 
     The foregoing disclosure and description of the disclosed embodiments is illustrative and explanatory of the embodiments of the invention. Various changes in the details of the illustrated embodiments can be made within the scope of the appended claims without departing from the true spirit of the disclosure. The embodiments of the present disclosure should only be limited by the following claims and their legal equivalents.