DEVICE AND METHOD FOR PRODUCING MEDICAL ISOTOPES
A hybrid nuclear reactor that is operable to produce a medical isotope includes an ion source operable to produce an ion beam from a gas, a target chamber including a target that interacts with the ion beam to produce neutrons, and an activation cell positioned proximate the target chamber and including a parent material that interacts with the neutrons to produce the medical isotope via a fission reaction. An attenuator is positioned proximate the activation cell and selected to maintain the fission reaction at a subcritical level, a reflector is positioned proximate the target chamber and selected to reflect neutrons toward the activation cell, and a moderator substantially surrounds the activation cell, the attenuator, and the reflector.
This application is a divisional of U.S. application Ser. No. 15/644,497, filed Jul. 7, 2017, which is a divisional of U.S. application Ser. No. 12/990,758, filed Jan. 12, 2011, which issued Aug. 15, 2017, as U.S. Pat. No. 9,734,926 and is a U.S. national stage filing of International Application No. PCT/US2009/042587, filed May 1, 2009, which claims priority to U.S. Provisional Application No. 61/050,096, filed May 2, 2008, each of which is fully incorporated herein by reference in its entirety.
BACKGROUNDThe invention relates to device and method for producing medical isotopes. More particularly, the invention relates to a device and method for producing neutron generated medical isotopes with or without a sub-critical reactor and low enriched uranium (LEU).
Radioisotopes are commonly used by doctors in nuclear medicine. The most commonly used of these isotopes is 99Mo. Much of the supply of 99Mo is developed from highly enriched uranium (HEU). The HEU employed is sufficiently enriched to make nuclear weapons. HEU is exported from the United States to facilitate the production of the needed 99Mo. It is desirable to produce the needed 99Mo without the use of HEU.
SUMMARYIn one embodiment, the invention provides a hybrid nuclear reactor that is operable to produce a medical isotope. The reactor includes an ion source operable to produce an ion beam from a gas, a target chamber including a target that interacts with the ion beam to produce neutrons, and an activation cell positioned proximate the target chamber and including a parent material that interacts with the neutrons to produce the medical isotope via a fission reaction. An attenuator is positioned proximate the activation cell and selected to maintain the fission reaction at a subcritical level, a reflector is positioned proximate the target chamber and selected to reflect neutrons toward the activation cell, and a moderator substantially surrounds the activation cell, the attenuator, and the reflector.
In another embodiment, the invention provides a hybrid nuclear reactor that is operable to produce a medical isotope. The reactor includes a fusion portion including a long target path that substantially encircles a space. The fusion portion is operable to produce a neutron flux within the target path. A reflector substantially surrounds the long target path and is arranged to reflect a portion of the neutron flux toward the space. An activation cell is positioned within the space and includes a parent material that reacts with a portion of the neutron flux to produce the medical isotope during a fission reaction. An attenuator is positioned within the activation cell and is selected to maintain the fission reaction at a subcritical level and a moderator substantially surrounds the activation cell, the attenuator, and the reflector.
In another embodiment, the invention provides a method of producing a medical isotope. The method includes exciting a gas to produce an ion beam, accelerating the ion beam, and passing the accelerated ion beam through a long target path including a target gas. The target gas and the ions react through a fusion reaction to produce neutrons. The method also includes reflecting a portion of the neutrons with a reflector that substantially surrounds the long target path, positioning a parent material within an activation chamber adjacent the long target path, and maintaining a fission reaction between a portion of the neutrons and the parent material to produce the medical isotope. The method further includes positioning an attenuator adjacent the activation chamber and converting a portion of the neutrons to thermal neutrons within the attenuator to enhance the fission reaction within the activation chamber.
In still another embodiment, the invention provides a method of producing a medical isotope. The method includes exciting a gas to produce an ion beam, accelerating the ion beam, and passing the accelerated ion beam through a substantially linear target path including a target gas. The target gas and the ions react through a fusion reaction to produce free neutrons. The method also includes reflecting a portion of the free neutrons with a reflector positioned radially outward of the target path, positioning a parent material within an activation chamber adjacent the target path, and reacting the free neutrons and the parent material to produce the medical isotope without the use of fissile material.
Other aspects and embodiments of the invention will become apparent by consideration of the detailed description and accompanying drawings.
The invention may be better understood and appreciated by reference to the detailed description of specific embodiments presented herein in conjunction with the accompanying drawings of which:
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
Before explaining at least one embodiment, it is to be understood that the invention is not limited in its application to the details set forth in the following description as exemplified by the Examples. Such description and Examples are not intended to limit the scope of the invention as set forth in the appended claims. The invention is capable of other embodiments or of being practiced or carried out in various ways.
Throughout this disclosure, various aspects of this invention may be presented in a range format. It should be understood that the description in range format is merely for convenience and brevity, and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, as will be understood by one skilled in the art, for any and all purposes, particularly in terms of providing a written description, all ranges disclosed herein also encompass any and all possible subranges and combinations of subranges thereof, as well as all integral and fractional numerical values within that range. As only one example, a range of 20% to 40% can be broken down into ranges of 20% to 32.5% and 32.5% to 40%, 20% to 27.5% and 27.5% to 40%, etc. Any listed range can be easily recognized as sufficiently describing and enabling the same range being broken down into at least equal halves, thirds, quarters, fifths, tenths, etc. As a non-limiting example, each range discussed herein can be readily broken down into a lower third, middle third, and upper third, etc. Further, as will also be understood by one skilled in the art, all language such as “up to,” “at least,” “greater than,” “less than,” “more than” and the like include the number recited and refer to ranges which can be subsequently broken down into subranges as discussed above. In the same manner, all ratios disclosed herein also include all subratios falling within the broader ratio. These are only examples of what is specifically intended. Further, the phrases “ranging/ranges between” a first indicate number and a second indicate number and “ranging/ranges from” a first indicate number “to” a second indicate number are used herein interchangeably.
Terms such as “substantially,” “about,” “approximately” and the like are used herein to describe features and characteristics that can deviate from an ideal or described condition without having a significant impact on the performance of the device. For example, “substantially parallel” could be used to describe features that are desirably parallel but that could deviate by an angle of up to 20 degrees so long as the deviation does not have a significant adverse effect on the device. Similarly, “substantially linear” could include a slightly curved path or a path that winds slightly so long as the deviation from linearity does not significantly adversely effect the performance of the device.
As illustrated in
In view of the disadvantages inherent in the conventional types of proton or neutron sources, the fusion portions 10, 11 provide a novel high energy proton or neutron source (sometimes referred to herein generically as an ion source but more correctly considered a particle source) that may be utilized for the production of medical isotopes. Each fusion portion 10, 11 uses a small amount of energy to create a fusion reaction, which then creates higher energy protons or neutrons that may be used for isotope production. Using a small amount of energy may allow the device to be more compact than previous conventional devices.
Each fusion portion 10, 11 suitably generates protons that may be used to generate other isotopes including but not limited to 18F, 11C, 15O, 13N, 63Zn, 124I and many others. By changing fuel types, each fusion portion may also be used to generate high fluxes of isotropic neutrons that may be used to generate isotopes including but not limited to 131I, 133Xe, 111In, 125I, 99Mo (which decays to 99mTc) and many others. As such, each fusion portion 10, 11 provides a novel compact high energy proton or neutron source for uses such as medical isotope generation that has many of the advantages over the proton or neutron sources mentioned heretofore.
In general, each fusion portion 10, 11 provides an apparatus for generating protons or neutrons, which, in turn, are suitably used to generate a variety of radionuclides (or radioisotopes). With reference to
It should be noted that while an RF-driven ion generator or ion source is described herein, other systems and devices are also well-suited to generating the desired ions. For example, other constructions could employ a DC arc source in place of or in conjunction with the RF-driven ion generator or ion source. Still other constructions could use hot cathode ion sources, cold cathode ion sources, laser ion sources, field emission sources, and/or field evaporation sources in place of or in conjunction with a DC arc source and or an RF-driven ion generator or ion source. As such, the invention should not be limited to constructions that employ an RF-driven ion generator or ion source.
As discussed, the fusion portion can be arranged in a magnetic configuration 10 and/or a linear configuration 11. The six major sections or components of the device are connected as shown in
The ion source 20 (
Ion injector 26 includes one or more shaped stages (23, 35). Each stage of the ion injector includes an acceleration electrode 32 suitably made from conductive materials that may include metals and alloys to provide effective collimation of the ion beam. For example, the electrodes are suitably made from a conductive metal with a low sputtering coefficient, e.g., tungsten. Other suitable materials may include aluminum, steel, stainless steel, graphite, molybdenum, tantalum, and others. RF antenna 24 is connected at one end to the output of an RF impedance matching circuit (not shown) and at the other end to ground. The RF impedance matching circuit may tune the antenna to match the impedance required by the generator and establish an RF resonance. RF antenna 24 suitably generates a wide range of RF frequencies, including but not limited to 0 Hz to tens of kHz to tens of MHz to GHz and greater. RF antenna 24 may be water-cooled by an external water cooler (not shown) so that it can tolerate high power dissipation with a minimal change in resistance. The matching circuit in a turn of RF antenna 24 may be connected to an RF power generator (not shown). Ion source 20, the matching circuit, and the RF power generator may be floating (isolated from ground) at the highest accelerator potential or slightly higher, and this potential may be obtained by an electrical connection to a high voltage power supply. RF power generator may be remotely adjustable, so that the beam intensity may be controlled by the user, or alternatively, by computer system. RF antenna 24 connected to vacuum chamber 25 suitably positively ionizes the fuel, creating an ion beam. Alternative means for creating ions are known by those of skill in the art and may include microwave discharge, electron-impact ionization, and laser ionization.
Accelerator 30 (
Each acceleration electrode 32 of accelerator 30 can be supplied bias either from high voltage power supplies (not shown), or from a resistive divider network (not shown) as is known by those of skill in the art. The divider for most cases may be the most suitable configuration due to its simplicity. In the configuration with a resistive divider network, the ion source end of the accelerator may be connected to the high voltage power supply, and the second to last accelerator electrode 32 may be connected to ground. The intermediate voltages of the accelerator electrodes 32 may be set by the resistive divider. The final stage of the accelerator is suitably biased negatively via the last acceleration electrode to prevent electrons from the target chamber from streaming back into accelerator 30.
In an alternate embodiment, a linac (for example, a RF quadrapole) may be used instead of an accelerator 30 as described above. A linac may have reduced efficiency and be larger in size compared to accelerator 30 described above. The linac may be connected to ion source 20 at a first end and connected to differential pumping system 40 at the other end. Linacs may use RF instead of direct current and high voltage to obtain high particle energies, and they may be constructed as is known in the art.
Differential pumping system 40 (
In some constructions, the pressure reducing barriers 42 are replaced or enhanced by plasma windows. Plasma windows include a small hole similar to those employed as pressure reducing barriers. However, a dense plasma is formed over the hole to inhibit the flow of gas through the small hole while still allowing the ion beam to pass. A magnetic or electric field is formed in or near the hole to hold the plasma in place.
Gas filtration system 50 is suitably connected at its vacuum pump isolation valves 51 to vacuum pump exhausts 41 of differential pumping system 40 or to additional compressors (not shown). Gas filtration system 50 (
Vacuum pump isolation valves 51 and target chamber isolation valves 52 may facilitate gas filtration system 50 to be isolated from the rest of the device and connected to an external pump (not shown) via pump-out valve 53 when the traps become saturated with gas. As such, if vacuum pump isolation valves 51 and target chamber isolation valves 52 are closed, pump-out valves 53 can be opened to pump out impurities.
Target chamber 60 (
For the magnetic system 12, target chamber 60 may resemble a thick pancake, about 10 cm to about 1 m tall and about 10 cm to about 10 m in diameter. Suitably, the target chamber 60 for the magnetic system 12 may be about 20 cm to about 50 cm tall and approximately 50 cm in diameter. For the magnetic target chamber 60, a pair of either permanent magnets or electromagnets (ion confinement magnet 12) may be located on the faces of the pancake, outside of the vacuum walls or around the outer diameter of the target chamber (see
r=1.44√{square root over (E)}/B (1)
for deuterons, wherein r is in meters, E is the beam energy in eV, and B is the magnetic field strength in gauss. The magnets may be oriented parallel to the flat faces of the pancake and polarized so that a magnetic field exists that is perpendicular to the direction of the beam from the accelerator 30, that is, the magnets may be mounted to the top and bottom of the chamber to cause ion recirculation. In another embodiment employing magnetic target chamber 60, there are suitably additional magnets on the top and bottom of the target chamber to create mirror fields on either end of the magnetic target chamber (top and bottom) that create localized regions of stronger magnetic field at both ends of the target chamber, creating a mirror effect that causes the ion beam to be reflected away from the ends of the target chamber. These additional magnets creating the mirror fields may be permanent magnets or electromagnets. It is also desirable to provide a stronger magnetic field near the radial edge of the target chamber to create a similar mirror effect. Again, a shaped magnetic circuit or additional magnets could be employed to provide the desired strong magnetic field. One end of the target chamber is operatively connected to differential pumping system 40 via differential pumping mating flange 33, and a gas recirculation port 62 allows for gas to re-enter the target chamber from gas filtration system 50. The target chamber may also include feedthrough ports (not shown) to allow for various isotope generating apparatus to be connected.
In the magnetic configuration of the target chamber 60, the magnetic field confines the ions in the target chamber. In the linear configuration of the target chamber 70, the injected ions are confined by the target gas. When used as a proton or neutron source, the target chamber may require shielding to protect the operator of the device from radiation, and the shielding may be provided by concrete walls suitably at least one foot thick. Alternatively, the device may be stored underground or in a bunker, distanced away from users, or water or other fluid may be used a shield, or combinations thereof.
Both differential pumping system 40 and gas filtration system 50 may feed into the target chamber 60 or 70. Differential pumping system 40 suitably provides the ion beam, while gas filtration system 50 supplies a stream of filtered gas to fill the target chamber. Additionally, in the case of isotope generation, a vacuum feedthrough (not shown) may be mounted to target chamber 60 or 70 to allow the isotope extraction system 90 to be connected to the outside.
Isotope extraction system 90, including the isotope generation system 63, may be any number of configurations to provide parent compounds or materials and remove isotopes generated inside or proximate the target chamber. For example, isotope generation system 63 may include an activation tube 64 (
In another construction, shown in
The isotopes 18F and 13N, which are utilized in PET scans, may be generated from the nuclear reactions inside each fusion portion using an arrangement as illustrated in
While a tubular spiral has been described, there are many other geometries that could be used to produce the same or other radionuclides. For example, isotope generation system 63 may suitably be parallel loops or flat panel with ribs. In another embodiment, a water jacket may be attached to the vacuum chamber wall. For 18F or 13N creation, the spiral could be replaced by any number of thin walled geometries including thin windows, or could be replaced by a solid substance that contained a high oxygen concentration, and would be removed and processed after transmutation. Other isotopes can be generated by other means.
With reference to
In the embodiment of linear target chamber 70, the ion beam continues in an approximately straight line and impacts the high density target gas to create nuclear reactions until it stops.
In the embodiment of magnetic target chamber 60, the ion beam is bent into an approximately helical path, with the radius of the orbit (for deuterium ions, 2H) given by the equation (2):
where r is the orbital radius in cm, Ti is the ion energy in eV, and B is the magnetic field strength in gauss. For the case of a 500 keV deuterium beam and a magnetic field strength of 5 kG, the orbital radius is about 20.4 cm and suitably fits inside a 25 cm radius chamber. While ion neutralization can occur, the rate at which re-ionization occurs is much faster, and the particle will spend the vast majority of its time as an ion.
Once trapped in this magnetic field, the ions orbit until the ion beam stops, achieving a very long path length in a short chamber. Due to this increased path length relative to linear target chamber 70, magnetic target chamber 60 can also operate at lower pressure. Magnetic target chamber 60, thus, may be the more suitable configuration. A magnetic target chamber can be smaller than a linear target chamber and still maintain a long path length, because the beam may recirculate many times within the same space. The fusion products may be more concentrated in the smaller chamber. As explained, a magnetic target chamber may operate at lower pressure than a linear chamber, easing the burden on the pumping system because the longer path length may give the same total number of collisions with a lower pressure gas as with a short path length and a higher pressure gas of the linac chamber.
Due to the pressure gradient between accelerator 30 and target chamber 60 or 70, gas may flow out of the target chamber and into differential pumping system 40. Vacuum pumps 17 may remove this gas quickly, achieving a pressure reduction of approximately 10 to 100 times or greater. This “leaked” gas is then filtered and recycled via gas filtration system 50 and pumped back into the target chamber, providing more efficient operation. Alternatively, high speed pump 100 may be oriented such that flow is in the direction back into the target chamber, preventing gas from flowing out of the target chamber.
While the invention described herein is directed to a hybrid reactor, it is possible to produce certain isotopes using the fusion portion alone. If this is desired, an isotope extraction system 90 as described herein is inserted into target chamber 60 or 70. This device allows the high energy protons to interact with the parent nuclide of the desired isotope. For the case of 18F production or 13N production, this target may be water-based (16O for 13N, and 18O for 18F) and will flow through thin-walled tubing. The wall thickness is thin enough that the 14.7 MeV protons generated from the fusion reactions will pass through them without losing substantial energy, allowing them to transmute the parent isotope to the desired daughter isotope. The 13N or 18F rich water then is filtered and cooled via external system. Other isotopes, such as 124I (from 124Te or others), 11C (from 14N or 11B or others), 15O (from 15N or others), and 63Zn, may also be generated. In constructions that employ the fission portion to generate the desired isotopes, the isotope extraction system 90 can be omitted.
If the desired product is protons for some other purpose, target chamber 60 or 70 may be connected to another apparatus to provide high energy protons to these applications. For example, the a fusion portion may be used as an ion source for proton therapy, wherein a beam of protons is accelerated and used to irradiate cancer cells.
If the desired product is neutrons, no hardware such as isotope extraction system 90 is required, as the neutrons may penetrate the walls of the vacuum system with little attenuation. For neutron production, the fuel in the injector is changed to either deuterium or tritium, with the target material changed to either tritium or deuterium, respectively. Neutron yields of up to about 1015 neutrons/sec or more may be generated. Additionally, getter trap 13 may be removed. The parent isotope compound may be mounted around target chamber 60 or 70, and the released neutrons may convert the parent isotope compound to the desired daughter isotope compound. Alternatively, an isotope extraction system may still or additionally be used inside or proximal to the target chamber. A moderator (not shown) that slows neutrons may be used to increase the efficiency of neutron interaction. Moderators in neutronics terms may be any material or materials that slow down neutrons. Suitable moderators may be made of materials with low atomic mass that are unlikely to absorb thermal neutrons. For example, to generate 99Mo from a 98Mo parent compound, a water moderator may be used. 99Mo decays to 99mTc, which may be used for medical imaging procedures. Other isotopes, such as 131I, 133Xe, 111In, and 125I, may also be generated. When used as a neutron source, the fusion portion may include shielding such as concrete or a fluid such as water at least one foot thick to protect the operators from radiation. Alternatively, the neutron source may be stored underground to protect the operators from radiation. The manner of usage and operation of the invention in the neutron mode is the same as practiced in the above description.
The fusion rate of the beam impacting a thick target gas can be calculated. The incremental fusion rate for the ion beam impacting a thick target gas is given by the equation (3):
where df(E) is the fusion rate (reactions/sec) in the differential energy interval dE, nb is the target gas density (particles/m3), Iion is the ion current (A), e is the fundamental charge of 1.6022*10−19 coulombs/particle, σ(E) is the energy dependent cross section (m2) and dl is the incremental path length at which the particle energy is E. Since the particle is slowing down once inside the target, the particle is only at energy E over an infinitesimal path length.
To calculate the total fusion rate from a beam stopping in a gas, equation (2) is integrated over the entire particle path length from where its energy is at its maximum of Ei to where it stops as shown in equation (4):
where F(Ei) is the total fusion rate for a beam of initial energy Ei stopping in the gas target. To solve this equation, the incremental path length dl is solved for in terms of energy. This relationship is determined by the stopping power of the gas, which is an experimentally measured function, and can be fit by various types of functions. Since these fits and fits of the fusion cross section tend to be somewhat complicated, these integrals were solved numerically. Data for the stopping of deuterium in 3He gas at 10 torr and 25° C. was obtained from the computer program Stopping and Range of Ions in Matter (SRIM; James Ziegler, www.srim.org) and is shown in
An equation was used to predict intermediate values. A polynomial of order ten was fit to the data shown in
As can be seen from these data, the fit was quite accurate over the energy range being considered. This relationship allowed the incremental path length, dl, to be related to an incremental energy interval by the polynomial tabulated above. To numerically solve this, it is suitable to choose either a constant length step or a constant energy step, and calculate either how much energy the particle has lost or how far it has gone in that step. Since the fusion rate in equation (4) is in terms of dl, a constant length step was the method used. The recursive relationship for the particle energy E as it travels through the target is the equation (5):
En+1=En−S(E)*dl (5)
where n is the current step (n=0 is the initial step, and Eo is the initial particle energy), En+1 is the energy in the next incremental step, S(E) is the polynomial shown above that relates the particle energy to the stopping power, and dl is the size of an incremental step. For the form of the incremental energy shown above, E is in keV and dl is in μm.
This formula yields a way to determine the particle energy as it moves through the plasma, and this is important because it facilitates evaluation of the fusion cross section at each energy, and allows for the calculation of a fusion rate in any incremental step. The fusion rate in the numerical case for each step is given by the equation (6):
To calculate the total fusion rate, this equation was summed over all values of En until E=0 (or n*dl=the range of the particle) as shown in equation (7):
This fusion rate is known as the “thick-target yield”. To solve this, an initial energy was determined and a small step size dl chosen. The fusion rate in the interval dl at full energy was calculated. Then the energy for the next step was calculated, and the process repeated. This goes on until the particle stops in the gas.
For the case of a singly ionized deuterium beam impacting a 10 torr helium-3 gas background at room temperature, at an energy of 500 keV and an intensity of 100 mA, the fusion rate was calculated to be approximately 2×1013 fusions/second, generating the same number of high energy protons (equivalent to 3 μA protons). This level is sufficient for the production of medical isotopes, as is known by those of skill in the art. A plot showing the fusion rate for a 100 mA incident deuterium beam impacting a helium-3 target at 10 torr is shown in
The fusion portions as described herein may be used in a variety of different applications. According to one construction, the fusion portions are used as a proton source to transmutate materials including nuclear waste and fissile material. The fusion portions may also be used to embed materials with protons to enhance physical properties. For example, the fusion portion may be used for the coloration of gemstones. The fusion portions also provide a neutron source that may be used for neutron radiography. As a neutron source, the fusion portions may be used to detect nuclear weapons. For example, as a neutron source the fusion portions may be used to detect special nuclear materials, which are materials that can be used to create nuclear explosions, such as Pu, 233U, and materials enriched with 233U or 235U. As a neutron source, the fusion portions may be used to detect underground features including but not limited to tunnels, oil wells, and underground isotopic features by creating neutron pulses and measuring the reflection and/or refraction of neutrons from materials. The fusion portions may be used as a neutron source in neutron activation analysis (NAA), which may determine the elemental composition of materials. For example, NAA may be used to detect trace elements in the picogram range. As a neutron source, the fusion portions may also be used to detect materials including but not limited to clandestine materials, explosives, drugs, and biological agents by determining the atomic composition of the material. The fusion portions may also be used as a driver for a sub-critical reactor.
The operation and use of the fusion portion 10, 11 is further exemplified by the following examples, which should not be construed by way of limiting the scope of the invention.
The fusion portions 10, 11 can be arranged in the magnetic configuration 10 to function as a neutron source. In this arrangement, initially, the system 10 will be clean and empty, containing a vacuum of 10−9 torr or lower, and the high speed pumps 17 will be up to speed (two stages with each stage being a turbomolecular pump). Approximately 25-30 standard cubic centimeters of gas (deuterium for producing neutrons) will be flowed into the target chamber 60 to create the target gas. Once the target gas has been established, that is, once the specified volume of gas has been flowed into the system and the pressure in the target chamber 60 reaches approximately 0.5 torr, a valve will be opened which allows a flow of 0.5 to 1 sccm (standard cubic centimeters per minute) of deuterium from the target chamber 60 into the ion source 20. This gas will re-circulate rapidly through the system, producing approximately the following pressures: in the ion source 20 the pressure will be a few mtorr; in the accelerator 30 the pressure will be around 20 μtorr; over the pumping stage nearest the accelerator, the pressure will be <20 μtorr; over the pumping stage nearest the target chamber, the pressure will be approximately 50 mtorr; and in the target chamber 60 the pressure will be approximately 0.5 torr. After these conditions are established, the ion source 20 (using deuterium) will be excited by enabling the RF power supply (coupled to the RF antenna 24 by the RF matching circuit) to about 10-30 MHz. The power level will be increased from zero to about 500 W creating a dense deuterium plasma with a density on the order of 1011 particles/cm3. The ion extraction voltage will be increased to provide the desired ion current (approximately 10 mA) and focusing. The accelerator voltage will then be increased to 300 kV, causing the ion beam to accelerate through the flow restrictions and into the target chamber 60. The target chamber 60 will be filled with a magnetic field of approximately 5000 gauss (or 0.5 tesla), which causes the ion beam to re-circulate. The ion beam will make approximately 10 revolutions before dropping to a negligibly low energy.
While re-circulating, the ion beam will create nuclear reactions with the target gas, producing 4×1010 and up to 9×1010 neutrons/sec for D. These neutrons will penetrate the target chamber 60, and be detected with appropriate nuclear instrumentation.
Neutral gas that leaks from the target chamber 60 into the differential pumping section 40 will pass through the high speed pumps 17, through a cold trap 13, 15, and back into the target chamber 60. The cold traps 13, 15 will remove heavier gasses that in time can contaminate the system due to very small leaks.
The fusion portions 11 can also be arranged in the linear configuration to function as a neutron source. In this arrangement, initially, the system will be clean and empty, containing a vacuum of 10−9 torr or lower and the high speed pumps 17 will be up to speed (three stages, with the two nearest that accelerator being turbomolecular pumps and the third being a different pump such as a roots blower). Approximately 1000 standard cubic centimeters of deuterium gas will be flowed into the target chamber 70 to create the target gas. Once the target gas has been established, a valve will be opened which allows a flow of 0.5 to 1 sccm (standard cubic centimeters per minute) from the target chamber 70 into the ion source 20. This gas will re-circulate rapidly through the system, producing approximately the following pressures: in the ion source 20 the pressure will be a few mtorr; in the accelerator 30 the pressure will be around 20 μtorr; over the pumping stage nearest the accelerator, the pressure will be <20 μtorr; over the center pumping stage the pressure will be approximately 50 mtorr; over the pumping stage nearest the target chamber 70, the pressure will be approximately 500 mtorr; and in the target chamber 70 the pressure will be approximately 20 torr.
After these conditions are established, the ion source 20 (using deuterium) will be excited by enabling the RF power supply (coupled to the RF antenna 24 by the RF matching circuit) to about 10-30 MHz. The power level will be increased from zero to about 500 W creating a dense deuterium plasma with a density on the order of 1011 particles/cm3. The ion extraction voltage will be increased to provide the desired ion current (approximately 10 mA) and focusing. The accelerator voltage will then be increased to 300 kV, causing the ion beam to accelerate through the flow restrictions and into the target chamber 70. The target chamber 70 will be a linear vacuum chamber in which the beam will travel approximately 1 meter before dropping to a negligibly low energy.
While passing through the target gas, the beam will create nuclear reactions, producing 4×1010 and up to 9×1010 neutrons/sec. These neutrons will penetrate the target chamber 70, and be detected with appropriate nuclear instrumentation.
Neutral gas that leaks from the target chamber 70 into the differential pumping section 40 will pass through the high speed pumps 17, through a cold trap 13, 15, and back into the target chamber 70. The cold traps 13, 15 will remove heavier gasses that in time can contaminate the system due to very small leaks.
In another construction, the fusion portions 10 are arranged in the magnetic configuration and are operable as proton sources. In this construction, initially, the system will be clean and empty, containing a vacuum of 10−9 torr or lower, and the high speed pumps 17 will be up to speed (two stages with each stage being a turbomolecular pump). Approximately 25-30 standard cubic centimeters of gas (an approximate 50/50 mixture of deuterium and helium-3 to generate protons) will be flowed into the target chamber 60 to create the target gas. Once the target gas has been established, that is, once the specified volume of gas has been flowed into the system and the pressure in the target chamber 60 reaches approximately 0.5 torr, a valve will be opened which allows a flow of 0.5 to 1 sccm (standard cubic centimeters per minute) of deuterium from the target chamber 60 into the ion source 20. This gas will re-circulate rapidly through the system, producing approximately the following pressures: in the ion source 20 the pressure will be a few mtorr; in the accelerator 30 the pressure will be around 20 μtorr; over the pumping stage nearest the accelerator 30, the pressure will be <20 μtorr; over the pumping stage nearest the target chamber 60, the pressure will be approximately 50 mtorr; and in the target chamber 60 the pressure will be approximately 0.5 torr. After these conditions are established, the ion source 20 (using deuterium) will be excited by enabling the RF power supply (coupled to the RF antenna 24 by the RF matching circuit) to about 10-30 MHz. The power level will be increased from zero to about 500 W creating a dense deuterium plasma with a density on the order of 1011 particles/cm3. The ion extraction voltage will be increased to provide the desired ion current (approximately 10 mA) and focusing. The accelerator voltage will then be increased to 300 kV, causing the ion beam to accelerate through the flow restrictions and into the target chamber 60. The target chamber 60 will be filled with a magnetic field of approximately 5000 gauss (or 0.5 tesla), which causes the ion beam to re-circulate. The ion beam will make approximately 10 revolutions before dropping to a negligibly low energy.
While re-circulating, the ion beam will create nuclear reactions with the target gas, producing 1×1011 and up to about 5×1011 protons/sec. These protons will penetrate the tubes of the isotope extraction system, and be detected with appropriate nuclear instrumentation.
Neutral gas that leaks from the target chamber 60 into the differential pumping section 40 will pass through the high speed pumps 17, through a cold trap 13, 15, and back into the target chamber 60. The cold traps 13, 15 will remove heavier gasses that in time can contaminate the system due to very small leaks.
In another construction, the fusion portions 11 are arranged in the linear configuration and are operable as proton sources. In this construction, initially, the system will be clean and empty, containing a vacuum of 10−9 torr or lower and the high speed pumps 17 will be up to speed (three stages, with the two nearest that accelerator being turbomolecular pumps and the third being a different pump such as a roots blower). Approximately 1000 standard cubic centimeters of about 50/50 mixture of deuterium and helium-3 gas will be flowed into the target chamber 70 to create the target gas. Once the target gas has been established, a valve will be opened which allows a flow of 0.5 to 1 sccm (standard cubic centimeters per minute) from the target chamber 70 into the ion source 20. This gas will re-circulate rapidly through the system, producing approximately the following pressures: in the ion source 20 the pressure will be a few mtorr; in the accelerator 30 the pressure will be around 20 μtorr; over the pumping stage nearest the accelerator 30, the pressure will be <20 μtorr; over the center pumping stage the pressure will be approximately 50 mtorr; over the pumping stage nearest the target chamber 70, the pressure will be approximately 500 mtorr; and in the target chamber 70 the pressure will be approximately 20 torr.
After these conditions are established, the ion source 20 (using deuterium) will be excited by enabling the RF power supply (coupled to the RF antenna 24 by the RF matching circuit) to about 10-30 MHz. The power level will be increased from zero to about 500 W creating a dense deuterium plasma with a density on the order of 1011 particles/cm3. The ion extraction voltage will be increased to provide the desired ion current (approximately 10 mA) and focusing. The accelerator voltage will then be increased to 300 kV, causing the ion beam to accelerate through the flow restrictions and into the target chamber 70. The target chamber 70 will be a linear vacuum chamber in which the beam will travel approximately 1 meter before dropping to a negligibly low energy.
While passing through the target gas, the beam will create nuclear reactions, producing 1×1011 and up to about 5×1011 protons/sec. These neutrons will penetrate the walls of the tubes of the isotope extraction system, and be detected with appropriate nuclear instrumentation.
Neutral gas that leaks from the target chamber 70 into the differential pumping section 40 will pass through the high speed pumps 17, through a cold trap 13, 15, and back into the target chamber 70. The cold traps 13, 15 will remove heavier gasses that in time can contaminate the system due to very small leaks.
In another construction, the fusion portions 10, 11 are arranged in either the magnetic configuration or the linear configuration and are operated as neutron sources for isotope production. The system will be operated as discussed above with the magnetic target chamber or with the linear target chamber 70. A solid sample, such as solid foil of parent material 98Mo will be placed proximal to the target chamber 60, 70. Neutrons created in the target chamber 60, 70 will penetrate the walls of the target chamber 60, 70 and react with the 98Mo parent material to create 99Mo, which may decay to meta-stable 99Tn. The 99Mo will be detected using suitable instrumentation and technology known in the art.
In still other constructions, the fusion portions 10, 11 are arranged as proton sources for the production of isotopes. In these construction, the fusion portion 10, 11 will be operated as described above with the magnetic target chamber 60 or with the linear target chamber 70. The system will include an isotope extraction system inside the target chamber 60, 70. Parent material such as water comprising H216O will be flowed through the isotope extraction system. The protons generated in the target chamber will penetrate the walls of the isotope extraction system to react with the 16O to produce 13N. The 13N product material will be extracted from the parent and other material using an ion exchange resin. The 13N will be detected using suitable instrumentation and technology known in the art.
In summary, each fusion portion 10, 11 provides, among other things, a compact high energy proton or neutron source. The foregoing description is considered as illustrative only of the principles of the fusion portion 10, 11. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the fusion portion 10, 11 to the exact construction and operation shown and described, and accordingly, all suitable modifications and equivalents may be resorted to as required or desired.
As illustrated in
With reference to
Each fusion portion 10, 11 is arranged to emit high energy neutrons from the target chamber. The neutrons emitted by the fusion portions 10, 11 are emitted isotropically, and while at high energy those that enter the activation column 410 pass through it with little interaction. The target chamber is surrounded by 10-15 cm of beryllium 420, which multiplies the fast neutron flux by approximately a factor of two. The neutrons then pass into the moderator where they slow to thermal energy and reflect back into the activation cell 410.
It is estimated that the flux from this configuration is about 1015 n/s (the estimated source strength for a single fusion portion 10, 11 operating at 500 kV and 100 mA is 1014 n/s and there are ten of these devices in the illustrated construction). The total volumetric flux in the activation cell 410 was calculated to be 2.35*1012 n/cm2/s with an uncertainty of 0.0094 and the thermal flux (less than 0.1 eV) was 1.34*1012 n/cm2/s with an uncertainty of 0.0122. This neutron rate improves substantially with the presence of LEU as will be discussed.
As discussed with regard to
The primary simplification in the linear configuration is the elimination of the components needed to establish the magnetic field that guides the beam in the spiral or helical pattern. The lack of the components needed to create the field makes the device cheaper and the magnets do not play a role in attenuating the neutron flux. However, in some constructions, a magnetic field is employed to collimate the ion beam produced by the linear arrangement of the fusion portions 11, as will be discussed.
In order to produce 99Mo of high specific activity as an end product, it should be made from a material that is chemically different so that it can be easily separated. The most common way to do this is by fission of 235U through neutron bombardment. The fusion portions 10, 11 described previously create sufficient neutrons to produce a large amount of 99Mo with no additional reactivity, but if 235U is already present in the device, it makes sense to put it in a configuration that will provide neutron multiplication as well as providing a target for 99Mo production. The neutrons made from fission can play an important role in increasing the specific activity of the 99Mo, and can increase the total 99Mo output of the system. The multiplication factor, keff is related to the multiplication by equation 1/(1−keff). This multiplication effect can result in an increase of the total yield and specific activity of the end product by as much as a factor of 5-10. keff is a strong function of LEU density and moderator configuration.
Several subcritical configurations of subcritical assemblies 435 which consist of LEU (20% enriched) targets combined with H2O (or D2O) are possible. All of these configurations are inserted into the previously described reaction chamber space 405. Some of the configurations considered include LEU foils, an aqueous solution of a uranium salt dissolved in water, encapsulated UO2 powder and others. The aqueous solutions are highly desirable due to excellent moderation of the neutrons, but provide challenges from a criticality perspective. In order to ensure subcritical operation, the criticality constant, keff should be kept below 0.95. Further control features could easily be added to decrease keff if a critical condition were obtained. These control features include, but are not limited to control rods, injectable poisons, or pressure relief valves that would dump the moderator and drop the criticality.
Aqueous solutions of uranium offer tremendous benefits for downstream chemical processes. Furthermore, they are easy to cool, and provide an excellent combination of fuel and moderator. Initial studies were performed using a uranium nitrate solution-UO2(NO3)2, but other solutions could be considered such as uranium sulfate or others. In one construction, the salt concentration in the solution is about 66 g of salt per 100 g H2O. The solution is positioned within the activation cell 410 as illustrated in
In the aqueous solution layout illustrated in
A common method to irradiate uranium is to form it into either uranium dioxide pellets or encase a uranium dioxide powder in a container. These are inserted into a reactor and irradiated before removal and processing. While the UO2 powders being used today utilize HEU, it is preferable to use LEU. In preferred constructions, a mixture of LEU and H2O that provides Keff<0.95 is employed.
In another construction, 99Mo is extracted from uranium by chemical dissolution of LEU foils in a modified Cintichem process. In this process, thin foils containing uranium are placed in a high flux region of a nuclear reactor, irradiated for some time and then removed. The foils are dissolved in various solutions and processed through multiple chemical techniques.
From a safety, non-proliferation, and health perspective, a desirable way to produce 99Mo is by (n,γ) reactions with parent material 98Mo. This results in 99Mo with no contamination from plutonium or other fission products. Production by this method also does not require a constant feed of any form of uranium. The disadvantage lies in the difficulty of separating 99Mo from the parent 98Mo, which leads to low specific activities of 99Mo in the generator. Furthermore, the cost of enriched 98Mo is substantial if that is to be used. Still, considerable progress has been made in developing new elution techniques to extract high purity 99mTc from low specific activity 99Mo, and this may become a cost-effective option in the near future. To implement this type of production in the hybrid reactor 5a, 5b illustrated herein, a fixed subcritical assembly 435 of LEU can be used to increase the neutron flux (most likely UO2), but can be isolated from the parent 98Mo. The subcritical assembly 435 is still located inside of the fusion portion 10, 11, and the 99Mo activation column would be located within the subcritical assembly 435.
In preferred constructions, 98Mo occupies a total of 20% of the activation column 410 (by volume). As illustrated in
For the LEU cases, the production rate and specific activity of 99Mo was determined by calculating 6% of the fission yield, with a fusion portion 10, 11 operating at 1015 n/s. Keff was calculated for various configurations as well. Table 1 summarizes the results of these calculations. In the case of production from 98Mo, an (n,γ) tally was used to determine the production rate of 99Mo. The following table illustrates the production rates for various target configurations in the hybrid reactor 5a, 5b.
While the specific activity of 99Mo generated is relatively constant for all of the subcritical cases, some configurations allow for a substantially higher total production rate. This is because these configurations allow for considerably larger quantities of parent material. It is also worth noting that production of 99Mo from 98Mo is as good a method as production from LEU when it comes to the total quantity of 99Mo produced. Still, the LEU process tends to be more favorable as it is easier to separate 99Mo from fission products than it is to separate it from 98Mo, which allows for a high specific activity of 99Mo to be available after separation.
In constructions in which 98Mo is used to produce 99Mo, the subcritical assembly 435 can be removed altogether. However, if the subcritical assembly 435 is removed, the specific activity of the end product will be quite a bit lower. Still, there are some indications that advanced generators might be able to make use of the low specific activity resulting from 98Mo irradiation. The specific activity produced by the hybrid reactor 5a, 5b without subcritical multiplication is high enough for some of these technologies. Furthermore, the total demand for U.S. 99Mo could still be met with several production facilities, which would allow for a fission free process.
For example, in one construction of a fusion only reactor, the subcritical assembly 435 is omitted and 98Mo is positioned within the activation column 410. To enhance the production of 99Mo, a more powerful ion beam produced by the linear arrangement of the fusion portion 11 is employed. It is preferred to operate the ion beams at a power level approximately ten times that required in the aforementioned constructions. To achieve this, a magnetic field is established to collimate the beam and inhibit the undesirable dispersion of the beams. The field is arranged such that it is parallel to the beams and substantially surrounds the accelerator 30 and the pumping system 40 but does not necessarily extend into the target chamber 70. Using this arrangement provides the desired neutron flux without the multiplicative effect produced by the subcritical assembly 435. One advantage of this arrangement is that no uranium is required to produce the desired isotopes.
Thus, the invention provides, among other things, a new and useful hybrid reactor 5a, 5b for use in producing medical isotopes. The constructions of the hybrid reactor 5a, 5b described above and illustrated in the figures are presented by way of example only and are not intended as a limitation upon the concepts and principles of the invention. Various features and advantages of the invention are set forth in the following claims.
Claims
1. A hybrid reactor comprising:
- an ion source operable to produce an ion beam from a gas;
- an accelerator operatively coupled to the ion source to define an accelerator/ion source region, wherein the accelerator is configured to receive the ion beam and accelerate the ion beam to yield an accelerated ion beam;
- a target chamber comprising a target that interacts with the ion beam to produce neutrons;
- a pumping system fluidly coupled to the target chamber and the accelerator/ion source region; and
- an activation cell positioned proximate the target chamber and including a parent material that interacts with the neutrons to produce a medical isotope via a fission reaction.
2. The hybrid reactor of claim 1, wherein the target chamber defines a higher gas pressure region and the accelerator/ion source region defines a lower gas pressure region.
3. The hybrid reactor of claim 2, wherein the target chamber is operatively coupled to the accelerator, the higher gas pressure region of the target chamber operating at a gas pressure within a range of 1 to 100 torr and the lower gas pressure region of the accelerator/ion source region operating at a gas pressure lower than the gas pressure of the higher gas pressure region.
4. The hybrid reactor of claim 2, wherein the target chamber is substantially open to the accelerator/ion source region with no physical barrier preventing a flow of gas molecules from the higher gas pressure region of the target chamber to the lower gas pressure region of the accelerator.
5. The hybrid reactor of claim 1, wherein the pumping system comprises a synchronized high-speed pump.
6. The hybrid reactor of claim 1, wherein the pumping system comprises a differential pumping system.
7. The hybrid reactor of claim 6, wherein the differential pumping system is configured to maintain a first pressure differential between an outside atmosphere and the accelerator/ion source region, a second pressure differential between the outside atmosphere and the target chamber, and a third pressure differential between the accelerator/ion source region and the target chamber.
8. The hybrid reactor of claim 6, wherein the differential pumping system comprises:
- a first end operatively coupled to the accelerator/ion source region and a second end operatively coupled to the target chamber;
- at least one vacuum chamber coupling the first end to the second end and allowing passage of the ion beam from the first end to the second end of the differential pumping system; and
- a vacuum pump connected to the at least one vacuum chamber.
9. The hybrid reactor of claim 6, wherein the differential pumping system comprises a turbulence generating apparatus.
10. A hybrid reactor comprising:
- an ion source operable to produce an ion beam from a gas;
- an accelerator operatively coupled to the ion source to define an accelerator/ion source region, wherein the accelerator is configured to receive the ion beam and accelerate the ion beam to yield an accelerated ion beam;
- a target chamber comprising a target that interacts with the ion beam to produce neutrons;
- a plasma window positioned between the target chamber and the accelerator/ion source region; and
- an activation cell positioned proximate the target chamber and including a parent material that interacts with the neutrons to produce a medical isotope via a fission reaction.
11. The hybrid reactor of claim 10, wherein the plasma window is configured to form a plasma between the target chamber and the accelerator/ion source region.
12. The hybrid reactor of claim 11, wherein the plasma is configured to reduce the flow of gas between the target chamber and the accelerator/ion source region and allow passage of the ion beam from the accelerator/ion source region to the target chamber.
13. The hybrid reactor of claim 11, wherein the plasma is configured to inhibit the flow of gas between the target chamber and the accelerator/ion source region and allow passage of the ion beam from the accelerator/ion source region to the target chamber.
14. The hybrid reactor of claim 11, wherein the target chamber defines a higher gas pressure region and the accelerator/ion source region defines a lower gas pressure region.
15. The hybrid reactor of claim 10, further comprising a differential pumping system fluidly coupled to one or both of the target chamber and the accelerator/ion source region, wherein the differential pumping system is configured to maintain a first pressure differential between an outside atmosphere and the accelerator/ion source region and a second pressure differential between the outside atmosphere and the target chamber.
16. The hybrid reactor of claim 15, wherein the differential pumping system comprises:
- a first end operatively coupled to the accelerator/ion source region and a second end operatively coupled to the target chamber;
- at least one vacuum chamber coupling the first end to the second end and allowing passage of the ion beam from the first end to the second end of the differential pumping system; and
- a vacuum pump connected to the at least one vacuum chamber.
17. The hybrid reactor of claim 15, wherein the plasma window is positioned to form a plasma within the differential pumping system and between the target chamber and the accelerator/ion source region.
18. A hybrid reactor comprising:
- an ion source operable to produce an ion beam from a gas;
- an accelerator operatively coupled to the ion source to define an accelerator/ion source region, wherein the accelerator is configured to receive the ion beam and accelerate the ion beam to yield an accelerated ion beam;
- a target chamber including a target that interacts with the ion beam to produce neutrons; and
- a plasma window positioned between the target chamber and the accelerator/ion source region.
19. The hybrid reactor of claim 18, wherein:
- the target chamber defines a higher gas pressure region and the accelerator/ion source region defines a lower gas pressure region; and
- the plasma window is configured to form a plasma between the target chamber and the accelerator/ion source region to reduce the flow of gas between the target chamber and the accelerator/ion source region and allow passage of the ion beam from the accelerator/ion source region to the target chamber.
20. The hybrid reactor of claim 19, wherein the plasma inhibits the flow of gas between the target chamber and the accelerator/ion source region and allow passage of the ion beam from the accelerator/ion source region to the target chamber.
Type: Application
Filed: Apr 15, 2022
Publication Date: Aug 25, 2022
Inventor: Gregory Piefer (Janesville, WI)
Application Number: 17/722,164