Next Article in Journal / Special Issue
Introduction of the New Center for Radiopharmaceutical Cancer Research at Helmholtz-Zentrum Dresden-Rossendorf
Previous Article in Journal / Special Issue
New Cross-Sections for natMo(α,x) Reactions and Medical 97Ru Production Estimations with Radionuclide Yield Calculator
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Boron Nitride Nanotube Cyclotron Targets for Recoil Escape Production of Carbon-11

1
BTI Targetry LLC, 1939 Evans Road, Cary, NC 27513, USA
2
National Institute of Aerospace, 100 Exploration Way, Hampton, VA 23666, USA
3
Lawrence Berkeley National Laboratory, 1 Cyclotron Road, Berkeley, CA 94720, USA
*
Author to whom correspondence should be addressed.
Instruments 2019, 3(1), 8; https://doi.org/10.3390/instruments3010008
Submission received: 19 December 2018 / Revised: 21 January 2019 / Accepted: 24 January 2019 / Published: 27 January 2019
(This article belongs to the Special Issue Instruments and Methods for Cyclotron Produced Radioisotopes)

Abstract

:
Boron nitride nanotubes (BNNTs) were investigated as a target media for cyclotron production of 11C for incident beam energy at or below 11 MeV. Both the 11B(p,n)11C and 14N(p,α)11C nuclear reactions were utilized. A sweep gas of nitrogen or helium was used to collect recoil escape atoms with a desired form of 11CO2. Three prototype targets were tested using an RDS-111 cyclotron. Target geometry and density were shown to impact the saturation yield of 11C and percent of yield recovered as carbon dioxide. Physical damage to the BNNT target media was observed at beam currents above 5 μA. Additional studies are needed to identify operating conditions suitable for commercial application of the method.

1. Introduction

Boron nitride nanotube (BNNT) nanomaterials [1,2,3,4,5] can be used in a recoil escape target to produce 11C for incident proton energy at or below 11 MeV. This would enable 11C production for economical low-energy cyclotrons [6,7,8,9], and it could be used to increase production from conventional 11C gas targets on MiniTrace and RDS-111 cyclotrons. Preliminary experiments have demonstrated recoil escape production and recovery of small quantities of 11CO2, and there has been a continued effort to develop a target design and platform that can be used to produce viable yields for a commercial system.
Conventional gas targets for 11C production operate by proton bombardment of nitrogen gas [10,11,12,13]. However, due to the low nuclear cross-section of the 14N(p,α)11C nuclear reaction below 11 MeV, this production method is not commercially viable for accelerators with proton energy in the range of 7–10 MeV. Adding BNNT nanomaterials to the target allows for an additional production route via the 11B(p,n)11C nuclear reaction, which has a higher cross-section at all proton energies, as shown in Figure 1 [14,15]. If the produced 11C can be effectively recovered from the target, the total yield of 11C will be greater than currently achievable using a conventional gas target.
The nanotube geometry should offer superior recovery of 11C recoil atoms to boron powder, due to the smaller mean particle size (nm versus μm) and higher porosity. Nearly complete recoil escape should be possible, because the walls of individual BNNT fibrils are single atomic thickness or at most a few atoms thick. The high porosity of the bulk material should allow sufficient gas flow to facilitate the slowing of recoil ions to thermal energies and their combination with trace oxygen in the sweep gas.

2. Materials and Methods

Both natural-abundance boron (19.9% 10B and 80.1% 11B) and enriched boron-11 (>98% 11B) BNNT nanomaterials are commercially available [16]. The bulk material is highly porous, allowing for diffusion of gas, and the nanotube dimensions are compatible with the recoil escape of 11C. In addition to the nanotubes, impurities of elemental boron and hexagonal boron nitride (h-BN) are present. Recovery of 11C is assumed to be strongly correlated to the impurity content, since larger structures could trap recoiling atoms and prevent recovery in the sweep gas. The BNNT material is supplied at a low density of roughly 1.38 g/cm3 [17]. It undergoes plastic deformation with light pressure and sticks to surfaces both mechanically and due to electrostatic attraction. As a result, loading a target at uniform density is challenging. A photograph of the bulk BNNT material is shown in Figure 2, and individual nanotubes and nontube impurities, such as boron and h-BN particles, can be seen in the scanning electron microscope (SEM) images shown in Figure 3.
Three prototype targets were tested at the RDS-111 cyclotron at Lawrence Berkeley National Laboratory (LBNL) using commercially available BNNT nanomaterials from supplier BNNT, LLC [16]. Preliminary work was performed using BNNT nanomaterials with natural-abundance boron and a target for the Eclipse target changer. The target, shown in Figure 4, features an aluminum target body with a cylindrical target chamber 1.0 cm in diameter by 1.0 cm in length. A window foil of either 25 μm of Havar or 30 μm of aluminum is used to result in a mean incident energy on the BNNT target media of 10.5 MeV or 8.1 MeV, respectively. Annular space between the target and changer creates a flow path for water cooling. Two 1-mm diameter passages, which intercept the target chamber front and rear, allow sweep gas to pass into the target through the BNNT material and out of the target into a delivery line during or after the irradiation process.
Using the initial prototype, sufficient quantities of 11C were produced and recovered using a range of operating conditions to demonstrate the feasibility of using BNNT as a target material, and more than 80% of the recovered 11C was in the desired form of CO2. The principle technical challenge was identified to be minimizing damage to the BNNT target media that occurred during target operation at a high current. Irradiation at 20 μA with 10.5-MeV incident protons resulted in a dramatic reduction in 11C saturation yield and physical damage to the BNNT material, including the formation of a cavity in the center of the target chamber with translucent glassy crystals along its margins, as shown in Figure 5. The crystalline material was presumed to be boron oxide (B2O3).
Two additional prototype targets with larger chamber volumes were developed for the single target station. The aluminum target bodies feature cylindrical target chambers with dimensions of 1.1 cm in diameter by 6.0 cm in length (BN-124 target) and 1.1 cm in diameter by 1.5 cm in length (BN-131 target), with four 6.1-mm in diameter water cooling channels. Helium-cooled Havar vacuum and target windows (25 μm and 38 μm, respectively) resulted in a mean incident energy on the BNNT media of 9.5 MeV. The BN-124 and BN-131 targets are shown in Figure 6 and Figure 7.
A custom BTI Targetry target station, shown in Figure 8, was used, consisting of a beam tube, a vacuum isolation valve, a collimator with an 8-mm diameter opening, and target mounting geometry. Because the BN-124 prototype target is considerably longer axially than the prior prototype or commercial 18F targets, the target–collimator interface is subjected to a greater bending moment while supporting the weight of the target. A pressed stainless steel pin on the vertical mid-plane was added to provide additional mechanical support for this application.
A diagram of the experimental setup is shown in Figure 9. The target chamber was filled with BNNT and pressurized by opening the target isolation valve and delivering gas through a flow control valve. For static mode irradiations, the target load valve was closed, and the target was irradiated at a fixed current. After irradiation, the target unload valve was opened, and the target was allowed to depressurize, followed by opening the load valve to sweep gas through the target chamber and remove volatile radioisotopes. For continuous flow mode irradiations, both the load and unload valves were opened with a gas sweep rate established by the flow control valve, and gas was swept through the target chamber throughout the irradiation. In all cases, the same gas was used to both fill the target and for the sweep to remove volatile radioisotopes. Experiments were performed using a fill gas of nitrogen or helium with 1%–10% oxygen.
For both static and continuous flow operation, the target gas was delivered through 10 m of 0.5-mm inside diameter tubing (valve E to trap G in Figure 9) to a hot cell in the laboratory. Once inside the hot cell, the gas was swept through a 11CO2 soda lime trapping cartridge, and the untrapped radiolabeled gases and target gas were collected in a Tedlar gas collection bag. The CO and CO2 were identified using an SRI 8610C gas chromatograph (GC) equipped with a Restek ShinCarbon ST 80/100 column (P/N 80486-800, 2 m, 2-mm inside diameter, 1/8-in. outside diameter Silicone). The original GC detector setup was a thermal conductivity detector (TCD) followed by a flame ionization detector (FID). A 1/16-in. outside diameter stainless steel line was added in between the two detectors and formed into a 1-in. loop to redirect flow through an NaI gamma detector with outside dimensions roughly 1 in. outside diameter by 4.75 in. high. A Carroll & Ramsey Associate post-amplifier/integrator (model 105-S) was used.
During the collection, the 11CO2 trap was held in a dose calibrator (ionization chamber style well detector) to measure the dynamic buildup and final quantity of 11C trapped as 11CO2 on the cartridge. Subsequently, a 50-mL sample of the volatile gases collected in the sampling bag was analyzed for radioactivity in the dose calibrator, and total activity in the bag was determined by volume ratio between the 50-mL sample and total bag volume. Activities of all samples were measured for a minimum of 5 min and fitted to the known half-lives for 11C and 13N, and the results were decay-corrected to end of bombardment.
The 11C was collected in several modes, depending on the experiment (soda lime trap and collection bag, soda lime trap and waste line, or collection bag only). The soda lime trap was made of Fisher Scientific brand (ACS certified, S-196) soda lime placed inside of a Swagelok 1/2–1/4 in. reducing union (PFA-820-6-4) with an approximate volume of 2–4 mL. The collection bag was a 3-L Tedlar bag (SKC Inc., Cat # 232-03). When a GC sample was to be analyzed, the entire target output was collected into the collection bag, and a 1-mL sample was injected onto the GC. Soda lime trap and collection bag mode was used when the CO2 composition was unknown to determine the percentage of recovered activity in the form of CO2 versus other radioactive products. Soda lime trap and waste line mode was used to determine target yield when the CO2 percentage was known to be high.
The recovered target saturation yield of 11C (Ysat) was calculated by
Y s a t = A E O B I ( 1 e λ t i r r ) ,
using the recovered decay-corrected end-of-bombardment 11C activity (AEOB), the average beam current (I), the 11C decay constant (λ = 0.034045 min−1), and a 5-min irradiation time (tirr). A portion of the produced 11C activity remained trapped in the target media but could not easily be measured.
The BN-124 and BN-131 prototype targets were tested using 98% enriched 11B BNNT (11BNNT) to increase the yield of 11C and reduce the production of 7Be, which has a half-life of 53 days. Additional tests were performed for the BN-131 target using 11BNNT material from a second commercial supplier, BNNano [18].

3. Results

3.1. Beam Tests of the BN-124 Target

Proton beam tests were performed on the single target station using the BN-124 prototype, which had a 6.0-cm depth and a 5.7-cm3 volume, for beam currents between 1 and 10 μA, with static operation at load pressures between 200 and 800 psi using a fill gas of nitrogen with 1% oxygen. The target was loaded with 377 mg of 11BNNT, corresponding to an effective BNNT density of 0.07 g/cm3. A recovered target saturation yield of 11CO2 as a function of beam current and load pressure is shown in Figure 10. More than 95% of the recovered activity was in the desired form of 11CO2, as indicated by soda lime trapping and confirmed by GC measurements. Target saturation yield increased with pressure between 200 and 600 psi, and then began to drop off. Saturation yield was highest at 1 μA, which corresponded to the lowest target heat input.
The BN-124 target was opened and visually inspected following a series of irradiations at each beam current. Following irradiation at 1 μA, the material changed color from gray to off-white, which was attributed to the conversion of elemental B impurities into B2O3. Material shrinkage (volume reduction) of the BNNT target media into the back of the target was observed, with additional shrinkage occurring for higher currents, as summarized in Table 1. After irradiation at 3 μA, the material shrinkage was about 40%, and the color continued to whiten. Following the 8-μA runs, observed changes in the BNNT material included crystallization, gray and black spots, and a white powdery buildup coating the inside walls of the target. Due to the additional material shrinkage, there was a 3.1-cm depth void in the front of the target, which was more than half of the chamber depth.
Photographs of the BN-124 target media post-irradiation at each beam current are shown in Figure 11. It is important to note that shades of gray and white can be very misleading due to variations in the angle of the photograph and lighting conditions.
The void formed in the front of the target during irradiation made interpretation of the data difficult, since most of the recovered yield was likely from the 14N(p,α)11C reaction in the nitrogen gas in the voided region. Increasing the effective density in the BN-124 target to mitigate material shrinkage would have required significantly more 11BNNT material, which was both cost-prohibitive (>$1000/g) and inefficient due to the range of the protons. Accounting for the Havar vacuum and target windows (25 μm and 38 μm, respectively), stopping power calculations indicated only 125 mg of BNNT was needed for the target to be axially range thick for 11-MeV protons.

3.2. Beam Tests of the BN-131 Target

To address these issues, a second prototype target (BN-131) was designed and fabricated for the single target station with a reduced target depth of 1.5 cm, resulting in a volume of 1.4 cm3. The target was loaded with 400 mg of 11BNNT, resulting in an effective BNNT density four times higher than that used for the prior prototype. Proton beam irradiations were performed at 5 μA, for static operation at 200–600 psi load pressure, using both nitrogen gas with 1% oxygen and helium gas with 1% oxygen. Negligible material shrinkage was observed for the BN-131 target following irradiation.
Total saturation yield of 11C in all forms (11CO2 and 11CO) for the BN-131 target irradiations is shown in Figure 12. Since helium does not offer a competing production reaction for 11C, all recovered 11C was produced in BNNT for these irradiations. The total yield of 11C was roughly equivalent for both gases, suggesting minimal production of 11C in the nitrogen fill gas. The fraction of activity recovered in the form of carbon dioxide is shown in Figure 13. Using helium fill gas in the BN-131 target consistently produced less 11C as CO2 (35%–55%) compared to using nitrogen gas in the BN-131 target (50%–55%). For both fill gases, the percentage of activity recovered as carbon dioxide was significantly less than that observed when using nitrogen gas in the BN-124 target (>95%).

3.3. Comparison of 11C Saturation Yield for the BN-124 and BN-131 Targets

Total saturation yield of 11C in all forms (11CO2 and 11CO) for the BN-124 and BN-131 targets is shown in Figure 14. The results were similar for static operation using a fill gas of nitrogen with 1% oxygen at 200 psi. However, the BN-124 target yield increased with nitrogen gas pressure, while the BN-131 target yield was insensitive to nitrogen gas pressure. This supported the assertion that a significant component of yield from the larger target was due to 11C production in the voided region and independent of the nanomaterials.

3.4. BN-124 Gas-Only Target Operation

To provide a better context for evaluating target performance, the BN-124 target was also operated as a gas target using a fill gas of nitrogen with 1% oxygen with no BNNT nanomaterials present. The recovered target saturation yield of 11CO2 for static operation at 200 psi load pressure using 377 mg 11BNNT and for gas-only static operation at 200 psi load pressure is shown in Figure 15. Monte Carlo radiation transport calculations were performed for the target using Monte Carlo N-Particle eXtended (MCNPX) [19]. Although MCNPX simulations using the nuclear cross-section data indicated more 11C was produced when using the 11BNNT, use of the 11BNNT resulted in a lower recovered saturation yield for all cases. This suggested a large amount of activity was being trapped in the target.

3.5. Evaluation of BNNT Nanomaterials from a Second Supplier

Additional BNNT nanomaterials were acquired from a second manufacturer, BNNano [18]. Low-purity material (<90% nanotubes) was selected to prevent the material from becoming too brittle to easily load in the cylindrical target chamber. The material was darker in color, with significantly higher density and more mechanical integrity when manipulated, although it was still susceptible to plastic deformation. Photographs of bulk BNNT material from the two suppliers are shown in Figure 16. A limited set of 11C saturation yield data was collected using the BN-131 target with 11BNNT nanomaterials from BNNano at the RDS-111 cyclotron at LBNL and at a commercial RDS-111 cyclotron operated by Triad Isotopes. The saturation yield data were 1–2 orders of magnitude lower than what was observed in the prior tests using 11BNNT from BNNT, LLC. SEM imaging revealed a much higher concentration of nontube impurities in the material, as shown in Figure 17. This further supported the theory that high-purity material was needed to prevent 11C trapping in targets and achieve a high recovered saturation yield.

4. Discussion

Use of BNNT nanomaterials in a recoil escape target has the potential to increase 11C yield for proton energies at or below 11 MeV by utilizing both the 11B(p,n)11C and 14N(p,α)11C nuclear reactions. However, additional studies are needed to determine operating conditions suitable for a commercial product. Beam irradiation experiments at a low effective BNNT density resulted in material shrinkage, making interpretation of the data difficult. Operating at a higher effective BNNT density prevented material shrinkage, but resulted in a lower saturation yield of 11C and a lower percentage of activity recovered in the desired form of CO2.
Poor recovery of produced 11C and material degradation at modest beam currents both pose significant challenges for the development of a commercial system. The trapping of produced 11C in the target was most likely a function of the nontube impurities present in the commercially sourced BNNT nanomaterials. Impurities could be removed prior to irradiation by thermal oxidation in a furnace, followed by a water rinse. Future work will include beam irradiation tests of a sample of 11BNNT that has been purified at 600 °C for 1 h at the National Institute of Aerospace (NIA). 11BNNT material as-received from the BNNT, LLC, supplier is shown next to the purified material (which is layered with wax paper) in Figure 18. The purified material is whiter in color, more brittle, and has increased density of roughly one order of magnitude.
Material degradation of BNNT materials has been observed as a function of beam current, due to elevated temperature in the target. Bulk BNNT material has low effective thermal conductivity of roughly 1 W/m2-K [20], and significant thermal oxidation has been observed for BNNT targets in the range of 800–900 °C [21]. A new target prototype is currently being designed that aims to reduce peak temperature in the BNNT by utilizing a grazing angle for the beam with only a thin layer of BNNT. The grazing angle prototype target will use high-purity BNNT target media (99% nanotubes and 1% nontube impurities of B and h-BN) from supplier BNNano.

Author Contributions

Conceptualization, J.P. and B.W.; methodology, J.P.O. and M.S.; investigation, S.-H.C., J.P.O., M.J., and M.S.; writing—original draft preparation, J.P.; writing—review and editing, M.S.; visualization, J.P. and M.S.; supervision, M.S.; project administration, J.P.; funding acquisition, J.P. and B.W.

Funding

This research was funded by the National Science Foundation, grant numbers 1519701 and 1632484.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Rubio, A.; Corkill, J.L.; Cohen, M.L. Theory of graphitic boron nitride nanotubes. Phys. Rev. B 1994, 49, 5081–5084. [Google Scholar] [CrossRef] [Green Version]
  2. Weng-Sieh, Z.; Cherrey, K.; Chopra, N.G.; Blase, X.; Miyamoto, Y.; Rubio, A.; Cohen, M.L.; Louie, S.G.; Zettl, A.; Gronsky, R. Synthesis of BxCyNx nanotubules. Phys. Rev. B 1995, 51, 11229–11232. [Google Scholar] [CrossRef]
  3. Chopra, N.G.; Luyken, R.J.; Cherrey, K.; Crespi, V.H.; Cohen, M.L.; Louie, S.G.; Zettl, A. Boron nitride nanotubes. Science 1995, 269, 966–967. [Google Scholar] [CrossRef] [PubMed]
  4. Smith, M.W.; Jordan, K.C.; Park, C.; Kim, J.W.; Lillehei, P.T.; Crooks, R.; Harrison, J.S. Very long single- and few-walled boron nitride nanotubes (BNNTs) via the pressurized vapor/condenser method. Nanotechnology 2009, 20, 505604. [Google Scholar] [CrossRef] [PubMed]
  5. Kim, K.S.; Kim, M.J.; Park, C.; Fay, C.C.; Chu, S.H.; Kingston, C.T.; Simard, B. Scalable manufacturing of boron nitride nanotubes and their assemblies: A review. Semicond. Sci. Technol. 2016, 32, 013003. [Google Scholar] [CrossRef]
  6. Jensen, M.; Eriksson, T.; Severin, G.; Parnaste, M.; Norling, J. Experimental yields of PET radioisotopes from a prototype 7.8 MeV cyclotron. In Proceedings of the 15th International Workshop on Targetry and Target Chemistry, Prague, Czech Republic, 18–21 August 2014; pp. 112–113. [Google Scholar]
  7. Khachaturian, M.; Bailey, J. The ABT Molecular Imaging biomarker generator Dose-on-DemandTM high flow tantalum 1.0 water target. In Proceedings of the 16th International Workshop on Targetry and Target Chemistry, Santa Fe, NM, USA, 29 August–1 September 2016; pp. 2–4. [Google Scholar]
  8. Smirnov, V.; Vorozhtsov, S.; Vincent, J. Design study of an ultra-compact superconducting cyclotron for isotope production. Nucl. Instr. Meth. Phys. Res. A 2014, 763, 6–12. [Google Scholar] [CrossRef]
  9. Podadera, I.; Ahedo, B.; Arce, P.; García-Tabarés, L.; Gavela, D.; Guirao, A.; Lagares, J.I.; Martínez, L.M.; Obradors-Campos, D.; Oliver, C.; et al. Beam diagnostics for commissioning and operation of a novel compact cyclotron for radioisotope production. In Proceedings of the International Beam Instrumentation Conference (IBIC2013), Oxford, UK, 16–19 September 2013; pp. 660–663. [Google Scholar]
  10. Koziorowski, J.; Larsen, P.; Gillings, N. A quartz-lined carbon-11 target: Striving for increased yield and specific activity. Nucl. Med. Biol. 2010, 37, 943–948. [Google Scholar] [CrossRef] [PubMed]
  11. Savio, E.; García, O.; Trindade, V.; Buccino, P.; Giglio, J.; Balter, H.; Engler, H. Improving production of 11C to achieve high specific labelled radiopharmaceuticals. AIP Conf. Proc. 2012, 1509, 185–189. [Google Scholar] [CrossRef]
  12. Fonslet, J.; Itsenko, O.; Koziorowski, J. Indirect measurement of specific activity of [11C]CO2 and the effects of target volume fractionation. AIP Conf. Proc. 2012, 1509, 190–193. [Google Scholar] [CrossRef]
  13. Peeples, J.L.; Magerl, M.; O’Brien, E.M.; Doster, J.M.; Bolotnov, I.A.; Wieland, B.W.; Stokely, M.H. High current C-11 gas target design and optimization using multi-physics coupling. AIP Conf. Proc. 2017, 1845, 020016. [Google Scholar] [CrossRef]
  14. Firouzbakht, M.L.; Schlyer, D.J.; Wolf, A.P. Yield measurements for the 11B(p,n)11C and 10B(d,n)11C nuclear reactions. Nucl. Med. Biol. 1998, 25, 161–164. [Google Scholar] [CrossRef]
  15. Takacs, S.; Tarkanyi, F.; Hermanne, A.; Paviotti de Corcuera, R. Validation and upgrade of the recommended cross section data of charged particle reactions used for production PET radioisotopes. Nucl. Instrum. Methods Phys. Res. B 2003, 211, 169. [Google Scholar] [CrossRef]
  16. BNNT, LLC [US]. Available online: https://www.bnnt.com/products (accessed on 17 December 2018).
  17. Zhi, C.; Bando, Y.; Tang, C.; Golberg, D. Specific heat capacity and density of multi-walled boron nitride nanotubes by chemical vapor deposition. Solid State Commun. 2012, 151, 183–186. [Google Scholar] [CrossRef]
  18. BNNano. Available online: https://www.bnnano.com/products (accessed on 17 December 2018).
  19. Pelowitz, D.B. (Ed.) MCNPX User’s Manual Version 2.7.0; LA-CP-11-00438; Los Alamos National Laboratory: Santa Fe, NM, USA, 2011.
  20. Jakubinek, M.B.; Niven, J.F.; Johnson, M.B.; Ashrafi, B.; Kim, K.S.; Simard, B.; White, M.A. Thermal conductivity of bulk boron nitride nanotube sheets and their epoxy-impregnated composites. Phys. Status Solidi A 2016, 213, 2237–2242. [Google Scholar] [CrossRef] [Green Version]
  21. Chen, Y.; Zou, J.; Campbell, S.J.; Le Caer, G. Boron nitride nanotubes: Pronounced resistance to oxidation. Appl. Phys. Lett. 2004, 84, 2430. [Google Scholar] [CrossRef] [Green Version]
Figure 1. Cross-sections for 11C production from the 11B(p,n)11C and 14N(p,α)11C nuclear reactions.
Figure 1. Cross-sections for 11C production from the 11B(p,n)11C and 14N(p,α)11C nuclear reactions.
Instruments 03 00008 g001
Figure 2. Photograph of 500-mg sample of bulk boron nitride nanotube (BNNT) material from BNNT, LLC, supplier.
Figure 2. Photograph of 500-mg sample of bulk boron nitride nanotube (BNNT) material from BNNT, LLC, supplier.
Instruments 03 00008 g002
Figure 3. SEM images of (a) bulk BNNT material and (b) isolated nontube impurities.
Figure 3. SEM images of (a) bulk BNNT material and (b) isolated nontube impurities.
Instruments 03 00008 g003
Figure 4. Prototype target for Eclipse target changer including (A) Havar or aluminum window foil, (B) an aluminum target body, (C) cooling water, (D) a front sweep gas flow path, (E) a rear sweep gas flow path, and (F) a target chamber for BNNT.
Figure 4. Prototype target for Eclipse target changer including (A) Havar or aluminum window foil, (B) an aluminum target body, (C) cooling water, (D) a front sweep gas flow path, (E) a rear sweep gas flow path, and (F) a target chamber for BNNT.
Instruments 03 00008 g004
Figure 5. Photograph of BNNT material in the prototype target, showing material damage resulting from irradiation at 20-μA beam current.
Figure 5. Photograph of BNNT material in the prototype target, showing material damage resulting from irradiation at 20-μA beam current.
Instruments 03 00008 g005
Figure 6. BN-124 target: (a) Isometric and (b) vertical mid-plane cross-section views.
Figure 6. BN-124 target: (a) Isometric and (b) vertical mid-plane cross-section views.
Instruments 03 00008 g006
Figure 7. BN-131 target: (a) Isometric and (b) vertical mid-plane cross-section views.
Figure 7. BN-131 target: (a) Isometric and (b) vertical mid-plane cross-section views.
Instruments 03 00008 g007
Figure 8. Custom target station with mechanical support for additional axial target depth.
Figure 8. Custom target station with mechanical support for additional axial target depth.
Instruments 03 00008 g008
Figure 9. Diagram of experimental apparatus for material irradiation and isotope collection, illustrating a (A) target gas tank and regulator, (B) flow control valve, (C) target load valve, (D) target unload valve, (E) delivery/waste valve, (F) target body and target material, (G) soda lime carbon dioxide trap, and (H) radioisotope gas collection bag.
Figure 9. Diagram of experimental apparatus for material irradiation and isotope collection, illustrating a (A) target gas tank and regulator, (B) flow control valve, (C) target load valve, (D) target unload valve, (E) delivery/waste valve, (F) target body and target material, (G) soda lime carbon dioxide trap, and (H) radioisotope gas collection bag.
Instruments 03 00008 g009
Figure 10. 11CO2 saturation yield for the BN-124 target using a fill gas of nitrogen with 1% oxygen.
Figure 10. 11CO2 saturation yield for the BN-124 target using a fill gas of nitrogen with 1% oxygen.
Instruments 03 00008 g010
Figure 11. Photographs of the BN-124 target post-irradiation at (a) 1 μA; (b) 3 μA; (c) 5 μA; and (d) 8 μA.
Figure 11. Photographs of the BN-124 target post-irradiation at (a) 1 μA; (b) 3 μA; (c) 5 μA; and (d) 8 μA.
Instruments 03 00008 g011
Figure 12. 11C saturation yield for the BN-131 target at 5 μA.
Figure 12. 11C saturation yield for the BN-131 target at 5 μA.
Instruments 03 00008 g012
Figure 13. Percent of 11C recovered as CO2 for the BN-131 target at 5 μA.
Figure 13. Percent of 11C recovered as CO2 for the BN-131 target at 5 μA.
Instruments 03 00008 g013
Figure 14. 11C saturation yield for the BN-124 and BN-131 targets at 5 μA using nitrogen with 1% oxygen.
Figure 14. 11C saturation yield for the BN-124 and BN-131 targets at 5 μA using nitrogen with 1% oxygen.
Instruments 03 00008 g014
Figure 15. 11CO2 saturation yield for the BN-124 target using a fill gas of nitrogen with 1% oxygen.
Figure 15. 11CO2 saturation yield for the BN-124 target using a fill gas of nitrogen with 1% oxygen.
Instruments 03 00008 g015
Figure 16. Photographs of BNNT nanomaterials from (a) BNNT, LLC, and (b) BNNano.
Figure 16. Photographs of BNNT nanomaterials from (a) BNNT, LLC, and (b) BNNano.
Instruments 03 00008 g016
Figure 17. SEM images of BNNT nanomaterials from (a) BNNT, LLC, and (b) BNNano.
Figure 17. SEM images of BNNT nanomaterials from (a) BNNT, LLC, and (b) BNNano.
Instruments 03 00008 g017
Figure 18. Photograph of 500-mg sample of as-received BNNT (left) and 500-mg sample of BNNT following purification at the National Institute of Aerospace (NIA) at 600 °C for 1 h (right).
Figure 18. Photograph of 500-mg sample of as-received BNNT (left) and 500-mg sample of BNNT following purification at the National Institute of Aerospace (NIA) at 600 °C for 1 h (right).
Instruments 03 00008 g018
Table 1. Material shrinkage measurements and visual observations for the BN-124 target.
Table 1. Material shrinkage measurements and visual observations for the BN-124 target.
Beam Current (μA)Depth of Void (cm)Depth of 11BNNT (cm)Observations
0-6.0Gray color
1-6.0Off-white color
32.53.5White color, shrinkage
52.53.5White color, shrinkage
83.12.9 Crystallization, powdery buildup coating walls

Share and Cite

MDPI and ACS Style

Peeples, J.; Chu, S.-H.; O’Neil, J.P.; Janabi, M.; Wieland, B.; Stokely, M. Boron Nitride Nanotube Cyclotron Targets for Recoil Escape Production of Carbon-11. Instruments 2019, 3, 8. https://doi.org/10.3390/instruments3010008

AMA Style

Peeples J, Chu S-H, O’Neil JP, Janabi M, Wieland B, Stokely M. Boron Nitride Nanotube Cyclotron Targets for Recoil Escape Production of Carbon-11. Instruments. 2019; 3(1):8. https://doi.org/10.3390/instruments3010008

Chicago/Turabian Style

Peeples, Johanna, Sang-Hyon Chu, James P. O’Neil, Mustafa Janabi, Bruce Wieland, and Matthew Stokely. 2019. "Boron Nitride Nanotube Cyclotron Targets for Recoil Escape Production of Carbon-11" Instruments 3, no. 1: 8. https://doi.org/10.3390/instruments3010008

APA Style

Peeples, J., Chu, S. -H., O’Neil, J. P., Janabi, M., Wieland, B., & Stokely, M. (2019). Boron Nitride Nanotube Cyclotron Targets for Recoil Escape Production of Carbon-11. Instruments, 3(1), 8. https://doi.org/10.3390/instruments3010008

Article Metrics

Back to TopTop