- 1. Introduction
- 2. Concept, pressure vessel and sample holder of the type-III gas-pressure cell
- 3. Double-walled sapphire single-crystal gas-pressure cell (type III)
- 4. Assembly
- 5. Tested temperature and pressure conditions
- 6. Validation of the double-walled sapphire single-crystal gas-pressure cell
- 7. Data quality of the type-I, -II and -III gas-pressure cells
- 8. Conclusions
- Supporting information
- References
- 1. Introduction
- 2. Concept, pressure vessel and sample holder of the type-III gas-pressure cell
- 3. Double-walled sapphire single-crystal gas-pressure cell (type III)
- 4. Assembly
- 5. Tested temperature and pressure conditions
- 6. Validation of the double-walled sapphire single-crystal gas-pressure cell
- 7. Data quality of the type-I, -II and -III gas-pressure cells
- 8. Conclusions
- Supporting information
- References
research papers
A double-walled sapphire single-crystal gas-pressure cell (type III) for in situ neutron diffraction
aInorganic Chemistry, Leipzig University, Johanisallee 29, Leipzig, 04103, Germany, and bInstitut Laue–Langevin, 71 avenue des Martyrs, Grenoble, 38000, France
*Correspondence e-mail: holger.kohlmann@uni-leipzig.de
In situ neutron diffraction is an important characterization technique for the investigation of many functional materials, e.g. for hydrogen uptake and release in hydrogen storage materials. A new sapphire single-crystal gas-pressure cell for elastic neutron scattering has been developed and evaluated; it allows conditions of 298 K and 9.5 MPa hydrogen pressure and 1110 K at ambient pressure. The pressure vessel consists of a sapphire single-crystal tube of 35 mm radius and a sapphire single-crystal crucible as sample holder. Heating is realized by two 100 W diode lasers. It is optimized for the D20 diffractometer, ILL, Grenoble, France, and requires the use of a radial oscillating collimator. Its advantages over earlier sapphire single-crystal gas-pressure cells are higher maximum temperatures and lower background at low and high diffraction angles. The deuterium uptake in palladium was followed in situ for validation, proving the potential of the type-III gas-pressure cell for in situ neutron diffraction on solid–gas reactions.
Keywords: neutron diffraction; hydrogenation; neutron instrumentation; solid–gas; metal hydrides; sapphire; powder diffraction.
1. Introduction
In situ X-ray and neutron diffraction have become very popular recently, because many interesting phenomena may be studied, such as phase transitions, chemical reactions, the wear of functional materials, the functioning of heterogeneous catalysts and battery materials, and industrial processes (Isnard, 2007; Pienack & Bensch, 2011; Hansen & Kohlmann, 2014; Yang et al., 2016; Peterson et al., 2017; Kohlmann, 2019). Time-resolved in situ neutron diffraction investigations are particularly interesting for materials in energy storage because processes of charging and discharging may be studied on an atomic level, e.g. in battery materials or in metal hydrides for hydrogen storage. Many phase transitions occur within the latter class of compounds, e.g. temperature- and pressure-driven structural and magnetic phase transitions (Kohlmann et al., 2003; Goncharenko et al., 1996). Hydrogen uptake and release from metal hydrides are of importance in view of the use as hydrogen stores (Møller et al., 2014; Hansen & Kohlmann, 2014; Götze et al., 2018).
For the in situ investigation of hydrogenation reactions under hydrogen (deuterium) gas pressure and at elevated temperature, specialized gas-pressure cells with laser heating have been developed and used in many studies (Peterson et al., 2017; Götze et al., 2018; Finger, Kurtzemann et al., 2021; Finger, Hansen & Kohlmann, 2021). A sample environment based on single-crystal holders made of α-Al2O3 [called sapphire herein; see Finger, Kurtzemann et al. (2021)] allows for extremely low background without parasitic reflections, given proper orientation of the single crystal. Typically, they operate with laser heating at moderate temperatures and allow for a time resolution of less than 1 min (on high-intensity diffractometers). They can withstand high hydrogen (deuterium) gas pressures [e.g. 16.0 MPa at 298 K and 8.0 MPa at 655 K for type I (Finger, Kurtzemann et al., 2021)], but are not designed for high temperatures. The highest temperature reached so far, 718 K, was recorded at ambient pressure with a type-II cell (Finger, Hansen & Kohlmann, 2021). In the present publication we describe a new type of sapphire single-crystal gas-pressure cell (type III). It allows for in situ neutron powder diffraction at considerably higher temperatures, thus enabling a wider range of solid–gas reactions to be studied. It is optimized for the D20 diffractometer (Hansen et al., 2008), ILL, Grenoble, France, in high-resolution mode, with a take-off angle of 120° and a wavelength of about 187 pm, and requires the use of a radial oscillating collimator.
2. Concept, pressure vessel and sample holder of the type-III gas-pressure cell
The previously presented gas-pressure cells of types I and II combine pressure vessel and sample holder in one work piece, a 10 cm-long machined sapphire single crystal with a 6 mm borehole (Finger, Kurtzemann et al., 2021; Finger, Hansen & Kohlmann, 2021). In type-I gas-pressure cells the sample holder is fixed between a base mount and a flange joint with no connection in between, thus providing free optical access in the diffraction plane (Finger, Kurtzemann et al., 2021). The type-II gas-pressure cell uses a single corpus around the sample holder with windows for primary and scattered neutron beams, optical surveillance and laser heating (Finger, Hansen & Kohlmann, 2021). For the cell presented herein, type III, the tasks of holding pressure and holding a sample are uncoupled, i.e. the pressure vessel and sample holder are two different work pieces. This results in more for physical dimensions and materials, and offers the opportunity to optimize both pieces for their individual task. For example, the sample holder may have a smaller wall thickness, since it does not need to withstand the gas pressure, reducing the contribution of the sample holder and thus resulting in a higher quality of the diffraction data. Furthermore, a smaller wall thickness for the sample holder means that a much wider variety of materials can be used as sample holder, e.g. parasitic reflections from polycrystalline materials or the structured background of amorphous materials may be small or negligible. Such materials were ruled out of consideration as a pressure vessel by Finger et al. but meet the requirements to be potential sample holders for the type-III gas-pressure cell. Therefore, we firstly focused on quartz glass (Hilgenberg GmbH, Malsfeld, Germany) as it is available in small wall thicknesses of less than 1 mm, even with an inner diameter of 4 mm. Though quartz glass showed a highly structured background despite its small wall thickness of 0.25 mm (Fig. 1, top), a sapphire single-crystal crucible, 32 mm in height, 6 mm inner diameter with a wall thickness of 1 mm, has been chosen as sample holder (Fig. 2). Despite the much higher wall thickness, the crucible offers a better overall data quality because of its low background contribution for proper orientation of the single-crystal crucible. For the pressure vessel, a sapphire single-crystal tube is used (Impex HighTech GmbH, Münster, Germany). The material is a common choice for in situ diffraction experiments (Finger, Kurtzemann et al., 2021; Götze et al., 2018). Neutron activation, neutron absorption for and are low for sapphire (Sears, 1992). Furthermore, potential irradiation damage occurs only at neutron doses as high as 1018 neutrons cm−2 (Abdukadyrova, 2005), which is way above the expected value for a typical neutron diffraction experiment considering the neutron at D20 [107 neutrons s−1 cm−2 for λ = 1.87 Å, Ge(115) monochromator, 120° take-off angle (Hansen et al., 2008)].
To completely avoid the contribution of the pressure vessel to the resulting diffraction pattern, a minimum diameter of 35 mm is dictated by the radial oscillating collimator used at D20 (Fig. 2). Equation (1) of Finger, Kurtzemann et al. (2021) gives a maximum pressure of 63 MPa at 298 K for a wall thickness of 3 mm and about 43 MPa at 770 K. Including a safety factor of four to account for mechanical stress and potential imperfections of the single crystal, the use of the type-III gas-pressure cell is limited to a maximum overpressure of 10 MPa. So far, a maximum pressure of 9.5 MPa at room temperature has been tested. Higher pressures may be realized but have not yet been tested, because they are not necessary for the kind of in situ experiment that we have so far carried out, typically with 0.1 < p < 10 MPa and 300 < T < 700 K.
3. Double-walled sapphire single-crystal gas-pressure cell (type III)
The gas-pressure cell has three main parts: a bottom plate, a corpus and a top plate. All main parts are made of austenitic chromium–nickel stainless steel (EN 1.4301/AISI 304). The bottom plate has a diameter of 80 mm and a thickness of 8 mm. The corpus is connected to it via eight M6 Allen screws. To fix the cell on the diffractometer, the bottom plate has an ISO metric M8 thread (Fig. 2). The grooves in the plate, 36.17 and 41.41 mm, are for the NBR 70 O-ring seal (Nitrile Butadiene Rubber 70 Shore, usable up to 393 K) to realize gas pressure. The outer rim keeps the O-ring in position. The corpus is the main part of the gas-pressure cell as it connects the bottom and top plates. It is painted with neutron-absorbing gadolinium oxide varnish to prevent neutron activation. The top plate is similar to the bottom plate with six boreholes to screw it to the corpus. A T-piece is welded on top of the plate for gas feed and temperature measurement. A thermocouple covered with neutron-absorbing gadolinium oxide varnish may be screwed into a 6 mm Swagelok nut in order to measure temperature in the reaction chamber (Figs. 3 and 4). Temperature surveillance with a pyrometer as for types I and II did not work, because only the temperature of the pressure vessel was measured. However, the opening that was originally designed for the pyrometer can be used for optical surveillance, which is valuable for reactions including colour changes.
The higher gas volume, compared with the type-I and -II cells, is compensated with an inlet, lowering the gas volume from 67.3 to 27.3 cm3 and thus minimizing risk. The inlet is 32 mm in diameter and 60 mm in height and has a 16 mm opening on the bottom for the sample holder and its rest. So as not to interfere with the primary beam or scattered neutrons, the inlet has the same openings as the corpus (Figs. 3 and 4). To prevent neutron activation, the corpus and inlet are painted with a neutron-absorbing varnish as used for the type-II gas-pressure cells (Finger, Hansen & Kohlmann, 2021). The inlet is fixed on the bottom plate via three pins, allowing a reproducible positioning. The central rest for the sample holder is not higher than the painted inlet, thus preventing neutron activation.
4. Assembly
As a first step, an O-ring seal (Fig. 5, black) is placed onto the bottom plate (Fig. 5, red). Then, the corpus (Fig. 5, green) is screwed to the bottom plate. The crucible is placed on the sample stage in the middle of the bottom plate and the inlet (Fig. 5, blue) is carefully put on top, being clicked into the three pins (Fig. 3, bottom left) to allow a reproducible positioning. Afterwards, the sapphire tube as pressure vessel (Fig. 5, grey) is placed on the O-ring. The threaded bars (ISO metric M6, 40 mm long) are turned all the way in the corresponding threaded boreholes on the top of the corpus. The upper seal is positioned on the top of the sapphire tube and the top plate is put carefully on top. Finally, the gas-pressure cell is screwed together by fastening the nuts on the threaded bars finger tight and then turning them crosswise step by step up to a torque of 1.2 N m. The thermocouple and gas supply may be attached afterwards. To realize the gas-tight sealing of the thermocouple with an inner diameter of 6 mm, a corresponding 6 mm Swagelok screw connection is attached and fixed.
5. Tested temperature and pressure conditions
In the course of our in situ studies, typical temperature–pressure conditions for hydrogenation reactions were applied, which are considerably lower than the maximum values given above. As breaking tests were not performed, we cannot state the maximum temperature–pressure conditions, but only those tested and found to be safe (Table 1 and Appendix A). The maximum temperature–pressure conditions might be higher. The temperatures are much higher than for type-I and -II cells (Finger, Kurtzemann et al., 2021; Finger, Hansen & Kohlmann, 2021), which is clearly one of the advantages of decoupling the pressure vessel and sample holder, albeit at the cost of reduced maximum pressure. For technical reasons, high temperatures have so far only been tested in air, but are expected to hold also for hydrogen pressures.
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For the exact sample temperature determination on a neutron diffractometer, calibration was performed via the known ) by a procedure described previously (Finger, Kurtzemann et al., 2021).
of the palladium lattice (Dutta & Dayal, 19636. Validation of the double-walled sapphire single-crystal gas-pressure cell
An ω scan (data collection while turning around the principal goniometer axis) of the type-III gas-pressure cell (Fig. 6, left) shows a section of about 5° with no significant change in absolute intensities (Fig. 6, middle) and of about 8° with unaffected reflection/background ratio (Fig. 6, right). Typically, less than 5° is needed for the fine tuning of the ω position, according to our experience with the single crystals used in type-I and -II cells (Finger, Kurtzemann et al., 2021; Finger, Hansen & Kohlmann, 2021). Thus, the window is wide enough to allow for proper alignment of the type-III gas-pressure cells.
To validate the type-III gas-pressure cell, the hydrogenation of palladium was studied. It is well suited due to a great body of knowledge, the high symmetry of the starting material and the resulting palladium deuteride, and favourable neutron scattering lengths. For the reaction, deuterium was chosen instead of hydrogen because of its lower in situ experiment, palladium powder was heated under vacuum (9 kPa) to 360 (2) K before injections of deuterium gas were slowly added. Rietveld refinements were performed using FullProf with pseudo-Voigt profile functions (Rodríguez-Carvajal, 1993). Starting models for palladium and the α and β phases of palladium deuteride were taken from the work of Kohlmann et al. (2013).
Palladium powder (99.95%, mesh size < 150 µm, GoodFellow) was dried under vacuum (1 Pa) at 773 K for 24 h and handled under argon afterwards. In theWhen hydrogen is absorbed by palladium, hydrogen atoms occupy octahedral voids; tetrahedral void occupation as seen above the ) was not observed, as we performed the experiment at temperatures and pressures below the The deuterium contents of palladium deuteride in this in situ experiment (Table 2) are in good accordance with the experimental data (Wicke & Blaurock, 1987) (Figs. 7, 8 and 9). The lattice parameter and isotropic displacement parameters (Biso) of the atoms are reasonable (Table 2).
of the phase diagram (Pitt & Gray, 2003
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7. Data quality of the type-I, -II and -III gas-pressure cells
To evaluate the overall data quality, the background at low and high 2θ values and the reflection/background ratios are considered (Table 3 and Fig. 10, top). The same amount of sample has been used for measurements with the type-I and -II gas-pressure cells, and only the measurement time is different (10 min for type III instead of 20 min for types I and II); thus the measurements are comparable for normalized representations (Fig. 10, bottom). Details for the type-I and -II measurements are provided by Finger, Hansen & Kohlmann (2021). The striking feature of the type-III compared with the type-I and -II gas-pressure cells is a very low background at low and high angles [calculated as by Finger, Hansen & Kohlmann (2021), standard deviation of intensities considered]. The air and deuterium gas scattering, visible at low 2θ angles, is very small, as a result of the inlet (Figs. 4 and 5).
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The tested temperature and pressure conditions of all three types of gas-pressure cells are compared in Fig. 11. The type-I cell has been used for over ten years and thus has well known operating conditions. Type-II and -III cells are mainly used for laboratory tests and are less well studied under real conditions. The type-III cell offers most potential at higher temperatures with a maximum of about 1110 K reached at 0.1 MPa air.
8. Conclusions
In this work we present a new design for a sapphire single-crystal gas-pressure cell for in situ neutron diffraction. It is suitable for hydrogenation reactions up to 10 MPa and reached a maximum temperature of about 1110 K. Its advantage over earlier designs is a lower diffraction background at low and high diffraction angles. The decoupling of the sample holder and pressure vessel allows for an optimization of both parts independently. Moreover, the new design allows for higher sample temperatures and thus enables further studies of thermal stability, decomposition, and reversibility of hydrogen uptake and release. The adaptation to gases other than hydrogen should be straightforward and will allow a wide range of in situ experiments on solid–gas reactions in the future.
APPENDIX A
Validation of temperature measurements
In order to confirm the measured temperatures in the type-III gas-pressure cell, three different experiments were performed using the same crucible with a 20–22 mm-high filling of silicon powder and heating by two diode lasers running at 91.5 W. A thin thermocouple was put into the crucible, measuring the temperature at the position of maximum laser heating to be 1110 K (experiment A). The temperature of the top surface of the sample was measured by a pyrometer to be 1013 K (experiment B). A long thin piece of aluminium was stuck into the silicon powder, reaching from the position of maximum laser heating to the air above the heating zone, while a thermocouple at 3 mm depth measured 839 K (experiment C). About half of the aluminium melted, which is in accordance with the temperature gradient and proves that the maximum temperature was at least as high as the melting point of aluminium (933 K). Additionally, the gadolinium oxide varnish showed signs of thermal decomposition, which is another indication of high sample temperatures (Fig. 12).
Supporting information
Link https://doi.org10.5291/ILL-DATA.5-24-605
Raw data: NUMOR 975353
Link https://doi.org/10.5291/ILL-DATA.5-24-639
Raw data: NUMOR 178819
Link https://doi.org/10.5291/ILL-DATA.5-24-621
Raw data: NUMOR 138794
Link https://doi.org/10.5291/ILL-DATA.5-22-767
Raw data: NUMORs 145703, 145704, 145748
Link https://doi.org/10.5291/ILL-DATA.5-24-639
Raw data: NUMORs 178819, 178776, 178781, 178810, 178819
Acknowledgements
We acknowledge the Institut Laue–Langevin for provision of beamtime at the high-intensity powder diffractometer D20 (Finger, Hansen & Kohlmann, 2021; https://10.5291/ILL-DATA.1-10-47). Open access funding enabled and organized by Projekt DEAL. Author contributions are as follows: conceptualization, RF, HK; methodology, RF, HK; software, RF; validation, RF; formal analysis, RF; investigation, RF, TCH, HK; resources, HK; data curation, RF; writing – original draft preparation, RF; writing – review and editing, RF, TCH, HK; visualization, RF; supervision, HK; project administration, HK; funding acquisition, HK.
Funding information
This work was supported by the BMBF – German Federal Ministry of Education and Research (grant No. 05K16OL1 to Holger Kohlmann).
References
Abdukadyrova, I. Kh. (2005). Inorg. Mater. 41, 1080–1084. Web of Science CrossRef CAS Google Scholar
Dutta, B. N. & Dayal, B. (1963). Phys. Status Solidi B, 3, 2253–2259. CrossRef CAS Web of Science Google Scholar
Finger, R., Hansen, T. C. & Kohlmann, H. (2021). QuBS, 5, 22. Web of Science CrossRef Google Scholar
Finger, R., Kurtzemann, N., Hansen, T. C. & Kohlmann, H. (2021). J. Appl. Cryst. 54, 839–846. Web of Science CrossRef CAS IUCr Journals Google Scholar
Goncharenko, I. N., Mignot, J.-M. & Mirebeau, I. (1996). Neutron News, 7(3), 29–31. CrossRef Google Scholar
Götze, A., Auer, H., Finger, R., Hansen, T. C. & Kohlmann, H. (2018). Physica B, 551, 395–400. Google Scholar
Hansen, T. C., Henry, P. F., Fischer, H. E., Torregrossa, J. & Convert, P. (2008). Meas. Sci. Technol. 19, 034001. Web of Science CrossRef Google Scholar
Hansen, T. C. & Kohlmann, H. (2014). Z. Anorg. Allg. Chem. 640, 3044–3063. Web of Science CrossRef CAS Google Scholar
Isnard, O. (2007). C. R. Phys. 8, 789–805. Web of Science CrossRef CAS Google Scholar
Kohlmann, H. (2019). Eur. J. Inorg. Chem. 2019, 4174–4180. CrossRef CAS Google Scholar
Kohlmann, H., Kurtzemann, N. & Hansen, T. (2013). Powder Diffr. 28, S242–S255. Web of Science CrossRef CAS Google Scholar
Kohlmann, H., Moyer, R. O. Jr, Hansen, T. & Yvon, K. (2003). J. Solid State Chem. 174, 35–43. Web of Science CrossRef ICSD CAS Google Scholar
Møller, K. T., Hansen, B. R. S., Dippel, A.-C., Jørgensen, J.-E. & Jensen, T. R. (2014). Z. Anorg. Allg. Chem. 640, 3029–3043. Google Scholar
Peterson, V. K., Auckett, J. E. & Pang, W.-K. (2017). IUCrJ, 4, 540–554. Web of Science CrossRef CAS PubMed IUCr Journals Google Scholar
Pienack, N. & Bensch, W. (2011). Angew. Chem. 123, 2062–2083. Web of Science CrossRef Google Scholar
Pitt, M. P. & Gray, E. (2003). Europhys. Lett. 64, 344–350. Web of Science CrossRef CAS Google Scholar
Rodríguez-Carvajal, J. (1993). Physica B, 192, 55–69. Google Scholar
Sears, V. F. (1992). Neutron News, 3(3), 26–37. CrossRef Google Scholar
Wicke, E. & Blaurock, J. (1987). J. Less-Common Met. 130, 351–363. CrossRef CAS Web of Science Google Scholar
Yang, J., Muhammad, S., Jo, M. R., Kim, H., Song, K., Agyeman, D. A., Kim, Y.-I., Yoon, W.-S. & Kang, Y.-M. (2016). Chem. Soc. Rev. 45, 5717–5770. Web of Science CrossRef CAS PubMed Google Scholar
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