2.1. Synthesis

For a typical synthesis, 2.32 g 1-methyl-DABCO (12.5 wt%) was mixed with 1.97 g KOH (20 wt%) and 0.743 g H-FAU (Si/Al = 6) to give a molar composition of 1(Si): 0.167(Al): 0.2(OSDA): 0.7(KOH): 20(H₂O). The resulting gel was mixed for 1 h at room temperature and then transferred into a Teflon lined autoclave. The crystallization was carried out at 150°C for 7 days unless otherwise stated. Solid yields are calculated based on Si/Al ratio in the reactant compared with the product. The raw materials used included: 1-methyl-DABCO prepared in-house (see supporting information for the synthesis procedure), KOH (reagent grade ≥98%, Sigma–Aldrich), in-house prepared co-precipitated amorphous silica–alumina (ASA) and Y-zeolite (CBV-712, from Zeolyst International).

2.2. Characterization

The synthesized materials were analyzed by X-ray diffraction using a Phillips PW1800 instrument system in θ–2θ geometry working in Bragg–Brentano mode using Cu Kα radiation (λ = 1.541 Å). An AntonPaar1200 cell equipped with a capillary stage was used for the in situ X-ray diffraction (XRD) heating experiments. Scanning electron microscopy (SEM) images were recorded using an XL30-SEM instrument operated at 10 kV. The samples were sprinkled over carbon tape, attached to Al stubs and then coated with a 30 nm layer of carbon to prevent charging. Thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) were performed using a Mettler TGA–DSC instrument with a heating rate of 5°C min⁻¹ and a temperature limit of 550°C. One-dimensional ¹³C-NMR was measured using a Brukner 400 MHz instrument in D₂O, and for the solid-state ¹³C CP-MAS NMR, the spectra were acquired at 9.4 T using a spinning speed of nR = 10.0 kHz and a CP contact time of 5.0 ms. For the ²⁷Al and ²⁹Si MAS NMR spectra, a Bruker Avance II HD 400 MHz spectrometer was used. ²⁷Al MAS NMR spectra were recorded at spinning rate of 20 kHz on a Bruker 3.2 mm probe, using a flip angle of π/12 and a recycle delay of 1 s. ²⁹Si MAS NMR spectra were recorded at a spinning rate of 5 kHz on a Bruker 4 mm probe using a flip angle of 60° and a recycle delay of 60 s.

3.1. Synthesis

The phase space using 1-methyl-DABCO was explored in alkaline media using NaOH or KOH. Two sources of T atoms (Si and Al) were selected for this screening study, namely the use of a co-precipitated silica–alumina as well as FAU. When 1-methyl-DABCO is used in combination with NaOH and FAU no crystalline products are observed at low OH⁻ concentrations. Increasing the OH⁻ concentration leads to a narrow region with LEV in line with previous studies (Xie et al., 2013). Further increase of the basicity yields ANA as the thermodynamic end-point in Na-rich systems (see Table S1).

In agreement with the example of LOS mentioned in the introduction and many other studies, exchanging the inorganic cation leads to a new set of obtainable phases. At low OH⁻ concentrations and high silica compositions (e.g. Si/Al gel ratios ≥ 15), when potassium hydroxide is applied together with the 1-methyl-DABCO organic molecule, a phase that we have not yet identified appears together with ERI, irrespective of the T atom source (see Table S2). At higher OH⁻ concentrations and in more Al-rich synthesis gels (Si/Al gel ratio = 6), phase selectivity becomes dependent on the T atom source (see Table 1). Using an amorphous co-precipitated silica–alumina leads to the well known LTL phase. However, exchanging the T atom source to a FAU zeolite leads to another zeolite product (named K-paracelsian herein, see below). This zeolite is furthermore dependent on the concerted effect of both 1-methyl-DABCO and potassium hydroxide. This is evident because the phase is only present as a small impurity when 1-methyl-DABCO is omitted in the gel (see sample 5 in Table 1). We also note that ERI is seen at lower hydroxide concentrations together with an unknown phase.

A phase-pure sample of the new zeolite was achieved (sample 4 in Table 1 and Fig. 1) by combination of high OH⁻ concentrations, an FAU as a T atom source and the combination of potassium hydroxide and 1-methyl-DABCO. Occlusion of the OSDA in the zeolite could not easily be measured by ¹³C CP-MAS NMR. Only when the number of scans was increased threefold could a small amount of C be measured in the sample (Fig. S1). This is consistent with the interpretation that 1-methyl-DABCO is not occluded in the pore system, which would have been expected from the classical role of an OSDA, but a small amount can be found on the surface of the crystallites. In the remaining part of the manuscript, we will focus on this material specifically.

Figure 1 Powder X-ray diffraction pattern and SEM image (insert) of K-paracelsian. The blue curve is the observed data, the red curve is the Rietveld fit of the final structure model and the grey curve is the difference curve.

3.2. Basic characterization and structure refinement

The initial characterization used to reveal the structure of the product (sample 4, Table 1) consisted of SEM imaging and ex situ XRD analysis of the as-synthesized products. SEM images revealed a homogeneous morphology consisting of large (∼2 µm) well faceted crystallites. Point EDS analysis on five different crystallites revealed an average composition of 3.3 (3) Si/Al and 0.29 (3) K/Si. Within the uncertainty of the EDS analysis, this is consistent with a stoichiometric compound of the composition KAlSi₃O₈, which is also in agreement with the expected Si/Al ratio from the yield reported in Table 1 and the Si/Al ratio of 2.92 calculated from ²⁷Si MAS NMR (Fig. S2).

Several attempts using the search–match software HighScorePlus combined with the PDF4+ database (Kabekkodu, 2018) did not result in identification of the phase. Because the search–match routine failed, an attempt to index the observed powder pattern was performed. Indexing and subsequent LeBail fitting (Coelho, 2018) revealed an orthorhombic unit cell, with the dimensions a = 9.198 (2) Å, b = 9.476 (2) Å and c = 8.593 (2) Å. The orthorhombic symmetry is also consistent with the morphology observed in the SEM images (see Fig. 1). A search of the ICSD (Hellenbrandt, 2004) using the observed lattice parameters with a 2% tolerance resulted in a match with four different published structures of paracelsian. This is a feldspar mineral with the composition BaAl₂Si₂O₈ and a structure consisting of a three-dimensional framework of corner sharing SiO₄ and AlO₄ tetrahedra, and Ba²⁺ cations filling interstitial sites. Because of the match in unit-cell dimensions and because the crystal chemistry of paracelsian is closely related to what is expected for sample 4, it is reasonable to assume that the new material is structurally closely related to paracelsian. The ionic radius of K⁺ is 133 pm while that of Ba²⁺ is 134 pm. It therefore makes perfect sense that both cations are able to structurally support the same paracelsian topology, but with Si/Al ratios of 3 and 1, respectively, to maintain charge neutrality.

A structure model based on the atomic arrangement from orthorhombic (Pnam) paracelsian (Smith, 1953), including the coupled substitution Ba²⁺ + Al³⁺ → K⁺ + Si⁴⁺, was therefore constructed. A subsequent Rietveld refinement (Coelho, 2018) using fixed atomic positions and fixed occupancies resulted in a good fit, confirming that the new material has the same framework topology as paracelsian. In the final step of the Rietveld analysis, the fractional coordinates of all atoms and the occupancy of K were refined, resulting in an excellent fit (Fig. 1) and in meaningful chemical bond distances and angles [see Figs. 2(a)–2(c) and the attached CIF]. The refined occupancy of K is 0.98 (1), which is very close to the initially assumed value of 1 for the stoichiometric compound KAlSi₃O₈. The name K-paracelsian is proposed for the new material.

Figure 2 Framework topology of K-paracelsian and a related feldspar represented by connected T sites. (a) and (b) topology of K-paracelsian. Red planes are used to emphasize the double-crankshaft chains and the black spheres represent potassium positions. The structure is shown in projection parallel and perpendicular to the double-crankshaft chains, respectively. (c) K-paracelsian cages occupied by potassium atoms. All cages are equivalent by space group symmetry (Pnam). Colours have been added to emphasize individual cages. (d) Framework topology of the feldspar mineral microcline in projection parallel to the twisted double-crankshaft chains.

The framework topology of common feldspars like orthoclase, albite and microcline as well as most other feldspars consist of twisted interconnected double-crankshaft chains as shown in Fig. 2(d). In contrast, the paracelsian topology consists entirely of straight interconnected double-crankshaft chains, which are also observed in many zeolite topologies such as GIS, APC, MER, PHI, SIV and GME (Baerlocher & McCusker, 2018).

The question we want to address next is whether K-paracelsian should be considered a feldspar or a zeolite. Feldspar and zeolite topologies consist of corner-connected SiO₄ and AlO₄ tetrahedra, forming a periodic three-dimensional structure. Feldspar topologies are made entirely of four, six and eight rings of connected tetrahedra. Some small-pore zeolites such as GIS, APC, MER, PHI and SIV are also constructed entirely from four, six and eight rings, resulting in cages and channels similar in size to those observed in feldspars. In this respect, feldspars could be considered small-pore zeolites. Water content is another property used to define the difference between feldspars and zeolites (Barrer, 1982): feldspars are anhydrous whereas zeolites are hydrous. For zeolites, it is well known that water can escape along the channels when heated, resulting in a significant change in the observed lattice parameters. For anhydrous feldspars we only expect to observe changes in lattice parameters that are consistent with the thermal expansion properties of the material. In situ XRD heating experiments were therefore performed on K-paracelsian and a reference feldspar material.

3.3. Comparison with isocompositional microcline

A fragment of microcline from a graphic granite collected in Setesdalen in Norway was used as a reference for the isocompositional K-paracelsian. Both samples were heated in air from room temperature to 500°C in steps of 20°C at a rate of 40°C h⁻¹ and cooled to room temperature using a symmetric ramp. XRD data were measured at each step. This heat treatment was repeated twice for each sample [Fig. 3(a), orange data points]. Analysis of the microcline data revealed the sample was composed of 83 wt% microcline and 17 wt% albite. Both feldspars show a simple linear relationship with temperature variation and a fully reversible behaviour on the four temperature ramps as shown in Fig. 3(b). These observations are fully consistent with simple thermal expansion and contraction.

Figure 3 Observed changes in K-paracelsian during two cycles of heating. (a) Evolution of the b axis (blue) during the temperature programme shown in orange. (b) Relative changes in unit-cell volume of K-paracelsian (blue) and the reference feldspars (yellow = albite and grey = microcline). (c) Observed sample weight during the TGA experiment (orange) plotted together with observed b axis variations (blue) from the in situ XRD experiment.

K-paracelsian, however, shows a clear non-linear unit-cell evolution in the temperature range 250–450°C on the first heating ramp [Figs. 3(a) and 3(b)]. On the following three ramps, K-paracelsian shows a linear and reversible change similar to that observed in the anhydrous feldspars [Fig. 3(b)]. The observed thermal expansion is dominated by the strong temperature dependence of the a and c parameters, while the b parameter shows almost no temperature dependence on the last three ramps [Fig. 3(a)]. The data from the TGA experiment show a relative mass loss of 5.7% in the temperature range 250–450°C, where the non-linear unit-cell evolution was observed [Fig. 3(c)]. The heat-treated K-paracelsian sample was reanalyzed at room temperature after 4 weeks of exposure to air. The observed lattice parameters were consistent with those of the dehydrated K-paracelsian, indicating that dehydration is not reversible under ambient conditions.

Normal zeolite dehydration behaviour, as observed in chabazite and faujasite, consists of an initial steep gradual weight loss initiated slightly above room temperature and continuing up to 200°C where at least 90% of the water has been evaporated. Most of the remaining water will have been evaporated by 400°C. In contrast to chabazite and faujasite, the zeolite natrolite (Na₂Al₂Si₃O₁₀·2H₂O) shows very little weight loss at temperatures up to 250°C, followed by a steep weight loss of 10% consistent with a loss of both water molecules (Gottardi & Galli, 1985; van Reeuwijk, 1974). In contrast to most other zeolites, all water molecules in natrolite are located in relatively well defined positions within the first coordination shell of Na, where they complete a six-fold coordination shell with a slightly distorted trigonal prism geometry (Meier, 1960).

The dehydration behaviour of K-paracelsian is very similar to that of natrolite, with a weight loss consistent with one water molecule per cage (KAlSi₃O₈·H₂O). Inspection of the calculated independent atom model electron density, as shown in Fig. 4, reveals a minimum in the density at the position where a water molecule would complete an octahedral coordination of the six oxygen atoms closest to K.

Figure 4 Calculated independent atom model electron density (Momma & Izumi, 2011) of the K-paracelsian structure. Yellow areas illustrate positions in the cage with minimum electron density.

Inspection of the observed XRD data of the as-synthesized sample did not reveal significant amounts of residual electron density in this position, indicating a more disordered nature of the H₂O positions. The evolution of the K occupancy as a function of temperature is shown in Fig. 5. The overall apparent temperature dependence of the K occupancy is an artefact caused by correlation with the displacement parameters. The relative decrease observed on the first heating ramp between 200 and 400°C is reliable and shows that a small fraction of the electron density inside the cages is disappearing at this stage. This observation could be consistent with a water molecule disappearing from the first coordination shell of K, or it could be consistent with an interpretation where a few percent of K ions are missing, leaving space available to be occupied by water molecules. The data are not conclusive on this issue.

Figure 5 Refined K-occupancies as a function of temperature. Orange points were collected on the first heating ramp.