2.1. Sample preparation

Sulfur flakes (Aldrich Chemical Co.) were hand ground and ca 6 cm³ of the resulting fine powder then sealed under helium gas in a rectangular sample can. The sample-can body was fabricated from aluminium alloy and incorporated a heater and Rh/Fe sensor; the sample was irradiated by the neutron beam through thin vanadium windows. Monoclinic sulfur was prepared by heating the sample to 380 K inside a standard `orange' He-flow cryostat maintained at 200 K. At room temperature, the transformation from β- to α-sulfur takes less than 1 h, although below 250 K β-sulfur is stable for several weeks. However, attempts to quench the sample in the β phase within the cryostat using a cooling rate of some 20 K min⁻¹ proved unsuccessful. Removing the sample from the cryostat and then quenching in liquid nitrogen yielded a phase-pure sample of monoclinic sulfur.

2.2. Data collection

The sample was removed from liquid nitrogen and mounted on a displex before cooling to 40 K. During the transfer period, at no time did the sample temperature exceed 240 K. Time-of-flight neutron powder diffraction data were collected on the high-resolution powder diffractometer (HRPD; Ibberson et al., 1992) at the ISIS pulsed neutron source. Data were recorded at backscattering, 〈2θ〉 = 168, over a time-of-flight range between 45 and 145 ms, corresponding to a d-spacing range of between 0.9 and 2.9 Å. Under these experimental settings the instrumental resolution, Δd/d, is approximately constant and equal to 8 × 10⁻⁴.

Diffraction data were recorded at 5 K intervals between 40 and 175 K, and between 215 and 250 K for a period of approximately 25 min (18 µAh); at each 25 K interval (i.e. at 50, 75, 100 K etc.) a longer data collection period, 140 min (100 µAh), was used. Over the region of the λ transition, between 180 and 210 K, data were also recorded at 2 K intervals for 18 µAh. In all cases, a period of 5 min for temperature equilibration was allowed between each data set.

2.3. Data analysis

A standard data reduction procedure was followed: the data were normalized to the incident-beam monitor profile and corrected for detector-efficiency effects using a previously recorded vanadium spectrum. The diffraction data were analysed using an in-house program suite adapted for neutron time-of-flight data (David et al., 1992) and based on the Rietveld method. The peak shape used in the refinement was the standard form for the high-resolution powder diffractometer (HRPD) at ISIS consisting of the convolution of a Voigt function with a double-exponential decay. Experimental details are given in Table 1.¹

Table 1 Experimental details for β-sulfur at 100 K Crystal data Chemical formula S8 Mr 256.58 Cell setting, space group Monoclinic, P21 Temperature (K) 100 a, b, c (Å) 10.8125 (1), 10.7232 (1), 10.6883 (1) β (°) 95.7460 (10) V (Å3) 1233.02 (2) Z 6 Dx (Mg m−3) 2.073 (1) Radiation type Time-of-flight neutron Specimen form, colour Flat sheet (particle morphology: irregular powder), yellow Specimen size (mm) 20 × 15 × 15     Data collection Diffractometer HRPD Data collection method Specimen mounting: standard rectangular sample holder (vanadium windows); time-of-flight range 45–145 ms Total flight path (m), 〈2θ〉 (°) 95.89, 168.329     Refinement Refinement on Rietveld method R-factors and goodness-of-fit Rp = 0.049, Rwp = 0.053, Rexp = 0.030, RB = 0.069, S = 3.19 Wavelength of incident radiation (Å) 1.85–5.98 Excluded region(s) None Profile function CCSL TOF profile function No. of parameters 86 Weighting scheme Based on measured s.u.s (Δ/σ)max 0.04 Computer programs used: ISIS Instrument control program (ICP), TF12LS (David et al., 1992), standard HRPD normalization routines, PLATON (Spek, 2003).

Atomic positions for the initial model of the ordered structure were taken from the 113 K data of Goldsmith & Strouse (1977). As was the case with the single-crystal X-ray study, the refinements were performed in the space group P2₁ with the 2₁ axis at x = 0, z = ¼, and with the constraint that the site occupancies for the disordered pseudocentric molecules summed to one. Although only a single parameter was refined for the fractional occupancy of one of the molecular sites, the structural analysis remained complex even with high-resolution powder diffraction data since there are four molecules, two ordered and the pseudocentric disordered pair, in the asymmetric unit and thus over 90 refinable parameters in terms of atomic coordinates alone. Indeed the comparatively weak neutron scattering length of sulfur (b = 2.847 fm) along with pseudosymmetry in the lattice-parameter values contribute additional difficulties with the analysis, especially with the rapidly collected data. It was therefore necessary to impose additional constraints on the structural model.

Firstly, the pseuodocentricity of the disordered S₈ crowns was rigorously imposed and the isotropic displacement parameters on the two ordered molecules were constrained to be equal, as were those of the partially occupied disordered molecular sites. Second, geometric bond length and angle constraints were applied. The bond lengths and angles were divided into two sets corresponding to the ordered and disordered molecules; in each set the bond lengths and angles were weakly restrained to be equal within ± 0.001 Å and ± 0.01°, respectively. These restraints are consistent with results from the single-crystal X-ray refinements (Goldsmith & Strouse, 1977) and have the advantage of biasing the refinement towards a chemically reasonable result, but without dictating precise bond-length and bond-angle values. A scale factor, coefficients of a background polynomial function, lattice constants and sample-dependent peak-width parameters were also refined.

3.1. Structure refinement

The structure of monoclinic sulfur is illustrated in Fig. 2 and the result of the profile fitting to the 100 K data set is shown in Fig. 3. The complexity of the powder diffraction pattern is evident. Table 2 lists the average bond lengths and bond angles for the ordered and disordered S₈ molecules in the structure in comparison with the 113 K X-ray single-crystal refinement. The values from the neutron powder data of 2.052 (10) Å and 107.4 (3)° for the average intramolecular bond length and bond angle, respectively, are in excellent agreement with the single-crystal values. Again, it should be emphasized that the constraints during refinement are only for equivalence between bond lengths and angles with no specific value being assigned. The method is further validated in that slight deviations from the ideal crown configuration observed in the single-crystal study are not significant compared with the estimated standard deviations on the bond length and angle values in the present study. The estimated standard deviations are some 3–5 times greater in the neutron-powder study than in the X-ray single-crystal study.

Table 2 Average intermolecular bond lengths (Å) and angles (°)   Neutron powder diffraction (this work) 100 K X-ray single-crystal diffraction (113 K)† 〈S—S〉I (Å)‡ 2.052 (10) 2.051 (2) 〈S—S〉II (Å)‡ 2.052 (10) 2.049 (2) 〈S—S〉III (Å)‡ 2.052 (10) 2.02 (3)       〈S—S〉I (°)‡ 107.4 (5) 107.66 (6) 〈S—S〉II (°)‡ 107.4 (5) 108.10 (6) 〈S—S〉III (°)‡ 107.4 (5) 114 (1) †See Goldsmith & Strouse (1977). ‡Molecule (I) comprises atoms S1–S8, molecule (II) atoms S9–S16 and the disordered molecule (III) atoms S17—S24 and S17′—S24′.

Figure 2 Illustration of the crystal structure of monoclinic sulfur, viewed (a) along the b axis and (b) along the c axis. The three S8 molecules in the asymmetric unit are denoted as (I) (atoms S1–S8), (II) (atoms S9–S16) and the disordered molecule (III) (atoms S17–S24, S17′–S24′).

Figure 3 Observed (circle), calculated (line) and difference/e.s.d profiles for monoclinic sulfur at 100 K. The vertical tick marks represent the calculated peak positions.

3.2. Order–disorder transition

3.2.1. Bragg–Williams model

The crystal structure of monoclinic sulfur showing the two pseudocentric orientations is illustrated in Fig. 2. It is the intermolecular interactions between neighbouring symmetry-related molecules which are responsible for the energy difference between the two orientations. Goldsmith & Strouse (1977) recognized that this dependency on the orientation of neighbouring molecules requires that the order–disorder transition be cooperative and used a simple Bragg–Williams model to characterize the transition using the limited information available.

The Bragg–Williams model of cooperative order–disorder transitions is typically applied in the description of transitions of alloys (see, for example, Muto & Takagi, 1955) and magnetic spin ½ systems (see, for example, Collins, 1989). It is a self-consistent model in which the energy of the system is expressed in terms of a long-range order parameter P, which corresponds to the difference in the fractional occupations of the two sites and an ordering energy U, which corresponds to the difference in energy between the two sites in the otherwise ordered structure. The temperature dependence of P based on the Bragg-Williams model is as follows

Fig. 4 shows a fit to the data using this expression. The model dictates that below the critical temperature, ln[(1 + P)/(1 − P)/P] versus 1/T be linear with a slope of U/R. The transition temperature, T_c, is defined simply as half the value of the ordering energy, U. As the critical temperature is approached, the data clearly deviate from the Bragg–Williams limit. This is not surprising since the model neglects the effects of short-range order and the variation of U owing to the temperature dependence of the lattice parameters. Thus, the refined value of U of 462 (4) K may be regarded simply as an indication of the magnitude of the ordering energy of the system. Goldsmith & Strouse (1977) derived a value of U of 553 K using a similar approach, which is comparable to the present study although based on just two measurements below the transition temperature. The temperature dependence of the observed disorder is best analysed in terms of mean-field behaviour, as described below.

Figure 4 The temperature dependence of the long-range order parameter, P, based on the Bragg–Williams model. The ordering energy, U = 462 (4) K, is determined by a least-squares fit to the points indicated (open circles).

3.2.2. Mean-field model

The X-ray single-crystal data recorded at only five different temperatures by Goldsmith & Strouse (1977) are not sufficient for quantitative analysis of the critical behaviour associated with the transition. However an indirect estimate of the order parameter was made by measuring the variation of intensity of the (50) reflection as a function of temperature. Least-squares fitting of 54 measurements between 178 and 196 K for T_c between 197 and 198 K gave a value for the critical exponent β of between 0.27 and 0.33. The standard deviations of the critical exponents were in the range 0.003–0.005, however, a precise determination of the critical temperature was not possible since near T_c both Bragg and critical scattering make significant contributions to the observed intensity. The refined site occupancies as determined from the present neutron powder diffraction study are shown in Fig. 5. Below the critical temperature the occupancy of the lower energy orientation (n_lower) can be fitted assuming power law behaviour of the form

Figure 5 Power-law behaviour of the refined values of the lower-energy orientation site occupancy: inset shows the range 150 < T < 200 K. The solid line is the least-squares fit to the points above 180 K. Saturation effects below 150 K are clearly seen.

The good quality of the fit is evident from Fig. 5 and gives a value for the critical exponent, β, of 0.28 (3) and T_c = 198.4 (3) K, which is in excellent agreement with the value of 198 K determined by heat-capacity measurements (Montgomery, 1974). A value of β in the region of 0.3 indicates short-range three-dimensional Ising Model behaviour indicative of dipole–dipole or, more likely, van der Waals interactions. Whilst the region just below T_c is well modelled, below 150 K saturation of the critical behaviour is clearly evident.

3.3. Lattice parameter variation

The refined values of the lattice parameters of monoclinic sulfur between 40 and 250 K are shown in Fig. 6. In each case the 198 K transition is evident and a smooth variation of the lattice parameters is observed across the region of the transition. There are a number of other notable features. In particular, the behaviour of the monoclinic β angle is anomalous and shows premonitory effects, apparently coincident with the saturation of the site occupancy, above 150 K. The most marked change in the unit-cell edges associated with the transition is along a and this is consistent with the molecular packing of the three molecules in the asymmetric unit. Along the a axis (Fig. 2) there is a sheet of S₈ type (I) molecules followed by a sheet of type (II) molecules; the sheets are rotated, relative to the axis, by −45 and +45°, respectively. The sheet of type (III) molecules is thus required to rotate in both senses, which is achieved through the disorder.

Figure 6 Variation of the lattice constants of β-sulfur with temperature: (a) a (circle), b (diamond) and c (square) lattice constants; (b) monoclinic β angle; (c) unit-cell volume. The unit-cell data from the long count-time runs at 40, 75, 100, 125, 150 and 175 K are fitted to a quadratic function shown by a solid line. The extrapolated fit above 175 K is shown by a dashed line.

Detailed analysis of the variation of lattice constants as a function of temperature can provide valuable information, especially with the high precision obtained by high-resolution neutron powder diffraction. A number of different functions, derived from the analysis of heat-capacity data, can be used to model the normal variation of the lattice parameters from which any residual variation can be obtained (David et al., 1993). However, such a detailed analysis has not been possible with the present data for the following reasons.

Inspection of the lattice-constant data shown in Fig. 6 outside the region of the phase transition shows discontinuities every 25 K. The 25 K breaks correspond to temperatures at which the data-collection time was longer, thus revealing the exceptionally slow attainment of thermal equilibrium of the sample. The unit-cell volume can be fitted successfully to a simple quadratic function (Fig. 6c) using the points corresponding to the long count-time data. Using the quadratic parameterization the expansion coefficient at 100 and 175 K is calculated as 5.50 × 10⁻⁶ and 4.45 × 10⁻⁶ K⁻¹, respectively. These values are significantly lower than those reported for orthorhombic sulfur in the α phase (23.5 × 10⁻⁶ K⁻¹ at 98 K, 112 × 10⁻⁶ K⁻¹ at 173 K) based on X-ray powder diffraction data (Wallis et al., 1986).

In a separate experiment, data were recorded on a second sample at fixed temperature (125 K) at intervals of 25 min, the sample having followed a temperature ramp from 100 K as in the first experiment. Variation of the lattice parameter as a function of time is shown in Fig. 7. An exponential increase with time was observed in all the lattice constant values that can be well fitted with an average characteristic time of τ = 117 (11) min. Selected values of thermal conductivity (Weast, 1986) for the sample-can component materials are listed in Table 3. The figures highlight the good insulating properties of elemental sulfur, which most likely accounts for the anomalous lattice constant behaviour. Nevertheless, the possibility of a relaxation of the structure on warming, especially in view of the intrinsic disorder and method of formation of the sample, cannot be discounted. These effects and the observed saturation effects of the critical behaviour and the likely premonitory effects observed in the lattice constants all require an improved experimental set-up before a more detailed analysis can be undertaken. A new design of sample can is required to circumvent the problems owing to the very low thermal conductivity of elemental sulfur and to allow better thermal contact between the powder, sensor and heater.

Figure 7 Variation of the b lattice constant of β-sulfur at 125 K as a function of time. The solid line is a least-squares fit to the data using the function b = b∞ − Δb*exp(−t/τ) to model the thermal equilibration of the sample. The characteristic time τ = 117 (11) min, b∞ = 10.7157 (1) Å and Δb = 0.0077 (4) Å.