Atomic order in synthetic end-member pargasite, NaCa2[6](Mg4Al)[4](Si6
Al2)O22(OH)2, has been examined by high-resolution H-1, Al-27, and Si-
29 magic-angle-spinning (MAS) NMR spectroscopy, with and without cross
-polarization, and by infrared spectroscopy. The spectra indicate that
Al occurs only on T1, M2, and M3 sites and are consistent with 1.5Mg
+ 0.5Al on M2 and 0.5Mg + 0.5Al on M3, [4]Al being ordered onto TI sit
es without Al avoidance (Al-O-Al linkages are allowed). Assuming rando
m mixing on sites in these ratios, we calculate a maximum configuratio
nal entropy for subordered synthetic pargasite of 38 J/(K.mol). This i
s much lower than the value of 56 J/(K.mol) indirectly estimated by We
strich and Holloway (1981) from their phase equilibrium study of the l
ow-pressure dehydration of synthetic pargasite. However, we show that
it is possible to reconcile their experimental results with our estima
te of the configurational entropy. Our results suggest that synthetic
pargasite is likely to be a good experimental analogue for natural par
gasite.