Intercalation chemistry and thermal characteristics of layered double hydroxides possessing organic phosphonates and sulfonates

Intercalation of 2-hydroxyethanesulfonate ( 2-heS ) and 3-hydroxy-1-propanesulfonate ( 3-hpS ) into layered Mg-Al double hydroxides (Mg-Al LDHs) allows delamination of layers in water and enables the synthesis of high-surface-area oxides through non-oxidative thermal decomposition. To investigate the roles of anionic heads and hydroxyl tails in these organic sulfonates, 2-hydroxyethanephosphonate ( 2-heP ) and 1,3-propanedisulfonate ( 1,3-pDS ) were tested as analogs of hydroxyalkylsulfonates, and the thermal characteristics of the resultant LDHs were investigated. Exchange of interlayer CO 3 2− with 2-heP proceeds similarly to 2-heS , causing the same degree of interlayer expansion. However, the resultant LDH resists swelling and delamination in water, demonstrating the distinct property enabled by the -SO 3 − group. Although LDH possessing 1,3-pDS intercalants seems to resist delamination because of the lack of hydroxyl groups, its thermal characteristics resemble those of its 3-hpS counterpart, demonstrating the crucial role of alkyl sulfonate groups to allow the formation of enhanced microporous structures through non-oxidative thermal treatments. Our results show further that even a partial exchange of CO 3 2− by 3-hpS , corresponding to 0.05 equivalents relative to the exchangeable Al sites, triggers unique thermal characteristics observed for LDH-sulfonates. The distinct roles of organic sulfonates that enable delamination in water and formation of microporous structures via thermal activation are elucidated.