R adioactive iodine (I 2 containing 129 I and/or 131 I) is a volatile solid that, when accidently released as a gas in nuclear power plant explosions, poses a serious threat to the public and the environment. 1−3 If ingested, it can cause acute tissue damage and cancer. A fast and efficient method of its sequestration would be useful as a countermeasure to accidental release, as well as a means to facilitate nuclear waste storage and fuel recycling. Standard methods for I 2 capture rely on inorganic composite adsorbents such as silver-based zeolites and aerogels. 4,5 These materials are chemically and hydrothermally stable but many have low I 2 adsorption capacity due to limited accessible surface area. Consequently, researchers are developing alternative absorbents that have higher I 2 affinity and loading capacity and that cost less. Also, it is important to note that during and after a loss-of-coolant accident at a nuclear power plant, equipment and facilities may be at elevated temperatures, 3 so any new materials designed for I 2 capture must also be thermally stable. 6 Currently, several types of novel adsorbents are being investigated. These include inorganic materials, 7 − 9 crystalline metal−organic frameworks (MOFs), 1,10−13 porous organic frameworks (POFs), 14−18 and porous organic polymers (POPs). 19−22 Inorganic materials often have low I 2 loading capacity, and MOFs tend to be unstable to moisture and water. POFs and POPs, on the other hand, often exhibit high loading capacity for small molecules and are generally stable to moisture and water. Also, their strong covalent bonds afford high thermal and chemical stability, and their constituent light elements add gravimetric advantage. POFs and POPs do, however, occasionally suffer from slow uptake kinetics, so the development of new porous adsorbents in particular organic adsorbents that possess high I 2 loading capacity and that also exhibit fast I 2 uptake kinetics, remains a significant challenge.Recently, we reported the synthesis of a calix[4]arene-based porous covalent polymer and described its use as an efficient adsorbent for water purification. 23 With these positive results and the known advantages of POPs as adsorbents, we decided to design a series of hyper-cross-linked π-bond-rich porous covalent polycalix[4]arenes, CalP2, CalP3, and CalP4, for I 2 adsorption. We enriched the polymers with arenes and alkynes, which are known to endow materials with high surface area 24,25 and high I 2 affinity. 11,26 Furthermore, because the phenols of calix [4]arenes are easily lithiated 27−30 and because alkali metal
