TY - JOUR
T1 - Nanoarchitecture through Strained Molecules
T2 - Cubane-Derived Scaffolds and the Smallest Carbon Nanothreads
AU - Huang, Haw Tyng
AU - Zhu, Li
AU - Ward, Matthew D.
AU - Wang, Tao
AU - Chen, Bo
AU - Chaloux, Brian L.
AU - Wang, Qianqian
AU - Biswas, Arani
AU - Gray, Jennifer L.
AU - Kuei, Brooke
AU - Cody, George D.
AU - Epshteyn, Albert
AU - Crespi, Vincent H.
AU - Badding, John V.
AU - Strobel, Timothy A.
N1 - Publisher Copyright:
©
PY - 2020/10/21
Y1 - 2020/10/21
N2 - Relative to the rich library of small-molecule organics, few examples of ordered extended (i.e., nonmolecular) hydrocarbon networks are known. In particular, sp3 bonded, diamond-like materials represent appealing targets because of their desirable mechanical, thermal, and optical properties. While many covalent organic frameworks (COFs) - extended, covalently bonded, and porous structures - have been realized through molecular architecture with exceptional control, the design and synthesis of dense, covalent extended solids has been a longstanding challenge. Here we report the preparation of a sp3-bonded, low-dimensional hydrocarbon synthesized via high-pressure, solid-state diradical polymerization of cubane (C8H8), which is a saturated, but immensely strained, cage-like molecule. Experimental measurements show that the obtained product is crystalline with three-dimensional order that appears to largely preserve the basic structural topology of the cubane molecular precursor and exhibits high hardness (comparable to fused quartz) and thermal stability up to 300 °C. Among the plausible theoretical candidate structures, one-dimensional carbon scaffolds comprising six- and four-membered rings that pack within a pseudosquare lattice provide the best agreement with experimental data. These diamond-like molecular rods with extraordinarily small thickness are among the smallest members in the carbon nanothread family, and calculations indicate one of the stiffest one-dimensional systems known. These results present opportunities for the synthesis of purely sp3-bonded extended solids formed through the strain release of saturated molecules, as opposed to only unsaturated precursors.
AB - Relative to the rich library of small-molecule organics, few examples of ordered extended (i.e., nonmolecular) hydrocarbon networks are known. In particular, sp3 bonded, diamond-like materials represent appealing targets because of their desirable mechanical, thermal, and optical properties. While many covalent organic frameworks (COFs) - extended, covalently bonded, and porous structures - have been realized through molecular architecture with exceptional control, the design and synthesis of dense, covalent extended solids has been a longstanding challenge. Here we report the preparation of a sp3-bonded, low-dimensional hydrocarbon synthesized via high-pressure, solid-state diradical polymerization of cubane (C8H8), which is a saturated, but immensely strained, cage-like molecule. Experimental measurements show that the obtained product is crystalline with three-dimensional order that appears to largely preserve the basic structural topology of the cubane molecular precursor and exhibits high hardness (comparable to fused quartz) and thermal stability up to 300 °C. Among the plausible theoretical candidate structures, one-dimensional carbon scaffolds comprising six- and four-membered rings that pack within a pseudosquare lattice provide the best agreement with experimental data. These diamond-like molecular rods with extraordinarily small thickness are among the smallest members in the carbon nanothread family, and calculations indicate one of the stiffest one-dimensional systems known. These results present opportunities for the synthesis of purely sp3-bonded extended solids formed through the strain release of saturated molecules, as opposed to only unsaturated precursors.
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U2 - 10.1021/jacs.9b12352
DO - 10.1021/jacs.9b12352
M3 - Article
C2 - 31961671
AN - SCOPUS:85094219606
SN - 0002-7863
VL - 142
SP - 17944
EP - 17955
JO - Journal of the American Chemical Society
JF - Journal of the American Chemical Society
IS - 42
ER -