Two-dimensional (2D) materials provide tremendous opportunities for next-generation energy storage technologies. We theoretically propose 2D group-IV oxides (-, and-CXO, X = Si/Ge). Among them,-CXO monolayers, composed of the C-O-X skeleton of silyl (germyl) methyl ether molecules, are the most stable phase.-CXO possess robust dynamical, mechanical, and thermal stabilities. Remarkably,-CGeO has an unusual negative Poisson's ratio (NPR). However,-CSiO displays a bidirectional half-auxeticity, different from all the already known NPR behaviors. The intrinsic moderate direct-band-gap, high carrier mobility, and superior optical absorption of-CXO make them attractive for optoelectronics applications. A series of-CXO-based excitonic solar cells can achieve high power conversion efficiencies. Besides,-CXO monolayers are promising anode materials for sodium- and potassium-ion batteries, exhibiting not only the high specific capacity (532-1433 mA h g) but also low diffusion barrier and open-circuit voltage. In particular, the specific capacity of K on-CSiO exhibits one of the highest values ever recorded in 2D materials. The multifunctionality renders-CXO promising candidates for nanomechanics, nanoelectronics, and nano-optics.
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