Traditional
semiconductor quantum dots of groups II–VI
are
key ingredients of next-generation display technology. Yet, the majority
of them contain toxic heavy-metal elements, thus calling for alternative
light-emitting materials. Herein, we have explored three novel categories
of multicomponent compounds, namely, tetragonal II-III2-VI4 porous ternary compounds, cubic I2-II3-VI4 ternary compounds, and cubic I-II-III3-V4 quaternary compounds. This is achieved by judicious
introduction of a “super atom” perspective and concurrently
varying the solid-state lattice packing of involved super atoms or
the population of surrounding counter cations. Based on first-principles
calculations of 392 candidate materials with designed crystal structures,
53 highly stable materials have been screened. Strikingly, 34 of them
are direct-bandgap semiconductors with emitting wavelengths covering
the near-infrared and visible-light regions. This work provides a
comprehensive database of highly efficient light-emitting materials,
which may be of interest for a broad field of optoelectronic applications