Sulfur dots are a new class of recently developed nonmetallic
luminescent
nanomaterials with various potential applications. Herein, we synthesized
sulfur dots using a mild chemical etching method and then modified
the structural features of the as-synthesized sulfur dots using a
slow and defined solvent-assisted aggregation process. This increases
the particle size and overall crystallinity along with the modifications
of the surface functional groups, which eventually show a new emission
band at longer wavelengths. Detailed photophysical and temperature-dependent
luminescence studies confirmed that the new emissive state evolves
due to interparticle interactions in the excited state. Furthermore,
the occurrence of a new emissive state in a longer-wavelength region
helped reduce the energy gap between the lowest excited singlet state
and the lowest excited triplet state in modified sulfur dots, resulting
in an aqueous stable room-temperature phosphorescence/afterglow emission
through efficient intersystem crossing. This typical efficacious afterglow
emission directly shows the potential applicability of structurally
modified sulfur dots in encryption devices and can also be potentially
effective in light emitting diodes (LED) and sensing devices.