AI Article Synopsis
- Cesium bismuth bromide (CBB) is a layered perovskite known for its potential in optoelectronic applications, but its weak photoluminescence (PL) has limited its use as a light source.
- The study explores metal intercalation, specifically introducing silver (Ag) into CBB, to enhance its room-temperature PL through both experimental methods and computational models.
- The research shows that intercalated Ag creates polaronic trap states that facilitate the formation of bound interlayer excitons (BIE), resulting in significantly improved PL characteristics, including a bright emission at 600 nm with a long decay time of 38.6 ns.
Article Abstract
Cesium bismuth bromide (CBB) has garnered considerable attention as a vacancy-ordered layered perovskite with notable optoelectronic applications. However, its use as a light source has been limited due to its weak photoluminescence (PL). Here, we demonstrate metal intercalation as a novel approach to engineer the room-temperature PL of CBB using experimental and computational methods. Ag, when introduced into CBB, occupies vacant sites in the spacer region, forming octahedral coordination with surrounding Br anions. First-principles density functional theory calculations reveal that intercalated Ag represents the most energetically stable Ag species compared to other potential forms, such as Ag substituting Bi. The intercalated Ag forms a strong polaronic trap state close to the conduction band minimum and quickly captures photoexcited electrons with holes remaining in CBB layers, leading to the formation of a bound interlayer exciton, or BIE. The radiative recombination of this BIE exhibits bright room-temperature PL at 600 nm and a decay time of 38.6 ns, 35 times greater than that of free excitons, originating from the spatial separation of photocarriers by half a unit cell separation distance. The BIE as a new form of interlayer exciton is expected to inspire new research directions for vacancy-ordered perovskites.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11273344 | PMC |
| http://dx.doi.org/10.1021/jacs.4c03191 | DOI Listing |
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