posted on 2018-05-30, 00:00authored byJon A. Bender, Emily K. Raulerson, Xin Li, Tamar Goldzak, Pan Xia, Troy Van Voorhis, Ming Lee Tang, Sean T. Roberts
Hybrid
organic:inorganic materials composed of semiconductor nanocrystals
functionalized with acene ligands have recently emerged as a promising
platform for photon upconversion. Infrared light absorbed by a nanocrystal
excites charge carriers that can pass to surface-bound acenes, forming
triplet excitons capable of fusing to produce visible radiation. To
fully realize this scheme, energy transfer between nanocrystals and
acenes must occur with high efficiency, yet the mechanism of this
process remains poorly understood. To improve our knowledge of the
fundamental steps involved in nanoparticle:acene energy transfer,
we used ultrafast transient absorption to investigate excited electronic
dynamics of PbS nanocrystals chemically functionalized with 6,13-bis(triisopropylsilylethynyl)pentacene
(TIPS-pentacene) ligands. We find photoexcitation of PbS does not
lead to direct triplet energy transfer to surface-bound TIPS-pentacene
molecules but rather to the formation of an intermediate state within
40 ps. This intermediate persists for ∼100 ns before evolving
to produce TIPS-pentacene triplet excitons. Analysis of transient
absorption lineshapes suggests this intermediate corresponds to charge
carriers localized at the PbS nanocrystal surface. This hypothesis
is supported by constrained DFT calculations that find a large number
of spin-triplet states at PbS NC surfaces. Though some of these states
can facilitate triplet transfer, others serve as traps that hinder
it. Our results highlight that nanocrystal surfaces play an active
role in mediating energy transfer to bound acene ligands and must
be considered when optimizing composite NC-based materials for photon
upconversion, photocatalysis, and other optoelectronic applications.