8 research outputs found
Time-Resolved Infrared Spectroscopy Directly Probes Free and Trapped Carriers in Organo-Halide Perovskites
Free carrier dynamics in organo-halide
perovskites can directly reveal information about their carrier lifetimes
and indirectly reveal information about trap state distributions,
both of which are critical to improving their performance and stability.
Time-resolved photoluminescence (TRPL) spectroscopy is commonly used
to probe carrier dynamics in these materials, but the technique is
only sensitive to radiative decay pathways and may not reveal the
true carrier dynamics. We used time-resolved infrared (TRIR) spectroscopy
in comparison to TRPL to show that photogenerated charges relax into
free carrier states with lower radiative recombination probabilities,
which complicates TRPL measurements. Furthermore, we showed that trapped
carriers exhibit distinct mid-infrared absorptions that can be uniquely
probed using TRIR spectroscopy. We used the technique to demonstrate
the first simultaneous measurements of trapped and free carriers in
organo-halide perovskites, which opens new opportunities to clarify
how charge trapping and surface passivation influence the optoelectronic
properties of these materials
Approaching Bulk Carrier Dynamics in Organo-Halide Perovskite Nanocrystalline Films by Surface Passivation
The electronic properties of organo-halide
perovskite absorbers
described in the literature have been closely associated with their
morphologies and processing conditions. However, the underlying origins
of this dependence remain unclear. A combination of inorganic synthesis,
surface chemistry, and time-resolved photoluminescence spectroscopy
was used to show that charge recombination centers in organo-halide
perovskites are almost exclusively localized on the surfaces of the
crystals rather than in the bulk. Passivation of these surface defects
causes average charge carrier lifetimes in nanocrystalline thin films
to approach the bulk limit reported for single-crystal organo-halide
perovskites. These findings indicate that the charge carrier lifetimes
of perovskites are correlated with their thin-film processing conditions
and morphologies through the influence these have on the surface chemistry
of the nanocrystals. Therefore, surface passivation may provide a
means to decouple the electronic properties of organo-halide perovskites
from their thin-film processing conditions and corresponding morphologies
Molecular Origins of Defects in Organohalide Perovskites and Their Influence on Charge Carrier Dynamics
The
chemical origins of charge recombination centers in lead-based
organohalide perovskites were investigated using a combination of
quantitative solution chemistry, X-ray diffraction, and time-resolved
photoluminescence spectroscopy. We explored the complex, concentration-dependent
solution equilibria among iodoplumbate coordination complexes that
have been implicated as potential midgap states in organohalide perovskites.
High concentrations of PbI<sub>2</sub>, PbI<sub>3</sub><sup>–</sup>, and PbI<sub>4</sub><sup>2–</sup> were found in precursor
solutions that match those used to deposit perovskite films for solar
cell applications. We found that the concentration of tetraiodoplumbate
PbI<sub>4</sub><sup>2–</sup> is uniquely correlated with the
density of charge recombination centers found in the final perovskite
films regardless of the lead precursor used to cast the films. However,
mixed-halide perovskites commonly referred to as CH<sub>3</sub>NH<sub>3</sub>PbI<sub>3–<i>x</i></sub>Cl<sub><i>x</i></sub> suppressed the formation of PbI<sub>4</sub><sup>2–</sup> in comparison to perovskites that included only iodide, which is
consistent with the longer charge carrier lifetimes reported in mixed-halide
perovskites. These findings bring a molecular-level view to the chemical
origins of charge recombination centers that provides a fundamental
basis from which to understand the reported improvement in uniformity
of perovskite films and devices deposited using sequential methods.
These findings also suggest new approaches to control the formation
of defect precursors during the deposition of organohalide perovskite
absorbers
Electron–Phonon Coupling and Resonant Relaxation from 1D and 1P States in PbS Quantum Dots
Observations
of the hot-phonon bottleneck, which is predicted to
slow the rate of hot carrier cooling in quantum confined nanocrystals,
have been limited to date for reasons that are not fully understood.
We used time-resolved infrared spectroscopy to directly measure higher
energy intraband transitions in PbS colloidal quantum dots. Direct
measurements of these intraband transitions permitted detailed analysis
of the electronic overlap of the quantum confined states that may
influence their relaxation processes. In smaller PbS nanocrystals,
where the hot-phonon bottleneck is expected to be most pronounced,
we found that relaxation of parity selection rules combined with stronger
electron–phonon coupling led to greater spectral overlap of
transitions among the quantum confined states. This created pathways
for fast energy transfer and relaxation that may bypass the predicted
hot-phonon bottleneck. In contrast, larger, but still quantum confined
nanocrystals did not exhibit such relaxation of the parity selection
rules and possessed narrower intraband states. These observations
were consistent with slower relaxation dynamics that have been measured
in larger quantum confined systems. These findings indicated that,
at small radii, electron–phonon interactions overcome the advantageous
increase in energetic separation of the electronic states for PbS
quantum dots. Selection of appropriately sized quantum dots, which
minimize spectral broadening due to electron–phonon interactions
while maximizing electronic state separation, is necessary to observe
the hot-phonon bottleneck. Such optimization may provide a framework
for achieving efficient hot carrier collection and multiple exciton
generation
Dynamic Exchange During Triplet Transport in Nanocrystalline TIPS-Pentacene Films
The multiplication of excitons in
organic semiconductors via singlet
fission offers the potential for photovoltaic cells that exceed the
Shockley–Quiesser limit for single-junction devices. To fully
utilize the potential of singlet fission sensitizers in devices, it
is necessary to understand and control the diffusion of the resultant
triplet excitons. In this work, a new processing method is reported
to systematically tune the intermolecular order and crystalline structure
in films of a model singlet fission chromophore, 6,13-bisÂ(triisopropylsilylethynyl)
pentacene (TIPS-Pn), without the need for chemical modifications.
A combination of transient absorption spectroscopy and quantitative
materials characterization enabled a detailed examination of the distance-
and time-dependence of triplet exciton diffusion following singlet
fission in these nanocrystalline TIPS-Pn films. Triplet–triplet
annihilation rate constants were found to be representative of the
weighted average of crystalline and amorphous phases in TIPS-Pn films
comprising a mixture of phases. Adopting a diffusion model used to
describe triplet–triplet annihilation, the triplet diffusion
lengths for nanocrystalline and amorphous films of TIPS-Pn were estimated
to be ∼75 and ∼14 nm, respectively. Importantly, the
presence of even a small fraction (<10%) of the amorphous phase
in the TIPS-Pn films greatly decreased the ultimate triplet diffusion
length, suggesting that pure crystalline materials may be essential
to efficiently harvest multiplied triplets even when singlet fission
occurs on ultrafast time scales
Molecular Rectification in Conjugated Block Copolymer Photovoltaics
We
investigate the influence that covalent linkage of electron
donating and accepting blocks in high performance fully conjugated
block copolymer photovoltaics has on charge generation and recombination
using ultrafast mid-infrared transient absorption spectroscopy. We
show that block copolymer architectures containing a conjugated bridge
between the donor and acceptor groups can be used to form ordered
mesoscale morphologies that lead to improved photovoltaic performance
without enhancing charge recombination. Judicious placement of an
electron-rich moiety in the electron accepting block of the block
copolymer creates a donor–bridge–acceptor architecture
that slows intramolecular charge transfer across the covalent linkage.
Charge recombination in such donor–bridge–acceptor block
copolymer films proceeds at the same rate as it does in their corresponding
homopolymer blends for which the donor and acceptor blocks are not
covalently linked, indicating that recombination is dominated by intermolecular
charge transfer in both systems. The electrical and morphological
properties of functional block copolymer photovoltaics are correlated
with their underlying charge generation and recombination kinetics,
permitting us to identify key design rules for further improvements
in the power conversion efficiency of fully conjugated block copolymer
solar cells
Observation of Two Triplet-Pair Intermediates in Singlet Exciton Fission
Singlet fission is an excitation
multiplication process in molecular
systems that can circumvent energy losses and significantly boost
solar cell efficiencies; however, the nature of a critical intermediate
that enables singlet fission and details of its evolution into multiple
product excitations remain obscure. We resolve the initial sequence
of events comprising the fission of a singlet exciton in solids of
pentacene derivatives using femtosecond transient absorption spectroscopy.
We propose a three-step model of singlet fission that includes two
triplet-pair intermediates and show how transient spectroscopy can
distinguish initially interacting triplet pairs from those that are
spatially separated and noninteracting. We find that the interconversion
of these two triplet-pair intermediates is limited by the rate of
triplet transfer. These results clearly highlight the classical kinetic
model of singlet fission and expose subtle details that promise to
aid in resolving problems associated with triplet extraction
Direct Observation of Correlated Triplet Pair Dynamics during Singlet Fission Using Ultrafast Mid-IR Spectroscopy
Singlet fission is
an exciton multiplication mechanism in organic
materials whereby high energy singlet excitons can be converted into
two triplet excitons with near unity quantum yields. As new singlet
fission sensitizers are developed with properties tailored to specific
applications, there is an increasing need for design rules to understand
how the molecular structure and crystal packing arrangements influence
the rate and yield with which spin-correlated intermediates known
as correlated triplet pairs can be successfully separatedî—¸a
prerequisite for harvesting the multiplied triplets. Toward this end,
we identify new electronic transitions in the mid-infrared spectral
range that are distinct for both initially excited singlet states
and correlated triplet pair intermediate states using ultrafast mid-infrared
transient absorption spectroscopy of crystalline films of 6,13-bisÂ(triisopropylsilylethynyl)
pentacene (TIPS-Pn). We show that the dissociation dynamics of the
intermediates can be measured through the time evolution of the mid-infrared
transitions. Combining the mid-infrared with visible transient absorption
and photoluminescence methods, we track the dynamics of the relevant
electronic states through their unique electronic signatures and find
that complete dissociation of the intermediate states to form independent
triplet excitons occurs on time scales ranging from 100 ps to 1 ns.
Our findings reveal that relaxation processes competing with triplet
harvesting or charge transfer may need to be controlled on time scales
that are orders of magnitude longer than previously believed even
in systems like TIPS-Pn where the primary singlet fission events occur
on the sub-picosecond time scale