Revealing the Dynamics of Charge Carriers in Polymer:Fullerene Blends Using Photoinduced Time-Resolved Microwave Conductivity

Savenije, Tom J.; Ferguson, Andrew J.; Kopidakis, Nikos; Rumbles, Garry

doi:10.1021/jp406706u

Cited by 223 publications

(336 citation statements)

References 137 publications

(243 reference statements)

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“…[17,[39][40][41][42] In short, the BiVO4 films are excited with a nanosecond laser pulse and the light-induced change in the reflected microwave power, which is sensitive to the presence of mobile carriers, is monitored (see Experimental Methods for more details). The TRMC signal can then be expressed as the product of the absorbance-normalized quantum yield () and the combined mobility of the charge carriers (∑μ, sum of the electron and hole mobilities).…”

Section: Resultsmentioning

confidence: 99%

“…Assuming that the internal quantum yield of electron-hole generation approaches 100% and no charge carrier recombination has taken place within the response time of the setup, the carrier mobility () and the carrier lifetime () can be obtained from the peak and the decay of the TRMC signal, respectively. [17,40] [43] , the individual electron (e) and hole mobility (h) of each films can be calculated ( Table 1). The carrier lifetime, however, shows a much larger change and increases from 43 ns to 109 ns.…”

Section: Resultsmentioning

confidence: 99%

“…[39,40] During the measurements, a change in the microwave power reflected by the cavity upon sample excitation by 6 ns (full-width at halfmaximum) pulses of a frequency-tripled Q-switched Nd:YAG laser at a wavelength of 355 nm (10 Hz repetition rate), ΔP/P, was monitored and correlated to the photoinduced change in the conductance of the sample, ΔG, by…”

Section: Time-resolved Spectroscopy: Time-resolved Microwave Conductimentioning

confidence: 99%

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Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Jang

Friedrich

Müller

et al. 2017

Advanced Energy Materials

114

161

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Widespread application of solar water splitting for energy conversion is largely dependent on the progress in developing not only efficient, but also cheap and scalable photoelectrodes. Metal oxides, which can be deposited with scalable techniques and are relatively cheap, are particularly interesting, but high efficiency is still hindered by the poor carrier transport properties (i.e., carrier mobility and lifetime). In this paper, a mild hydrogen treatment is introduced to bismuth vanadate (BiVO4), which is one of the most promising metal oxide photoelectrodes, as a method to overcome the carrier transport limitations. Timeresolved microwave and terahertz conductivity measurements reveal more than two-fold enhancement of the carrier lifetime for the hydrogen-treated BiVO4, without significantly affecting the carrier mobility. This is in contrast to the case of tungsten-doped BiVO4, although hydrogen is also shown to be a donor type dopant in BiVO4. The enhancement in carrier lifetime is found to be caused by significant reduction of trap-assisted recombination, either via passivation of deep trap states or reduction of trap state density, which can be related to vanadium anti-site on bismuth or vanadium interstitials according to density functional theory calculations. Overall, these findings provide further insights on the interplay between defect modulation and carrier transport in metal oxide photoelectrodes, which will benefit the development of low-cost, highly-efficient solar energy conversion devices.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Time-resolved Spectroscopy: Time-resolved Microwave Conductimentioning

confidence: 99%

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Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Jang

Friedrich

Müller

et al. 2017

Advanced Energy Materials

114

161

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“…The recombination from the chargeseparated (CS) state back to the CT-state with rate constant r is assumed to be described by [68]. Similarly, the mobilities on a nm length scale obtained from Transient Microwave Conductivity measurements is typically 1, 2 orders of magnitude higher than the bulk mobility [69]. Possible reasons are that charges have to cross less or no domain boundaries in the nm regime, or charge delocalization over the polymer chain or several molecules.…”

Section: Ii64 Onsager-braun Theorymentioning

confidence: 99%

“…Charge generation is often studied using transient absorption spectroscopy (TAS) [174], transient microwave conductivity (TRMC) [69] or with the relatively new Time-Delayed Collection Field (TDCF) technique [90,91]. TAS allows the assessment and quantification of the initial population of exciton and charge transfer states prior to recombination of free carriers and TRMC measures the product of the generation yield and the sum of the "local" charge carrier mobilities.…”

Section: Introductionmentioning

confidence: 99%

Charge Generation and Transport Phenomena in Disordered Organic Semiconductors and Photovoltaic Diodes

Stolterfoht¹

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Organic semiconductors are of great interest for a broad range of optoelectronic applications due to their solution processability, chemical tunability and mechanical flexibility. In contrast to traditional banded semiconductors, organic semiconductors are intrinsically disordered systems and exhibit therefore much lower charge carrier mobilities. They are also low dielectric constant systems -as such, their photo-excitations are excitonic at room temperature with the electron-hole pair remaining Coulombically-bound. Blending organic semiconductors with differing electron affinities, so-called electron acceptors and donors, creates molecular heterojunctions which deliver the required driving force for exciton separation. These so-called bulk heterojunctions (BHJs) are the dominant architecture for creating organic photovoltaic cells and photodetectors. However, not least because of an incomplete understanding of the underlying physical mechanism that control the conversion of photons to free charges, and the subsequent extraction of these free charges to the electrodes, these organic optoelectronic systems still lag behind their inorganic counterparts.Motivated by these factors, the work described in this thesis advances the fundamental understanding of the loss mechanisms associated with charge photogeneration and charge transport phenomena in BHJ organic solar cells and photodetectors, and presents new experimental methodologies to study these processes. The transport of photogenerated charge carriers in the percolated donor: acceptor pathways towards the extracting electrodes has been studied in-depth via existing and newly developed transient photovoltage and steady-state characterization techniques. A simple but conclusive understanding has been developed which allows for minimization of the detrimental recombination of free charge carriers for given device parameters such as film thickness, applied voltage and the mobility of the slower carrier type (either electrons or holes). The models' predictions have been experimentally validated for many different (> 25) BHJ solar cell systems. Inspired by the need to selectively optimize the processes which control the photocurrent output of the cell, such a charge photogeneration and extraction, a technique to quantify and disentangle both efficiencies has been developed as a next step. Corroborated by transient absorption spectroscopy, the dynamics of the photocarrier generation process was examined. The results suggest that the so-called charge-transfer state (CTS) separation limits the conversion of photons to free charges and the photocurrent output from short-circuit to the maximum power point, strongly depending on the slower carrier ii mobility. These findings were explained by the ability of the slower carriers to leave the donor: acceptor interface via 1) a high enough mobility, 2) a sufficiently large domain size, and 3) enough conduction pathways (entropy). This work also shows that the dynamics of charge extraction and CTS dissociation are simi...

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Semiconducting Metal Oxides for Photocatalytic and Gas Sensing Applications

Malik

Tomer²,

Chaudhary³

et al. 2020

Metal Oxide Nanocomposites

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Revealing the Dynamics of Charge Carriers in Polymer:Fullerene Blends Using Photoinduced Time-Resolved Microwave Conductivity

Cited by 223 publications

References 137 publications

Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Charge Generation and Transport Phenomena in Disordered Organic Semiconductors and Photovoltaic Diodes

Semiconducting Metal Oxides for Photocatalytic and Gas Sensing Applications

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