Probing Defect States in Organic Polymers and Bulk Heterojunctions Using Surface Photovoltage Spectroscopy

Murthy, Lakshmi N.S.; Barrera, Diego; Xu, Liang; Gadh, Aakash; Cao, Fong Yi; Tseng, Cheng Chun; Cheng, Yen‐Ju; Hsu, Julia W. P.

doi:10.1021/acs.jpcc.9b01667

Cited by 6 publications

(10 citation statements)

References 41 publications

(69 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These deep defects states have been found in various types of organic solar cells originating from the energetic disorder of the materials and depending on factors like thermal annealing and prolonged illumination. [ 46–49 ] The recombination via these defects can be quantified by Shockley–Read–Hall recombination statistics. For trap states in the center of the bandgap, the recombination rate R SRH is given by

R_{normalSRH} (x, Φ) = \frac{n (x, Φ) p (x, Φ)}{τ_{normalp} n (x, Φ) + τ_{normaln} p (x, Φ)}

Here, n is the electron concentration, p is the hole concentration and τ n/p is the charge‐carrier lifetime.…”

Section: Theorymentioning

confidence: 99%

Understanding the Light‐Intensity Dependence of the Short‐Circuit Current of Organic Solar Cells

Hartnagel

Kirchartz

2020

Advcd Theory and Sims

View full text Add to dashboard Cite

In organic solar cells, bimolecular recombination is a key factor limiting the device performance and creating the need for characterization. Light‐intensity‐dependent short‐circuit current density measurements are a frequently used tool to qualitatively analyze bimolecular recombination in a device. When applying a 0D model, bimolecular recombination is expected to reduce the otherwise linear correlation of the short‐circuit current density Jsc and the light intensity Φ to a sublinear trend. It is shown by numerical simulations that the slope of the Jsc–Φ curve is affected by the recombination mechanism (direct or via traps), the spatial distribution of charge carriers and—in thick solar cells—by space charge effects. Only the combination of these effects allows proper explanation of the different cases, some of which cannot be explained in a simple 0D device model.

show abstract

R_{normalSRH} (x, Φ) = \frac{n (x, Φ) p (x, Φ)}{τ_{normalp} n (x, Φ) + τ_{normaln} p (x, Φ)}

Here, n is the electron concentration, p is the hole concentration and τ n/p is the charge‐carrier lifetime.…”

Section: Theorymentioning

confidence: 99%

Understanding the Light‐Intensity Dependence of the Short‐Circuit Current of Organic Solar Cells

Hartnagel

Kirchartz

2020

Advcd Theory and Sims

View full text Add to dashboard Cite

show abstract

“…SPS results of 0, 1, 5, and 10 wt % P3HT in PC 71 BM on PEDOT:PSS and ZnO are shown in Figure , parts c and d, respectively. The positive SPS in Figure c and negative SPS in Figure d indicate that holes transfer to PEDOT:PSS and electrons transfer to ZnO, respectively. − SPS of 0 wt % P3HT on PEDOT:PSS (open red circles in Figure c) and on ZnO (solid red circles in Figure d) have the same threshold at 1.75 eV (∼708 nm), which corresponds to the PC 71 BM optical band gap (red solid line in Figure a and red dashed line in Figure b) . With increasing P3HT concentration, the thresholds of spectra for both transport layers shift to lower energies, i.e., below the PC 71 BM band gap.…”

Section: Results and Discussionmentioning

confidence: 89%

“…With increasing P3HT concentration, the thresholds of spectra for both transport layers shift to lower energies, i.e., below the PC 71 BM band gap. While below band gap SPS signals can arise from charge transfer state absorption at donor–acceptor interfaces or midgap defect states, we believe it is due to charge transfer state absorption in these samples because this part of the SPS increases with the P3HT concentration, concomitant with increasing donor–acceptor interfacial area …”

Section: Results and Discussionmentioning

confidence: 92%

Device Architecture Study in Fullerene-Based Organic Photovoltaics

2020

Self Cite

View full text Add to dashboard Cite

The effect of device architecture on the performance of fullerene-based organic photovoltaic (OPV) devices has not been investigated so far. Here, we performed experimental and simulation studies on fullerenebased OPVs with conventional and inverted architectures to understand the contributions from photogeneration of carriers, carrier mobility, and vertical phase separation. Charge transfer from the active layer to the bottom transport layer was studied with surface photovoltage spectroscopy (SPS) measurements. Our results show that SPS signals and spectral shape depend strongly on donor concentration in the conventional architecture but not in the inverted architecture. Additionally, conventional OPV devices show better device current density−voltage performance than inverted devices, specifically producing higher short-circuit current density. Carrier generation alone cannot explain these results. X-ray photoelectron spectroscopy results show poly(3-hexylthiophene) (P3HT) enrichment on the air surface, which should have enhanced inverted device performance. Using a solar cell capacitor simulator, we studied the active layer thickness and carrier mobility effects and established the imbalance in carrier mobilities in these devices. This carrier mobility imbalance explains the architecture dependence in the SPS results, OPV device performance, and optimal active layer thickness, while total photogeneration rate and vertical phase separation predict results inconsistent with experimental observation.

show abstract

“…Many researchers have studied and calculated the DOS in organic materials and devices using various methods such as Deep Level Transient Spectroscopy (DLTS) [18] and Thermally Stimulated Current (TSC) [19]. In addition, capacitance characterization has been popularly employed to measure not only the DOS [20,21] but also the doping density [22][23][24], built-in potential [21,24], carrier mobility [25] and even thermal stability [26] in different materials. Capacitance spectroscopy involves measurement of the depletion capacitance Cj over a range of biases and frequencies and finding the DOS by analyzing the capacitance-voltage, C(V), and capacitancefrequency, C(f), plots.…”

Section: Introductionmentioning

confidence: 99%

“…Thenceforth, this method has been applied to organic devices as well, including OPVs. For instance, characterization of the defect states in NPB [29], determination of the interfacial and deep defect states in organic solar cells [20,[29][30][31] and investigation of trap states formed in different deposition rates [32] or traps resulted from degradation [21,[33][34][35] are all conducted using capacitance spectroscopy in organic devices. It is worth noting that the techniques used for inorganic semiconductors are applicable to organic materials only when fitting models and parameters are employed due to the differences in band gaps, resistances and carrier mobilities.…”

Section: Introductionmentioning

confidence: 99%

Characterization of Strain-induced Defects Density in Flexible Organic Photovoltaic Cells using Capacitance Spectroscopy

Salari

Naseri

Manesh

2020

J. Photopol. Sci. Technol.

View full text Add to dashboard Cite

Probing Defect States in Organic Polymers and Bulk Heterojunctions Using Surface Photovoltage Spectroscopy

Cited by 6 publications

References 41 publications

Understanding the Light‐Intensity Dependence of the Short‐Circuit Current of Organic Solar Cells

Understanding the Light‐Intensity Dependence of the Short‐Circuit Current of Organic Solar Cells

Device Architecture Study in Fullerene-Based Organic Photovoltaics

Characterization of Strain-induced Defects Density in Flexible Organic Photovoltaic Cells using Capacitance Spectroscopy

Contact Info

Product

Resources

About