Role of Polymeric Metal Nucleation Inducers in Fabricating Large‐Area, Flexible, and Transparent Electrodes for Printable Electronics

Jeong, Soyeong; Jung, Sungyong; Kang, Hongkyu; Lee, Dasol; Choi, Sang‐Bae; Kim, Seok; Park, Byoungwook; Yu, Kilho; Lee, Jinho; Lee, Kwanghee

doi:10.1002/adfm.201606842

Cited by 46 publications

(34 citation statements)

References 51 publications

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“…The pink layer denotes the CBL composed of ZrAcac, PEI, or ZrAcac/PEI (Figure b), which was spin‐coated on the underlying PCBM film using the optimal concentration of ZrAcac (1 mg mL −1 ) and PEI (0.1 mg mL −1 ) solutions with isopropanol (IPA) as solvent . The main motivation for the use of PEI is that this polymer molecule acts as a good substrate for deposition of smooth silver films . The function of CBL at the cathode interface is clearly demonstrated in the current density–bias voltage ( J–V ) curves in reverse scan of the devices tested under a simulated AM1.5G sunlight (100 mW cm −2 ) (Figure c).…”

Section: Summary Of the Photovoltaic Performances Of The Inverted Plamentioning

confidence: 99%

“…The silver grains in both kinds of films are well connected with each other (Figure f,h), which contribute to the high conductivity and transmittance shown in Figure a,c. Different from PCBM and ZrAcac, the abundant amine groups in the backbone of PEI molecules are inclined to uniformly localize Ag adatoms by the AgN bonds and hence to offer the low energy nucleation sites for the growth of continuous silver films …”

Section: Summary Of the Photovoltaic Performances Of The Inverted Plamentioning

confidence: 99%

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Supersmooth Ta₂O₅/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells

Ying

Chen

Lin

et al. 2018

Advanced Optical Materials

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Semitransparent solar cells have attractedincreasing attention because of their gen eral applications in smart windows for automobiles and buildings, tandem solar cells, electronic chargers, and so on. [1][2][3] Due to facile solution processing and high record efficiency of 23.3% in nontrans parent devices, [4][5][6][7][8] organic-inorganic lead halide perovskite solar cells (PSCs) are excellent candidates for semitransparent devices, since the efficiency of semi transparent devices is inevitably lower compared to devices with fully reflective electrodes. In a typical semitransparent PSC structure, the rear transparent elec trode (RTE) is one of the key components because it is deposited on the underlying soft active layer. So far, various trans parent conductive electrodes have been investigated as RTEs for semitransparent PSCs, such as transparent conductive oxides, [9] conductive polymers, [10] carbon nanotubes, [11] graphene, [12] metal nano wires, [13,14] metal mesh, [15] ultrathin metal films, [16] and so on. Among them, the ultrathin metal films with the thickness below 10 nm have the advantage in the facile deposition pro cess, as well as low sheet resistance, high optical transmittance, and good adhesive strength comparable to other alternatives.The ultrathin silver film exhibits great potential as a low cost, effective RTE material in semitransparent devices. [17][18][19][20] However, there are still some challenges for the application of ultrathin silver films in high performance semitransparent PSCs. First, the 3D growth mode of silver results in separate islands for film thickness below 10 nm, [21] which leads not only low conductivity due to disconnect between parts of the electrode, [22] but also optical loss due to surface plasmonic effect. [23] The smooth and crossconnecting surface morphology of ultrathin silver film is necessary to realize high performance semitransparent PSCs. Second, the band level offset at the silver electrode interface always affects the carrier transport and collection, [24] especially for ultrathin silver electrodes. [25] The chemical interaction at the interface also determines the adhesive strength between silver film and the underlayer, as well as electrode degradation by halide anions and ambientAlthough it exhibits great potential as the rear transparent electrode (RTE) material in semitransparent devices, the ultrathin silver film still faces some significant challenges, such as surface plasmonic effect induced optical loss, the conflict between conductivity and transmittance, and the band level mismatch at device interfaces. In this work, a novel combination of ZrAcac/PEI/Ag/Ta 2 O 5 is employed as the RTE of the semitransparent perovskite solar cells in the planar inverted device structure of "indium-tin-oxide (ITO)/NiO x /MAPbI 3 /PC 61 BM/ZrAcac/PEI/Ag/Ta 2 O 5 ." Interface engineering with ZrAcac/PEI enables a significant increase in the device efficiency for 100 nm thick Ag electrode, from 17.48% to 18.84%. Ultrathin 9 nm Ag film coated on polyetherimide (PE...

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Section: Summary Of the Photovoltaic Performances Of The Inverted Plamentioning

confidence: 99%

Section: Summary Of the Photovoltaic Performances Of The Inverted Plamentioning

confidence: 99%

Supersmooth Ta₂O₅/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells

Ying

Chen

Lin

et al. 2018

Advanced Optical Materials

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“…1c(i) and (ii)), or PET modified with an ultra-thin layer of PEI (polyethylenimine) the latter of which is known to serve as an effective seed layer for evaporated Ag film. 16 The substrate was then exposed to Ag vapour in a vacuum evaporator until a total thickness of 90 nm was deposited onto PFDMA-free regions and the adjacent quartz crystal microbalance ( Fig. 1c(iii)).…”

Section: Introductionmentioning

confidence: 99%

Embedded-grid silver transparent electrodes fabricated by selective metal condensation

et al. 2020

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“…This is because the structures of Ag films so deposited are still far from being ideal and consist of rough surfaces with high densities of voids and grain boundaries when the film thickness is < 6 nm. Recently, it was demonstrated that the density of the sites that are chemically reactive with the evaporated Ag atoms could be determined by the concentration of functional amine groups on the NISL surface (Jeong et al, 2017). However, the adsorbed amine groups in the PEI NISL is always limited by the poor electrostatic attraction to the weakly charged substrate as well as the strong repulsion between the PEI chain entanglements (Hoogeveen et al, 1996;Li et al, 1997;Dobrynin et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

Metal-Enhanced Adsorption of High-Density Polyelectrolyte Nucleation-Inducing Seed Layer for Highly Conductive Transparent Ultrathin Metal Films

Wang

Yang

et al. 2019

Front. Mater.

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In recent years, ultrathin Ag films (UTAFs), which are attractive owing to its extremely low resistance, relatively high transparency, excellent mechanical flexibility, and mature mass production, have been reported as potential candidates to replace traditional indium tin oxide (ITO). To achieve a high-quality UTAF, a nucleation-inducing seed layer (NISL) is required to address the issue of irregular Ag islands growth. However, the structures of films so deposited are still far from being ideal and consist of rough surfaces with high densities of voids and grain boundaries when the film thickness is < ∼6 nm. Here, a hybrid structure composed of a gold (Au)/polyethyleneimine (PEI) bilayer is employed as a high-density NISL for the fabrication of an UTAF. Compared to the conventional single-layered PEI NISL that physisorbed on the substrate via the weak electrostatic attraction between the negatively charged substrate and the positively charged amine groups in PEI, our novel bilayered Au/PEI NISL exhibits a much higher density of nucleation sites due to the formation of strong coordinate covalent bonds between the Au atoms and amine groups. As a result, the percolation threshold thickness of the UTAF based on the Au/PEI bilayer can be reduced to as low as 3 nm. After capping with a high-refractive-index tantalum pentoxide (Ta 2 O 5 ) anti-reflection layer, the resultant Au/PEI/8 nm Ag/30 nm Ta 2 O 5 (APAT) electrode exhibits an excellent optoelectrical performance with a sheet resistance of 9.07 /sq and transmittance of 92.9% in the spectral range of 400-800 nm as well as outstanding long-term environmental and mechanical stabilities. The findings demonstrate a novel strategy for the development of high-performance UTAF-based transparent electrodes.

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Role of Polymeric Metal Nucleation Inducers in Fabricating Large‐Area, Flexible, and Transparent Electrodes for Printable Electronics

Cited by 46 publications

References 51 publications

Supersmooth Ta₂O₅/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells

Supersmooth Ta₂O₅/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells

Embedded-grid silver transparent electrodes fabricated by selective metal condensation

Metal-Enhanced Adsorption of High-Density Polyelectrolyte Nucleation-Inducing Seed Layer for Highly Conductive Transparent Ultrathin Metal Films

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Role of Polymeric Metal Nucleation Inducers in Fabricating Large‐Area, Flexible, and Transparent Electrodes for Printable Electronics

Cited by 46 publications

References 51 publications

Supersmooth Ta2O5/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells

Supersmooth Ta2O5/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells

Embedded-grid silver transparent electrodes fabricated by selective metal condensation

Metal-Enhanced Adsorption of High-Density Polyelectrolyte Nucleation-Inducing Seed Layer for Highly Conductive Transparent Ultrathin Metal Films

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Product

Resources

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Supersmooth Ta₂O₅/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells

Supersmooth Ta₂O₅/Ag/Polyetherimide Film as the Rear Transparent Electrode for High Performance Semitransparent Perovskite Solar Cells