Starting materials: PbO, HI, H3PO2, heptylamine

Product: spin-coated thin film

Description: First step: (C7)2PbI4 single crystal flakes synthesized as follows: Slow-cooling in HI method: 2.232g (10 mmol) of PbO dissolved in glass vial containing 10 mL of HI and 1.7 mL of H3PO2. Brought to near-boiling temperature. 10 mmol of the organic amine mixed with 5 mL HI, cooled in an ice bath. Solutions were mixed and heated, then cooled to room temperature, upon which single crystal flakes form. Crystals were then washed thrice with diethyl ether and dried under a vacuum. Second step (thin film formation): Flakes were dissolved in 4:1 DMF:DMSO solvent mixture, stirred for 30 minutes. Substrate: quartz substrate with 120 nm gold layer of interdigitated fingers. Precursor solution (0.1-0.3 molar) pipetted onto substrate and then spun at 4000 rpm for 30 seconds, targeting film thickness of 80-300nm. Film was solvent-annealed, then enclosed with 2mL dH2O. When the crystallites were cooled to low temperature, a portion remained in phase I structure, allowing for simultaneous measurements in phase I and II structures.

Method: Electroabsorption

Description: Films were spin-coated onto interdigitated Au electrode array - 45 micron distance between opposing fingers. Samples mounted in cryostat with Cu wires soldered to opposing electrode stripes. Xe lamp light spectrally filtered, focused on sample and subsequently on UV-enhanced Si photodiode detector. Sample transmission, substrate transmission, and sample electrotransmission were collected in independent scans. Absorbance and electroabsorbance were then calculated from the respective transmissions. The exciton binding energy arises as the difference of the 1s exciton peak energy observed in conventional absorption and the fundamental gap as determined by the crossover point of absorption curves measured under different electric fields in the fundamental band gap region.

Comment: Significantly more detail in paper.

K. Hansen, C. Wong, C. E. McClure, B. Romrell, L. Flannery, D. Powell, K. Garden, A. Berzansky, M. Eggleston, D. King, C. Shirley, M. Beard, W. Nie, A. Schleife, J. Colton, and L. Whittaker-Brooks, Uncovering Unique Screening Effects in 2D Perovskites: Implications for Exciton and Band Gap Engineering, ResearchSquare Preprint, 1‑22 (2023). doi: https://doi.org/10.21203/rs.3.rs-2667143/v1.

Extraction method: Manual from article (Table S1)
Entry added on: Aug. 16, 2023, 6:47 p.m.
Entry added by: Kelly Ma
Last updated on: Aug. 16, 2023, 6:52 p.m.
Last updated by: Kelly Ma

Starting materials: PbO, HI, H3PO2, heptylamine

Product: spin-coated thin film

Description: First step: (C7)2PbI4 single crystal flakes synthesized as follows: Slow-cooling in HI method: 2.232g (10 mmol) of PbO dissolved in glass vial containing 10 mL of HI and 1.7 mL of H3PO2. Brought to near-boiling temperature. 10 mmol of the organic amine mixed with 5 mL HI, cooled in an ice bath. Solutions were mixed and heated, then cooled to room temperature, upon which single crystal flakes form. Crystals were then washed thrice with diethyl ether and dried under a vacuum. Second step (thin film formation): Flakes were dissolved in 4:1 DMF:DMSO solvent mixture, stirred for 30 minutes. Substrate: quartz substrate with 120 nm gold layer of interdigitated fingers. Precursor solution (0.1-0.3 molar) pipetted onto substrate and then spun at 4000 rpm for 30 seconds, targeting film thickness of 80-300nm. Film was solvent-annealed, then enclosed with 2mL dH2O. When the crystallites were cooled to low temperature, a portion remained in phase I structure, allowing for simultaneous measurements in phase I and II structures.

Comment: Data for phase II

Method: Electroabsorption

Description: Films were spin-coated onto interdigitated Au electrode array - 45 micron distance between opposing fingers. Samples mounted in cryostat with Cu wires soldered to opposing electrode stripes. Xe lamp light spectrally filtered, focused on sample and subsequently on UV-enhanced Si photodiode detector. Sample transmission, substrate transmission, and sample electrotransmission were collected in independent scans.Absorbance and electroabsorbance were then calculated from the respective transmissions. The fundamental gap is determined by the crossover point of absorption curves measured under different electric fields in the fundamental band gap region.

Comment: Significantly more detail in paper.

K. Hansen, C. Wong, C. E. McClure, B. Romrell, L. Flannery, D. Powell, K. Garden, A. Berzansky, M. Eggleston, D. King, C. Shirley, M. Beard, W. Nie, A. Schleife, J. Colton, and L. Whittaker-Brooks, Uncovering Unique Screening Effects in 2D Perovskites: Implications for Exciton and Band Gap Engineering, ResearchSquare Preprint, 1‑22 (2023). doi: https://doi.org/10.21203/rs.3.rs-2667143/v1.

Extraction method: Manual from article (Table S1)
Entry added on: Aug. 16, 2023, 7:06 p.m.
Entry added by: Kelly Ma
Last updated on: Aug. 16, 2023, 7:06 p.m.
Last updated by: Kelly Ma