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1. Controlled n‐Doping of Naphthalene‐Diimide‐Based 2D Polymers

   https://doi.org/10.1002/adma.202101932  

   Evans, Austin_M; Collins, Kelsey_A; Xun, Sangni; Allen, Taylor_G; Jhulki, Samik; Castano, Ioannina; Smith, Hannah_L; Strauss, Michael_J; Oanta, Alexander_K; Liu, Lujia; et al (February 2022, Advanced Materials)

   Abstract 2D polymers (2DPs) are promising as structurally well‐defined, permanently porous, organic semiconductors. However, 2DPs are nearly always isolated as closed shell organic species with limited charge carriers, which leads to low bulk conductivities. Here, the bulk conductivity of two naphthalene diimide (NDI)‐containing 2DP semiconductors is enhanced by controllably n‐doping the NDI units using cobaltocene (CoCp₂). Optical and transient microwave spectroscopy reveal that both as‐prepared NDI‐containing 2DPs are semiconducting with sub‐2 eV optical bandgaps and photoexcited charge‐carrier lifetimes of tens of nanoseconds. Following reduction with CoCp₂, both 2DPs largely retain their periodic structures and exhibit optical and electron‐spin resonance spectroscopic features consistent with the presence of NDI‐radical anions. While the native NDI‐based 2DPs are electronically insulating, maximum bulk conductivities of >10⁻⁴ S cm⁻¹are achieved by substoichiometric levels of n‐doping. Density functional theory calculations show that the strongest electronic couplings in these 2DPs exist in the out‐of‐plane (π‐stacking) crystallographic directions, which indicates that cross‐plane electronic transport through NDI stacks is primarily responsible for the observed electronic conductivity. Taken together, the controlled molecular doping is a useful approach to access structurally well‐defined, paramagnetic, 2DP n‐type semiconductors with measurable bulk electronic conductivities of interest for electronic or spintronic devices. 

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2. Ion formation in droplet‐assisted ionization

   https://doi.org/10.1002/rcm.8227  

   Apsokardu, Michael_J; Kerecman, Devan_E; Johnston, Murray_V (September 2018, Rapid Communications in Mass Spectrometry)

   RationaleIn droplet‐assisted ionization (DAI), intact molecular ions are generated from molecules in aerosol droplets by passing the droplets through a temperature‐controlled capillary inlet. Ion formation is explored through the effects of analyte mass flow, droplet solvent composition, and capillary temperature on ion signal intensity. MethodsA Waters SYNAPT G2‐S is adapted for DAI by reconfiguring the inlet with a temperature‐controlled capillary. Droplets are generated by atomization of a solution containing analyte and then sampled through the inlet. If desired, solvent can be removed from the droplets prior to analysis by sending the aerosol through a series of diffusion dryers. Size distributions of the dried aerosols allow the mass flow of analyte into the inlet to be determined. ResultsAnalyte signal intensities are orders of magnitude higher from droplets containing a protic solvent (water) than an aprotic solvent (acetonitrile). The highest signal intensities for DAI are obtained with inlet temperatures above 500°C, though the optimum temperature is analyte dependent. At elevated temperatures, droplets are thought to undergo rapid solvent evaporation and bursting to produce ions. The lowest signal intensities are generally obtained in the 100–350°C range, where slow solvent evaporation is thought to inhibit ion formation. As the temperature decreases from 100°C down to 25°C, the signal intensity increases significantly. When 3‐nitrobenzonitrile, a common matrix for solid‐state matrix‐assisted ionization (MAI), is added to droplets consisting of 50/50 v/v water and acetonitrile, the matrix enhances ion formation to produce a signal intensity comparable to DAI in 100% water. ConclusionsThe results are consistent with other inlet ionization techniques, suggesting that similar ion formation mechanisms are operative. Optimized ion yields (the combined effects of ionization probability and ion transmission) for DAI are currently in the 10⁻⁵to 10⁻⁶range, which is sufficient for many aerosol applications. 

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3. Liquid chromatography enantiomeric separation of chiral ethanolamine substituted compounds

   https://doi.org/10.1002/chir.23419  

   Firooz, Sepideh Khaki; Putman, Joshua; Fulton, Brandon; Lovely, Carl J.; Berthod, Alain; Armstrong, Daniel W. (January 2022, Chirality)

   Abstract Eleven racemic ethanolamine derivatives were prepared, and their enantiomers were separated using liquid chromatography with various chiral columns. These derivatives included chiral vicinal amino alcohols, β‐hydroxy ureas, β‐hydroxy thioureas, and β‐hydroxy guanidines, all of which are present in many active pharmaceutical ingredients. The screening study was performed with six chiral stationary phase containing columns, including four recently introduced superficially porous particles bonded with two macrocyclic glycopeptides, a cyclodextrin derivative and a cyclofructan derivative. The two remaining columns contained chiral stationary phases, based on either a cellulose derivative or derivatized amylose, both bonded to fully porous particles. The cyclodextrin and cellulose‐based chiral stationary phases proved to be the most broadly effective selectors and were able to separate 8 and 7 of the 11 tested compounds, respectively. With respect to analyte structural features, marked differences in enantiorecognition were observed between compounds containing phenyl and cyclohexyl groups adjacent to the stereogenic center. Additionally, replacing a small electronegative oxygen atom by a larger and less electronegative sulfur atom induced a significant difference in chiral recognition by the cellulose derivative as well as by the vancomycin‐based chiral selectors. 

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4. Preparation, characterization, and simulation of continuous stationary phase gradients on butyl functionalized liquid chromatography columns for protein and peptide separations

   https://doi.org/10.1016/j.chroma.2025.466048  

   Cecil, Thomas; Young, Ash K; Rutan, Sarah C; Collinson, Maryanne M (August 2025, Journal of Chromatography A)

   This work seeks to explore the capabilities of stationary phase gradients (SPGs) for the large-molecule chromatographic separations of proteins and peptides through a combination of experimental studies and simulations. Continuous SPGs are fabricated on commercial Phenomenex Jupiter C4 columns using the time-based infusion of trifluoroacetic acid through the column. The resultant gradients are characterized using smallmolecule chromatography and physical gradient profiling via thermogravimetric analysis. The gradient columns are then tested using two different protein analyte mixtures and a peptide standard analyte mixture to examine the efficacy of the separations. Collected experimental data from these tests are used to establish fitted parameters for the Linear Solvent Strength (LSS) model to computationally predict the retention behavior of the analytes on the gradient columns. Successful chromatographic separation of all three analyte mixtures was achieved. The re-parameterized LSS model successfully simulates the analyte retention on the gradient columns with only minor deviations from observed experimental retention data. Collectively, this work demonstrates the ability to create a C4 continuous stationary phase gradient starting with a uniform commercial column that can be effectively used to separate mixtures of biomolecules, and the ability to accurately simulate and predict retention times. The computational model described herein could be used to effectively predict retention behavior in silico, significantly reducing the time needed for experimental design. 

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5. Introducing gallium in silicon and thin film polysilicon using self assembled monolayer doping

   https://doi.org/https://doi.org/10.1016/j.matlet.2022.132839  

   Carolyn Spaulding; Alex Taylor; Scott Williams; Glenn Packard; Gabriel Curvacho; Santosh Kurinec (October 2022, Materials letters)

   Aldo R. Boccaccini (Ed.)

   Monolayer Doping (MLD) is a technique involving the fmmation of a self-assembled dopant-containing layer on the substrate. The dopant is subsequently incorporated into the substrate by annealing, fmming a diffused region. Following MLD, samples were capped with silicon dioxide and rapid the1mal annealed (RTA). In this work, gallium doping using MLD has been demonstrated. Gallium containing compound Tris (2,4 pentanedionato) gallium(III) was synthesized, and shown to be suitable for monolayer doping silicon subsa-ates and deposited thin film polysi!icon. Seconda1y ion mass spectroscopy (SIMS) and spreading resistance probe (SRP) measurements were performed to determine the dopant profiles and dopant elecu-ical activation. TI1ese results showed that a dose of l.6*1015 atoms/cm2 was received, and the gallium dopant produced a 0.2 µm junction in 11-type silicon. For polysilicon, tlle entire 0.4 µm film was evenly doped, witll a concenu-ation greater than 1019 atoms/cm3 tllroughout. 

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