Your search keyword '"Lehnherr D"' showing total 41 results

1. Copper‐Enabled Photo‐Sulfonylation of Aryl Halides Using Alkylsulfinates.

Author

Mdluli, V., primary, Lehnherr, D., additional, Lam, Y.‐h., additional, Ji, Y., additional, Newman, J. A., additional, and Kim, J., additional

Published

2023

2. Formal Intramolecular Photoredox Chemistry of Meta-Substituted Benzophenones

Author

Mitchell, D., Lukeman, M., Lehnherr, D., and Wan, P.

Abstract

Photolysis of 3-(hydroxymethyl)benzophenone (1) in aqueous solution (pH < 3) results in clean formation of 3-formylbenzhydrol (2) at dilute (<10^-4 M) conditions. Evidence suggests that the highly efficient (Φ ~ 0.6) reaction involves a unimolecular mechanism and an overall formal intramolecular photoredox process, which requires electronic communication between the 1,3-positions of the benzene ring, an unprecedented example of the photochemical meta effect. The photoredox reaction was not observed in organic solvents, where only photoreduction of the benzophenone moiety was observed.

Published

2005

3. More Nitrogen in the Pi.

Author

LEHNHERR, D., ALZOLA, J. M., MULZER, C. R., HEIN, S. J., and DICHTEL, W. R.

Published

2017

4. Helical ortho-Arylene Foldamers.

Author

LEHNHERR, D., CHEN, C., PEDRAMRAZI, Z., DEBLASE, C. R., ALZOLA, J. M., KERESZTES, I., LOBKOVSKY, E. B., CROMMIE, M. F., and DICHTEL, W. R.

Published

2016

5. Hydrogen Isotope Labeling of Pharmaceuticals Via Dual Hydrogen Isotope Exchange Pathways Using CdS Quantum Dot Photocatalyst.

Author

Maity R, Dungan O, Perras FA, Li J, Liu D, Ren S, Lehnherr D, Huang Z, Phillips EM, Adeyemo M, Frimpong J, Quainoo T, Liu ZF, and Luo L

Subjects

Catalysis, Pharmaceutical Preparations chemistry, Quantum Dots chemistry, Sulfides chemistry, Cadmium Compounds chemistry, Hydrogen chemistry, Photochemical Processes, Isotope Labeling

Abstract

Isotopic labeling is a powerful technique extensively used in the pharmaceutical industry. By tracking isotope-labeled molecules, researchers gain unique and invaluable insights into the pharmacokinetics and pharmacodynamics of new drug candidates. Hydrogen isotope labeling is particularly important as hydrogen is ubiquitous in organic molecules in biological systems, and it can be introduced effectively through late-stage hydrogen isotope exchange (HIE). However, hydrogen isotope methods that simultaneously label multiple sites with varying types of C-H bonds in the different types of molecules are still lacking. Herein, we demonstrate a heterogeneous photocatalytic system using a CdS quantum dot catalyst that proceeds via a unique dual HIE pathway mechanism─one occurs in the reaction solution and the other on the catalytic surface─to address it. This unique mechanism unlocked several unique labeling capabilities, including simultaneous labeling of multiple and challenging sites such as secondary α-amino, α-ethereal, allyl, and vinyl sites, providing great versatility in practical uses for pharmaceutical labeling.

Published

2024

6. Electrosynthesis of iminophosphoranes and applications in nickel catalysis.

Author

Mdluli V, Lehnherr D, Lam YH, Chaudhry MT, Newman JA, DaSilva JO, and Regalado EL

Abstract

P(v) iminophosphorane compounds are accessed via electrochemical oxidation of commercially available P(iii) phosphines, including mono-, di- and tri-dentate phosphines, as well as chiral phosphines. The reaction uses inexpensive bis(trimethylsilyl)carbodiimide as an efficient and safe aminating reagent. DFT calculations, cyclic voltammetry, and NMR studies provide insight into the reaction mechanism. The proposed mechanism reveals a special case of sequential paired electrolysis. DFT calculations of the frontier orbitals of an iminophosphorane are compared with those of the analogous phosphines and phosphine oxides. X-ray crystallographic studies of the ligands as well as a Ni-coordination complex provide structural insight for these ligands. The utility of these iminophosphoranes as ligands is demonstrated in nickel-catalyzed cross-electrophile couplings including C(sp 2 )-C(sp 3 ) and C(sp 2 )-C(sp 2 ) couplings, an electrochemically driven C-N cross-coupling, and a photochemical arylative C(sp 3 )-H functionalization. In some cases, these new ligands provide improved performance over commonly used sp 2 - N -based ligands ( e.g. 4,4'-di- tert -butyl-2,2'-bipyridine)., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

7. Accelerating Pharmaceutical Process Development with an Acoustic Droplet Ejection-Multiple Reaction Monitoring-Mass Spectrometry Workflow.

Author

Hu H, Singh AN, Lehnherr D, Mdluli V, Chun SW, Makarewicz AM, Gouker JR, Ukaegbu O, Li S, Wen X, McLaren DG, Velasquez JE, Moore JC, Galanie S, Appiah-Amponsah E, and Regalado EL

Subjects

Acoustics, Mass Spectrometry methods, Peptides, Workflow, Drug Development

Abstract

Fast-paced pharmaceutical process developments (e.g., high-throughput experimentation, directed evolution, and machine learning) involve the introduction of fast, sensitive, and accurate analytical assays using limited sample volumes. In recent years, acoustic droplet ejection (ADE) coupled with an open port interface has been invented as a sampling technology for mass spectrometry, providing high-throughput nanoliter analytical measurements directly from the standard microplates. Herein, we introduce an ADE-multiple reaction monitoring-mass spectrometry (ADE-MRM-MS) workflow to accelerate pharmaceutical process research and development (PR&D). This systematic workflow outlines the selection of MRM transitions and optimization of assay parameters in a data-driven manner using rapid measurements (1 sample/s). The synergy between ADE sampling and MRM analysis enables analytical assays with excellent sensitivity, selectivity, and speed for PR&D reaction screenings. This workflow was utilized to develop new ADE-MRM-MS assays guiding a variety of industrial processes, including (1) screening of Ni-based catalysts for C-N cross-coupling reaction at 1 Hz and (2) high-throughput regioisomer analysis-enabled enzyme library screening for peptide ligation reaction. ADE-MRM-MS assays were demonstrated to deliver accurate results that are comparable to conventional liquid chromatography (LC) experiments while providing >100-fold throughput enhancement.

Published

2024

8. Quinone-mediated hydrogen anode for non-aqueous reductive electrosynthesis.

Author

Twilton J, Johnson MR, Sidana V, Franke MC, Bottecchia C, Lehnherr D, Lévesque F, Knapp SMM, Wang L, Gerken JB, Hong CM, Vickery TP, Weisel MD, Strotman NA, Weix DJ, Root TW, and Stahl SS

Abstract

Electrochemical synthesis can provide more sustainable routes to industrial chemicals 1-3 . Electrosynthetic oxidations may often be performed 'reagent-free', generating hydrogen (H 2 ) derived from the substrate as the sole by-product at the counter electrode. Electrosynthetic reductions, however, require an external source of electrons. Sacrificial metal anodes are commonly used for small-scale applications 4 , but more sustainable options are needed at larger scale. Anodic water oxidation is an especially appealing option 1,5,6 , but many reductions require anhydrous, air-free reaction conditions. In such cases, H 2 represents an ideal alternative, motivating the growing interest in the electrochemical hydrogen oxidation reaction (HOR) under non-aqueous conditions 7-12 . Here we report a mediated H 2 anode that achieves indirect electrochemical oxidation of H 2 by pairing thermal catalytic hydrogenation of an anthraquinone mediator with electrochemical oxidation of the anthrahydroquinone. This quinone-mediated H 2 anode is used to support nickel-catalysed cross-electrophile coupling (XEC), a reaction class gaining widespread adoption in the pharmaceutical industry 13-15 . Initial validation of this method in small-scale batch reactions is followed by adaptation to a recirculating flow reactor that enables hectogram-scale synthesis of a pharmaceutical intermediate. The mediated H 2 anode technology disclosed here offers a general strategy to support H 2 -driven electrosynthetic reductions., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

9. High-Throughput Determination of Stern-Volmer Quenching Constants for Common Photocatalysts and Quenchers.

Author

Motz RN, Sun AC, Lehnherr D, and Ruccolo S

Abstract

Mechanistic information on reactions proceeding via photoredox catalysis has enabled rational optimizations of existing reactions and revealed new synthetic pathways. One essential step in any photoredox reaction is catalyst quenching via photoinduced electron transfer or energy transfer with either a substrate, additive, or cocatalyst. Identification of the correct quencher using Stern-Volmer studies is a necessary step for mechanistic understanding; however, such studies are often cumbersome, low throughput and require specialized luminescence instruments. This report describes a high-throughput method to rapidly acquire a series of Stern-Volmer constants, employing readily available fluorescence plate readers and 96-well plates. By leveraging multichannel pipettors or liquid dispensing robots in combination with fast plate readers, the sampling frequency for quenching studies can be improved by several orders of magnitude. This new high-throughput method enabled the rapid collection of 220 quenching constants for a library of 20 common photocatalysts with 11 common quenchers. The extensive Stern-Volmer constant table generated greatly facilitates the systematic comparison between quenchers and can provide guidance to the synthetic community interested in designing and understanding catalytic photoredox reactions., Competing Interests: The authors declare no competing financial interest., (© 2023 Merck & Co., Inc., Rahway, NJ, USA and its affiliates. Published by American Chemical Society.)

Published

2023

10. Pentacenones as Divergent Intermediates to Unsymmetrically Substituted Pentacenes: Synthesis and Crystallographic Analysis.

Author

Schroeder ZW, McDonald R, Ferguson MJ, Chalifoux WA, Tykwinski RR, and Lehnherr D

Abstract

We report a general method for the desymmetrization of 6,13-pentacenequinone to access ethynylated pentacene ketones, namely, 13-hydroxy-13-(ethynylated)pentacene-6(13 H )-ones. These pentacene ketones ("pentacenones") serve as divergent intermediates to unsymmetrically 6,13-disubstituted pentacenes, commonly used for studying singlet fission processes and charge transport phenomena in organic field effect transistors. We report a synthetic method to access pentacenones, which utilizes a precipitation/crystallization from the crude mixture to enable facile purification on a multigram scale. X-ray crystallographic analysis of the pentacenones reveals key noncovalent interactions that contribute to the crystallization, specifically, hydrogen bonding between the ketone and alcohol functional groups as well as π-π-stacking and dipole-dipole interactions.

Published

2022

11. Parallel versus Twisted Pentacenes: Conformational Impact on Singlet Fission.

Author

Papadopoulos I, Reddy SR, Coto PB, Lehnherr D, Thiel D, Thoss M, Tykwinski RR, and Guldi DM

Abstract

We placed two pentacene chromophores at the termini of a diacetylene linker to investigate the impact of excitation wavelength, conformational flexibility, and vibronic coupling on singlet fission. Photoexcitation of the low-energy absorption results in a superposed mixture of states, which transform on an ultrafast time-scale into a spin-correlated and vibronically coupled/hot delocalized triplet pair 1 (T 1 T 1 ) deloc . Regardless of temperature, the lifetime for 1 (T 1 T 1 ) deloc is less than 2 ps. In contrast, photoexcitation of the high-energy absorption results in the formation of 1 (T 1 T 1 ) deloc lasting 1.0 ps, which then decays at room temperature within 4 ps via triplet-triplet annihilation. Lowering the temperature enables 1 (T 1 T 1 ) deloc to delocalize and vibronically decouple, in turn affording 1 (T 1 T 1 ) loc . In addition, our results suggest that the quasi-free rotation at the diacetylene spacer may lead to twisted conformations with very low SF quantum yields, highlighting the need of controlling this structural aspect in the design of new singlet fission active molecules.

Published

2022

12. Electrochemically driven cross-electrophile coupling of alkyl halides.

Author

Zhang W, Lu L, Zhang W, Wang Y, Ware SD, Mondragon J, Rein J, Strotman N, Lehnherr D, See KA, and Lin S

Abstract

Recent research in medicinal chemistry has suggested that there is a correlation between an increase in the fraction of sp 3 carbons-those bonded to four other atoms-in drug candidates and their improved success rate in clinical trials 1 . As such, the development of robust and selective methods for the construction of carbon(sp 3 )-carbon(sp 3 ) bonds remains a critical problem in modern organic chemistry 2 . Owing to the broad availability of alkyl halides, their direct cross-coupling-commonly known as cross-electrophile coupling-provides a promising route towards this objective 3-5 . Such transformations circumvent the preparation of carbon nucleophiles used in traditional cross-coupling reactions, as well as stability and functional-group-tolerance issues that are usually associated with these reagents. However, achieving high selectivity in carbon(sp 3 )-carbon(sp 3 ) cross-electrophile coupling remains a largely unmet challenge. Here we use electrochemistry to achieve the differential activation of alkyl halides by exploiting their disparate electronic and steric properties. Specifically, the selective cathodic reduction of a more substituted alkyl halide gives rise to a carbanion, which undergoes preferential coupling with a less substituted alkyl halide via bimolecular nucleophilic substitution to forge a new carbon-carbon bond. This protocol enables efficient cross-electrophile coupling of a variety of functionalized and unactivated alkyl electrophiles in the absence of a transition metal catalyst, and shows improved chemoselectivity compared with existing methods., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

13. Efficient Aliphatic Hydrogen-Isotope Exchange with Tritium Gas through the Merger of Photoredox and Hydrogenation Catalysts.

Author

Yang H, Huang Z, Lehnherr D, Lam YH, Ren S, and Strotman NA

Subjects

Catalysis, Hydrogenation, Tritium chemistry, Carbon chemistry, Hydrogen chemistry

Abstract

Employment of a combination of an organophotoredox catalyst with Wilkinson's catalyst (Rh(PPh 3 ) 3 Cl) has given rise to an unprecedented method for hydrogen-isotope exchange (HIE) of aliphatic C(sp 3 )-H bonds of complex pharmaceuticals using T 2 gas directly. Wilkinson's catalyst, commonly used for catalytic hydrogenations, was exploited as a precatalyst for activation of D 2 or T 2 and hydrogen atom transfer. In this combined methodology and mechanistic study, we demonstrate that by coupling photocatalysis with Rh catalysis, carbon-centered radicals generated via photoredox catalysis can be intercepted by Rh-hydride intermediates to deliver an effective hydrogen atom donor for hydrogen-isotope labeling of complex molecules in one step. By optimizing the ratio of the photocatalyst and Wilkinson's catalyst to balance the rate of the dual catalytic cycles, we can achieve efficient HIE and high recovery yield. This protocol was readily applied to direct HIE of C(sp 3 )-H bonds in 10 complex drug molecules, showing high isotope incorporation efficiency and exceptionally good functional group tolerance and demonstrating this approach as a practical and attractive labeling method for deuteration and tritiation.

Published

2022

14. Benzylic Photobromination for the Synthesis of Belzutifan: Elucidation of Reaction Mechanisms Using In Situ LED-NMR.

Author

Ji Y, Bottecchia C, Lévesque F, Narsimhan K, Lehnherr D, McMullen JP, Dalby SM, Xiao KJ, and Reibarkh M

Subjects

Humans, Kinetics, Magnetic Resonance Spectroscopy, Carcinoma, Renal Cell complications, Carcinoma, Renal Cell pathology, Kidney Neoplasms complications, Kidney Neoplasms pathology, von Hippel-Lindau Disease complications

Abstract

A detailed mechanistic understanding of a benzylic photobromination en route to belzutifan (MK-6482, a small molecule for the treatment of renal cell carcinoma associated with von Hippel-Lindau syndrome) has been achieved using in situ LED-NMR spectroscopy in conjunction with kinetic analysis. Two distinct mechanisms of overbromination, namely, the ionic and radical pathways, have been revealed by this study. The behavior of the major reaction species, including reactants, intermediates, products, and side products, has been elucidated. Comprehensive understanding of both pathways informed and enabled mitigation of a major process risk: a sudden product decomposition. Detailed knowledge of the processes occurring during the reaction and their potential liabilities enabled the development of a robust photochemical continuous flow process implemented for commercial manufacturing.

Published

2022

15. Photons or Electrons? A Critical Comparison of Electrochemistry and Photoredox Catalysis for Organic Synthesis.

Author

Tay NES, Lehnherr D, and Rovis T

Subjects

Catalysis, Chemistry Techniques, Synthetic methods, Electrochemistry, Electrons, Photons

Abstract

Redox processes are at the heart of synthetic methods that rely on either electrochemistry or photoredox catalysis, but how do electrochemistry and photoredox catalysis compare? Both approaches provide access to high energy intermediates (e.g., radicals) that enable bond formations not constrained by the rules of ionic or 2 electron (e) mechanisms. Instead, they enable 1e mechanisms capable of bypassing electronic or steric limitations and protecting group requirements, thus enabling synthetic chemists to disconnect molecules in new and different ways. However, while providing access to similar intermediates, electrochemistry and photoredox catalysis differ in several physical chemistry principles. Understanding those differences can be key to designing new transformations and forging new bond disconnections. This review aims to highlight these differences and similarities between electrochemistry and photoredox catalysis by comparing their underlying physical chemistry principles and describing their impact on electrochemical and photochemical methods.

Published

2022

16. Unlocking the Potential of High-Throughput Experimentation for Electrochemistry with a Standardized Microscale Reactor.

Author

Rein J, Annand JR, Wismer MK, Fu J, Siu JC, Klapars A, Strotman NA, Kalyani D, Lehnherr D, and Lin S

Abstract

Organic electrochemistry has emerged as an enabling and sustainable technology in modern organic synthesis. Despite the recent renaissance of electrosynthesis, the broad adoption of electrochemistry in the synthetic community, and especially in industrial settings, has been hindered by the lack of general, standardized platforms for high-throughput experimentation (HTE). Herein, we disclose the design of the HT e - Chem, a high-throughput microscale electrochemical reactor that is compatible with existing HTE infrastructure and enables the rapid evaluation of a broad array of electrochemical reaction parameters. Utilizing the HT e - Chem to accelerate reaction optimization, reaction discovery, and chemical library synthesis is illustrated using a suite of oxidative and reductive transformations under constant current, constant voltage, and electrophotochemical conditions., Competing Interests: The authors declare no competing financial interest., (© 2021 Cornell University and Merck & Co., Inc., Kenilworth, NJ, USA. Published by American Chemical Society.)

Published

2021

17. Synthesis of Sterically Hindered Primary Amines by Concurrent Tandem Photoredox Catalysis.

Author

Nicastri MC, Lehnherr D, Lam YH, DiRocco DA, and Rovis T

Abstract

Primary amines are an important structural motif in active pharmaceutical ingredients (APIs) and intermediates thereof, as well as members of ligand libraries for either biological or catalytic applications. Many chemical methodologies exist for amine synthesis, but the direct synthesis of primary amines with a fully substituted α carbon center is an underdeveloped area. We report a method which utilizes photoredox catalysis to couple readily available O -benzoyl oximes with cyanoarenes to synthesize primary amines with fully substituted α-carbons. We also demonstrate that this method enables the synthesis of amines with α-trifluoromethyl functionality. Based on experimental and computational results, we propose a mechanism where the photocatalyst engages in concurrent tandem catalysis by reacting with the oxime as a triplet sensitizer in the first catalytic cycle and a reductant toward the cyanoarene in the second catalytic cycle to achieve the synthesis of hindered primary amines via heterocoupling of radicals from readily available oximes.

Published

2020

18. Electrochemical Synthesis of Hindered Primary and Secondary Amines via Proton-Coupled Electron Transfer.

Author

Lehnherr D, Lam YH, Nicastri MC, Liu J, Newman JA, Regalado EL, DiRocco DA, and Rovis T

Abstract

Accessing hindered amines, particularly primary amines α to a fully substituted carbon center, is synthetically challenging. We report an electrochemical method to access such hindered amines starting from benchtop-stable iminium salts and cyanoheteroarenes. A wide variety of substituted heterocycles (pyridine, pyrimidine, pyrazine, purine, azaindole) can be utilized in the cross-coupling reaction, including those substituted with a halide, trifluoromethyl, ester, amide, or ether group, a heterocycle, or an unprotected alcohol or alkyne. Mechanistic insight based on DFT data, as well as cyclic voltammetry and NMR spectroscopy, suggests that a proton-coupled electron-transfer mechanism is operational as part of a hetero-biradical cross-coupling of α-amino radicals and radicals derived from cyanoheteroarenes.

Published

2020

19. Discovery of a Photoinduced Dark Catalytic Cycle Using in Situ LED-NMR Spectroscopy.

Author

Lehnherr D, Ji Y, Neel AJ, Cohen RD, Brunskill APJ, Yang J, and Reibarkh M

Abstract

We report the use of LED-NMR spectroscopy to study the reaction mechanism of a newly discovered photoinduced iron-catalyzed cycloisomerization of alkynols to cyclic enol ethers. By understanding on/off ligand binding to the catalyst, we were able to appropriately design reaction conditions to balance catalyst activity and stability. LED-NMR was demonstrated to be a powerful tool in elucidating reaction mechanisms of photochemical reactions. Temporal NMR spectroscopic data under visible light illumination (1) revealed the pre-catalyst activation mechanism, (2) proved that photon flux provides a unique external control of the equilibrium distribution between the pre-catalyst and active catalyst, and ultimately the rate of reaction, (3) provided information about the reaction driving forces and the turnover-limiting step, and (4) enabled both real-time structural and kinetic insights into elusive species (e.g., dissolved gases).

Published

2018

20. Alkyne Benzannulation Reactions for the Synthesis of Novel Aromatic Architectures.

Author

Hein SJ, Lehnherr D, Arslan H, J Uribe-Romo F, and Dichtel WR

Abstract

Aromatic compounds and polymers are integrated into organic field effect transistors, light-emitting diodes, photovoltaic devices, and redox-flow batteries. These compounds and materials feature increasingly complex designs, and substituents influence energy levels, bandgaps, solution conformation, and crystal packing, all of which impact performance. However, many polycyclic aromatic hydrocarbons of interest are difficult to prepare because their substitution patterns lie outside the scope of current synthetic methods, as strategies for functionalizing benzene are often unselective when applied to naphthalene or larger systems. For example, cross-coupling and nucleophilic aromatic substitution reactions rely on prefunctionalized arenes, and even directed metalation methods most often modify positions near Lewis basic sites. Similarly, electrophilic aromatic substitutions access single regioisomers under substrate control. Cycloadditions provide a convergent route to densely functionalized aromatic compounds that compliment the above methods. After surveying cycloaddition reactions that might be used to modify the conjugated backbone of poly(phenylene ethynylene)s, we discovered that the Asao-Yamamoto benzannulation reaction is notably efficient. Although this reaction had been reported a decade earlier, its scope and usefulness for synthesizing complex aromatic systems had been under-recognized. This benzannulation reaction combines substituted 2-(phenylethynyl)benzaldehydes and substituted alkynes to form 2,3-substituted naphthalenes. The reaction tolerates a variety of sterically congested alkynes, making it well-suited for accessing poly- and oligo(ortho-arylene)s and contorted hexabenzocoronenes. In many cases in which asymmetric benzaldehyde and alkyne cycloaddition partners are used, the reaction is regiospecific based on the electronic character of the alkyne substrate. Recognizing these desirable features, we broadened the substrate scope to include silyl- and halogen-substituted alkynes. Through a combined experimental and computational approach, we have elucidated mechanistic insight and key principles that govern the regioselectivity outcome of the benzannulation of structurally diverse alkynes. We have applied these methods to prepare sterically hindered, shape-persistent aromatic systems, heterocyclic aromatic compounds, functionalized 2-aryne precursors, polyheterohalogenated naphthalenes, ortho-arylene foldamers, and graphene nanoribbons. As a result of these new synthetic avenues, aromatic structures with interesting properties were uncovered such as ambipolar charge transport in field effect transistors based on our graphene nanoribbons, conformational aspects of ortho-arylene architectures resulting from intramolecular π-stacking, and modulation of frontier molecular orbitals via protonation of heteroatom containing aromatic systems. Given the availability of many substituted 2-(phenylethynyl)benzaldehydes and the regioselectivity of the benzannulation reaction, naphthalenes can be prepared with control of the substitution pattern at seven of the eight substitutable positions. Researchers in a range of fields are likely to benefit directly from newly accessible molecular and polymeric systems derived from polyfunctionalized naphthalenes.

Published

2017

21. Rapid access to substituted 2-naphthyne intermediates via the benzannulation of halogenated silylalkynes.

Author

Hein SJ, Lehnherr D, and Dichtel WR

Abstract

Aryne intermediates are versatile and important reactive intermediates for natural product and polymer synthesis. 2-Naphthynes are relatively unexplored because few methods provide precursors to these intermediates, especially for those bearing additional substituents. Here we report a general synthetic strategy to access 2-naphthyne precursors through an Asao-Yamamoto benzannulation of ortho -(phenylethynyl)benzaldehydes with halo-silylalkynes. This transformation provides 2-halo-3-silylnaphthalenes with complete regioselectivity. These naphthalene products undergo desilylation/dehalogenation in the presence of F - to generate the corresponding 2-naphthyne intermediate, as evidenced by furan trapping experiments. When these 2-naphthynes are generated in the presence of a copper catalyst, ortho -naphthalene oligomers, trinaphthalene, or binaphthalene products are formed selectively by varying the catalyst loading and reaction temperature. The efficiency, mild conditions, and versatility of the naphthalene products and naphthyne intermediates will provide efficient access to many new functional aromatic systems.

Published

2017

22. Reductive Aromatization/Dearomatization and Elimination Reactions to Access Conjugated Polycyclic Hydrocarbons, Heteroacenes, and Cumulenes.

Author

Marshall JL, Lehnherr D, Lindner BD, and Tykwinski RR

Abstract

Acenes, heteroacenes, conjugated polycyclic hydrocarbons, and polycyclic aromatic hydrocarbons (collectively referred to in this review as conjugated polycyclic molecules, CPMs) have fascinated chemists since they were first isolated and synthesized in the mid 19th century. Most recently, these compounds have shown significant promise as the active components in organic devices (e.g., solar cells, thin-film transistors, light-emitting diodes, etc.), and, since 2001, a plethora of publications detail synthetic strategies to produce CPMs. In this review, we discuss reductive aromatization, reductive dearomatization, and elimination/extrusion reactions used to form CPMs. After a brief discussion on early methods to synthesize CPMs, we detail the use of reagents used for the reductive (de)aromatization of precursors containing 1,4-diols/diethers, including SnCl 2 and iodide (I - ). Extension of these methods to carbomers and cumulenes is briefly discussed. We then describe low-valent metal species used to reduce endoxides to CPMs, and discuss the methods to directly reduce acenediones and acenones to the respective acene. In the final section, we describe methods used to affect aromatization to the desired CPM via extrusion of small, volatile molecules., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

23. Tautomerization and Dimerization of 6,13-Disubstituted Derivatives of Pentacene.

Author

Garcia-Borràs M, Konishi A, Waterloo A, Liang Y, Cao Y, Hetzer C, Lehnherr D, Hampel F, Houk KN, and Tykwinski RR

Abstract

Two new 6,13-disubstituted pentacene derivatives, 1 c and 1 d, with alkyl and triisopropylsilylethynyl substitution have been synthesized and characterized experimentally and computationally. The alkyl substituted 1 c and 1 d represent the first 6-alkyl-substituted pentacene derivative where the fully aromatic species dominates over the corresponding tautomer. Indeed, no tautomerization product is found for either 1 c or 1 d upon heating or in the presence of catalytic amounts of acid. On the other hand, an unexpected dimer (3 c) is formed from 1 c. A plausible mechanism for this new dimerization process of the 6-methyl-substituted pentacene derivative 1 c is proposed, which involves first a bimolecular hydrogen atom transfer followed by an intramolecular [4+2] Diels-Alder cycloaddition. In the case of 6-butyl substitution, neither tautomerization nor dimerization is observed. Computations support the proposed 1 c dehydrodimerization pathway, explain why 1 d does not dimerize, and show the importance of the nature of the group at C-13 in controlling the relative stability of 6-alkyl-substituted pentacene tautomers., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

24. Diazatetracenes Derived from the Benzannulation of Acetylenes: Electronic Tuning via Substituent Effects and External Stimuli.

Author

Lehnherr D, Alzola JM, Mulzer CR, Hein SJ, and Dichtel WR

Abstract

Functionalized diazatetracenes are prepared using a new two-step sequence. The use of a dichlorobenzaldehyde in a Cu-catalyzed benzannulation of acetylenes provides functionalized dichloronaphthalenes that afford diazatetracenes using Buchwald-Hartwig aminations. This approach provides unique substitution patterns and rapid access to covalently linked dimeric diazatetracenes. Their electronic properties are characterized by UV-vis absorption/emission and cyclic voltammetry, revealing strong effects from both external stimuli by acid and internal substituent effects.

Published

2017

25. Mechanism-Guided Development of a Highly Active Bis-thiourea Catalyst for Anion-Abstraction Catalysis.

Author

Kennedy CR, Lehnherr D, Rajapaksa NS, Ford DD, Park Y, and Jacobsen EN

Abstract

We describe the rational design of a linked, bis-thiourea catalyst with enhanced activity relative to monomeric analogues in a representative enantioselective anion-abstraction reaction. Mechanistic insights guide development of this linking strategy to favor substrate activation though the intramolecular cooperation of two thiourea subunits while avoiding nonproductive aggregation. The resulting catalyst platform overcomes many of the practical limitations that have plagued hydrogen-bond-donor catalysis and enables use of catalyst loadings as low as 0.05 mol %. Computational analyses of possible anion-binding modes provide detailed insight into the precise mechanism of anion-abstraction catalysis with this pseudo-dimeric thiourea.

Published

2016

26. Sequence-defined oligo( ortho -arylene) foldamers derived from the benzannulation of ortho (arylene ethynylene)s.

Author

Lehnherr D, Chen C, Pedramrazi Z, DeBlase CR, Alzola JM, Keresztes I, Lobkovsky EB, Crommie MF, and Dichtel WR

Abstract

A Cu-catalyzed benzannulation reaction transforms ortho (arylene ethynylene) oligomers into ortho -arylenes. This approach circumvents iterative Suzuki cross-coupling reactions previously used to assemble hindered ortho -arylene backbones. These derivatives form helical folded structures in the solid-state and in solution, as demonstrated by X-ray crystallography and solution-state NMR analysis. DFT calculations of misfolded conformations are correlated with variable-temperature 1 H and EXSY NMR to reveal that folding is cooperative and more favorable in halide-substituted naphthalenes. Helical ortho -arylene foldamers with specific aromatic sequences organize functional π-electron systems into arrangements ideal for ambipolar charge transport and show preliminary promise for the surface-mediated synthesis of structurally defined graphene nanoribbons.

Published

2016

27. Conformational Control of Chiral Amido-Thiourea Catalysts Enables Improved Activity and Enantioselectivity.

Author

Lehnherr D, Ford DD, Bendelsmith AJ, Kennedy CR, and Jacobsen EN

Subjects

Catalysis, Hydrogen Bonding, Solutions, Stereoisomerism, Thiourea chemistry

Abstract

While aryl pyrrolidinoamido-thioureas derived from α-amino acids are effective catalysts in a number of asymmetric transformations, they exist as mixtures of slowly interconverting amide rotamers. Herein, the compromising role of amide bond isomerism is analyzed experimentally and computationally. A modified catalyst structure that exists almost exclusively as a single amide rotamer is introduced. This modification is shown to result in improved reactivity and enantioselectivity by minimizing competing reaction pathways.

Published

2016

28. Anion-Abstraction Catalysis: The Cooperative Mechanism of α-Chloroether Activation by Dual Hydrogen-Bond Donors.

Author

Ford DD, Lehnherr D, Kennedy CR, and Jacobsen EN

Abstract

We provide here a detailed mechanistic characterization of the electrophile-activation step in a representative thiourea-catalyzed enantioselective reaction proposed to involve generation of ion-pair intermediates. Comparison of catalyst-promoted substrate epimerization with catalytic alkylation points to the participation of a common intermediate in both pathways and provides conclusive evidence for anion abstraction via an SN1-like pathway involving the cooperative action of two catalyst molecules., Competing Interests: Notes The authors declare no competing financial interests.

Published

2016

29. On- and Off-Cycle Catalyst Cooperativity in Anion-Binding Catalysis.

Author

Ford DD, Lehnherr D, Kennedy CR, and Jacobsen EN

Subjects

Crystallography, X-Ray, Ether chemistry, Hydrogen Bonding, Kinetics, Thiourea chemistry, Anions, Catalysis, Chemistry, Organic methods

Abstract

Chiral, neutral H-bond donors have found widespread use as catalysts in enantioselective reactions involving ion-pair intermediates. Herein, a systematic mechanistic study of a prototypical anion-binding reaction, the thiourea-catalyzed enantioselective alkylation of α-chloroethers, is detailed. This study reveals that the catalyst resting state is an inactive dimeric aggregate that must dissociate and then reassemble to form a 2:1 catalyst-substrate complex in the rate-determining transition structure. Insight into this mode of catalyst cooperativity sheds light on the practical limitations that have plagued many of the H-bond donor-catalyzed reactions developed to date and suggests design strategies for new, highly efficient catalyst structures.

Published

2016

30. Solution-based intramolecular singlet fission in cross-conjugated pentacene dimers.

Author

Zirzlmeier J, Casillas R, Reddy SR, Coto PB, Lehnherr D, Chernick ET, Papadopoulos I, Thoss M, Tykwinski RR, and Guldi DM

Abstract

We show unambiguous and compelling evidence by means of pump-probe experiments, which are complemented by calculations using ab initio multireference perturbation theory, for intramolecular singlet fission (SF) within two synthetically tailored pentacene dimers with cross-conjugation, namely XC1 and XC2. The two pentacene dimers differ in terms of electronic interactions as evidenced by perturbation of the ground state absorption spectra stemming from stronger through-bond contributions in XC1 as confirmed by theory. Multiwavelength analysis, on one hand, and global analysis, on the other hand, confirm that the rapid singlet excited state decay and triplet excited state growth relate to SF. SF rate constants and quantum yields increase with solvent polarity. For example, XC2 reveals triplet quantum yields and rate constants as high as 162 ± 10% and (0.7 ± 0.1) × 10(12) s(-1), respectively, in room temperature solutions.

Published

2016

31. Regioselective Synthesis of Polyheterohalogenated Naphthalenes via the Benzannulation of Haloalkynes.

Author

Lehnherr D, Alzola JM, Lobkovsky EB, and Dichtel WR

Abstract

Independent control of halide substitution at six of the seven naphthalene positions of 2-arylnaphthalenes is achieved through the regioselective benzannulation of chloro-, bromo-, and iodoalkynes. The modularity of this approach is demonstrated through the preparation of 44 polyheterohalogenated naphthalene products, most of which are difficult to access through known naphthalene syntheses. The outstanding regioselectivity of the reaction is both predictable and proven unambiguously by single-crystal X-ray diffraction for many examples. This synthetic method enables the rapid preparation of complex aromatic systems poised for further derivatization using established cross-coupling methods. The power and versatility of this approach makes substituted naphthalenes highly attractive building blocks for new organic materials and diversity-oriented synthesis., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

32. Singlet fission in pentacene dimers.

Author

Zirzlmeier J, Lehnherr D, Coto PB, Chernick ET, Casillas R, Basel BS, Thoss M, Tykwinski RR, and Guldi DM

Abstract

Singlet fission (SF) has the potential to supersede the traditional solar energy conversion scheme by means of boosting the photon-to-current conversion efficiencies beyond the 30% Shockley-Queisser limit. Here, we show unambiguous and compelling evidence for unprecedented intramolecular SF within regioisomeric pentacene dimers in room-temperature solutions, with observed triplet quantum yields reaching as high as 156 ± 5%. Whereas previous studies have shown that the collision of a photoexcited chromophore with a ground-state chromophore can give rise to SF, here we demonstrate that the proximity and sufficient coupling through bond or space in pentacene dimers is enough to induce intramolecular SF where two triplets are generated on one molecule.

Published

2015

33. Aryl substitution of pentacenes.

Author

Waterloo AR, Sale AC, Lehnherr D, Hampel F, and Tykwinski RR

Abstract

A series of 11 new pentacene derivatives has been synthesized, with unsymmetrical substitution based on a trialkylsilylethynyl group at the 6-position and various aryl groups appended to the 13-position. The electronic and physical properties of the new pentacene chromophores have been analyzed by UV-vis spectroscopy (solution and thin films), thermoanalytical methods (DSC and TGA), cyclic voltammetry, as well as X-ray crystallography (for 8 derivatives). X-ray crystallography has been specifically used to study the influence of unsymmetrical substitution on the solid-state packing of the pentacene derivatives. The obtained results add to our ability to better predict substitution patterns that might be helpful for designing new semiconductors for use in solid-state devices.

Published

2014

34. Isomerically pure syn-anthradithiophenes: synthesis, properties, and FET performance.

Author

Lehnherr D, Waterloo AR, Goetz KP, Payne MM, Hampel F, Anthony JE, Jurchescu OD, and Tykwinski RR

Abstract

The synthesis of isomerically pure syn-anthradithiophene derivatives (syn-ADTs) is described. X-ray crystallography is used to compare the solid-state arrangement of syn-ADT derivatives 2a,b to the analogous mixture of syn- and anti-ADTs. Single-crystal OFETs based on isomerically pure syn-ADTs 2a,b display device performance comparable to those based on a mixture of ADT isomers syn/anti-2a,b with mobilities as high as 1 cm(2)/(V s).

Published

2012

35. Synthesis and properties of isomerically pure anthrabisbenzothiophenes.

Author

Lehnherr D, Hallani R, McDonald R, Anthony JE, and Tykwinski RR

Abstract

The synthesis of three heptacyclic heteroacenes is described, namely anthra[2,3-b:7,6-b']bis[1]benzothiophenes (ABBTs). A stepwise sequence of aldol reactions provides regiochemical control, affording only the syn-isomer. The ABBTs are characterized by X-ray crystallography, UV-vis absorption, and emission spectroscopy, as well as cyclic voltammetry. Field effect transistors based on solution-cast thin films of ABBT derivatives exhibit charge-carrier mobilities of as high as 0.013 cm(2)/(V s)., (© 2011 American Chemical Society)

Published

2012

36. A modular synthetic approach to conjugated pentacene di-, tri-, and tetramers.

Author

Lehnherr D, Murray AH, McDonald R, and Tykwinski RR

Published

2010

37. Pentacene-based polycyclic aromatic hydrocarbon dyads with cofacial solid-state pi-stacking.

Author

Lehnherr D, Murray AH, McDonald R, Ferguson MJ, and Tykwinski RR

Published

2009

38. Pentacene-based dendrimers: synthesis and thin film photoconductivity measurements of branched pentacene oligomers.

Author

Lehnherr D, Gao J, Hegmann FA, and Tykwinski RR

Abstract

The synthesis of pentacene-based dendrimers has been achieved via esterification of 1,3,5-benzenetricarboxylic acid and unsymmetrical pentacene 4 possessing a hydroxy group. Dendrimers 1 (C(183)H(204)O(9)Si(9), 2800 g mol(-1)) and 2 (C(540)H(570)O(30)Si(24), 8214 g mol(-1)) are characterized by (1)H and (13)C NMR, IR, UV-vis, and fluorescence spectroscopy, as well as mass spectrometry. These branched oligomeric materials are benchtop stable and soluble in common organic solvents, allowing for solution cast formation of thin films. Photocurrent and photocurrent yield measurements of these films reveal improved efficiency in photogenerated conduction for dendrimers in comparison to linearly connected pentacene-based polymers.

Published

2009

39. Synthesis and electronic properties of conjugated pentacene dimers.

Author

Lehnherr D, Gao J, Hegmann FA, and Tykwinski RR

Abstract

Conjugated pentacene dimers 1-3 were synthesized in two steps from readily available precursors. Noteworthy is the initial step, which assembles five independent fragments to form the carbon-rich molecular framework. Solution-cast films of these materials are air stable. Photocurrent measurements for solution-deposited thin films show that dimer 3 exhibits photoconductive gain >10.

Published

2008

40. Exploring electronically polarized pentacenes.

Author

Lehnherr D, McDonald R, and Tykwinski RR

Abstract

Unsymmetrically functionalized pentacenes with electron-rich and/or -poor substituents at the 6- and 13-positions were synthesized. The electronic influence was evaluated by solution-state UV-vis absorption and emission spectroscopies. These materials exhibit good solubility in common organic solvents and are stable in the presence of air and water.

Published

2008

41. Pentacene oligomers and polymers: functionalization of pentacene to afford mono-, di-, tri-, and polymeric materials.

Author

Lehnherr D and Tykwinski RR

Abstract

The synthesis and characterization of defined-length di- and trimeric pentacenes and the corresponding polymers are described. The synthesis is divergent from two common pentacene building blocks, 1 and 2, allowing for structural diversity. The resulting materials are air stable and exhibit good solubility in common organic solvents.

Published

2007