Your search keyword '"Christopher R. Benson"' showing total 10 results

1. Plug-and-Play Optical Materials from Fluorescent Dyes and Macrocycles

Author

Krishnan Raghavachari, Tumpa Sadhukhan, Bo Qiao, Yoan C. Simon, Chun-Hsing Chen, Christopher R. Benson, Bo W. Laursen, Wei Zhao, Katherine L. VanDenburgh, Brad J. Davis, Sina Borgi, Maren Pink, Laura Kacenauskaite, Junsheng Chen, and Amar H. Flood

Subjects

Materials science, Fluorophore, General Chemical Engineering, Supramolecular chemistry, Ionic bonding, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, chemistry.chemical_compound, Materials Chemistry, OLED, Environmental Chemistry, chemistry.chemical_classification, business.industry, Biochemistry (medical), Wide-bandgap semiconductor, General Chemistry, Polymer, 021001 nanoscience & nanotechnology, Fluorescence, 0104 chemical sciences, chemistry, Photonics, 0210 nano-technology, business

Abstract

Summary Fluorescence is critical to applications in optical materials including OLEDs and photonics. While fluorescent dyes are potential key components of these materials, electronic coupling between them in the solid state quenches their emission, preventing their reliable translation to applications. We report a universal solution to this long-standing problem with the discovery of a class of materials called small-molecule ionic isolation lattices (SMILES). SMILES perfectly transfer the optical properties of dyes to solids, are simple to make by mixing cationic dyes with anion-binding cyanostar macrocycles, and work with major classes of commercial dyes, including xanthenes, oxazines, styryls, cyanines, and trianguleniums. Dyes are decoupled spatially and electronically in the lattice by using cyanostar with its wide band gap. Toward applications, SMILES crystals have the highest known brightness per volume and solve concentration quenching to impart fluorescence to commercial polymers. SMILES materials enable predictable fluorophore crystallization to fulfill the promise of optical materials by design.

Published

2020

2. Multi-State Amine Sensing By Electron Transfers In A Bodipy Probe

Author

Krishnan Raghavachari, Christopher R. Benson, Katherine L. VanDenburgh, Sundus Erbas-Cakmak, Yun Liu, Natalie Cox, Tumpa Sadhukhan, Bo Qiao, Amar H. Flood, Maren Pink, and Xinfeng Gao

Subjects

Boron Compounds, Quenching (fluorescence), Fluorophore, Chemistry, Quinolinium Compounds, Organic Chemistry, Electron, Ring (chemistry), Photochemistry, Biochemistry, Fluorescence, Photoinduced electron transfer, chemistry.chemical_compound, Spectrometry, Fluorescence, Models, Chemical, Amine gas treating, Physical and Theoretical Chemistry, BODIPY, Amines, Density Functional Theory, Fluorescent Dyes

Abstract

Amines are ubiquitous in the chemical industry and are present in a wide range of biological processes, motivating the development of amine-sensitive sensors. There are many turn-on amine sensors, however there are no examples of turn-on sensors that utilize the amine's ability to react by single electron transfer (SET). We investigated a new turn-on amine probe with a 4,4-difluoro-4-bora-3a,4a-diaza-s-indacene (BODIPY) fluorophore. BODIPY fluorescence is first preprogrammed into an off state by internal photoinduced electron transfer (PET) to an electron-deficient quinolinium ring, resulting in fluorescence quenching. At low concentrations of aliphatic amine (0 to 10 mM), this PET pathway is shut down by external SET from the amine to the photoexcited charge-transfer state of the probe and the fluorescence is turned on. At high concentrations of amine (50 mM to 1 M), we observed collisional quenching of the BODIPY fluorescence. The probe is selective for aliphatic amines over aromatic amines, and aliphatic thiols or alcohols. The three molecular processes modulate the BODIPY fluorescence in a multi-mechanistic way with two of them producing a direct response to amine concentrations. The totality of the three molecular processes produced the first example of a multi-state and dose-responsive amine sensor.

Published

2020

3. Fundamental Design Rules for Turning on Fluorescence in Ionic Molecular Crystals

Author

Chun-Hsing Chen, Krishnan Raghavachari, Wei Zhao, Amar H. Flood, Bo Qiao, Junsheng Chen, Katherine L. VanDenburgh, Laura Kacenauskaite, Sina Borgi, Maren Pink, Christopher R. Benson, Tumpa Sadhukhan, and Bo W. Laursen

Subjects

Rhodamine, chemistry.chemical_compound, Materials science, Fluorophore, chemistry, Band gap, OLED, Ionic bonding, Cyanine, Photochemistry, HOMO/LUMO, Fluorescence

Abstract

Fluorescence is critical to many advanced materials including OLEDs and bioimaging. While molecular fluorophores that show bright emission in solution are potential sources of these materials, their emission is frequently lost in the solid state preventing their direct translation to optical applications. Unpredictable packing and coupling of dyes leads to uncontrolled spectral shifts and quenched emission. No universal solution has been found since Perkin made the first synthetic dye 150 years ago. We report the serendipitous discovery of a new type of material that we call small-molecule ionic isolation lattices(SMILES) tackling this long-standing problem. SMILES are easily prepared by adding two equivalents of the anion receptor cyanostar to cationic dyes binding the counter anions and inducing alternating packing of dyes and cyanostar-anion complexes. SMILES materials reinstate solution-like spectral properties and bright fluorescence to thin films and crystals. These positive outcomes derive from the cyanostar. Its wide 3.45-eV band gap allows the HOMO and LUMO levels of the dye to nest inside those of the complex as verified by electrochemistry. This feature simultaneously enables spatial and electronic isolation to decouple the fluorophores from each other and from the cyanostar-anion lattice. Representative dyes from major families of fluorophores, viz, xanthenes, oxazines, styryls, cyanines, and trianguleniums, all crystalize in the characteristic structure and regain their attractive fluorescence. SMILES crystals of rhodamine and cyanine display unsurpassed brightness per volume pointing to uses in demanding applications such as bioimaging. SMILES materials enable predictable fluorophore crystallization to fulfil the promise of optical materials by design.

Published

2019

4. Extreme Stabilization and Redox Switching of Organic Anions and Radical Anions by Large-Cavity, CH Hydrogen-Bonding Cyanostar Macrocycles

Author

Michelle B. Mills, Matthew G. Marzo, Kathryn E. Preuss, Amar H. Flood, Christopher R. Benson, Semin Lee, Maren Pink, and Elisabeth M. Fatila

Subjects

biology, 010405 organic chemistry, Hydrogen bond, Chemistry, Radical, General Chemistry, Electronic structure, 010402 general chemistry, Electrochemistry, Photochemistry, 01 natural sciences, Biochemistry, Redox, Catalysis, 0104 chemical sciences, Ion, Tetrazine, chemistry.chemical_compound, Colloid and Surface Chemistry, biology.protein, Organic anion

Abstract

Encapsulation of unstable guests is a powerful way to enhance their stability. The lifetimes of organic anions and their radicals produced by reduction are typically short on account of reactivity with oxygen while their larger sizes preclude use of traditional anion receptors. Here we demonstrate the encapsulation and noncovalent stabilization of organic radical anions by C–H hydrogen bonding in π-stacked pairs of cyanostar macrocycles having large cavities. Using electrogenerated tetrazine radical anions, we observe significant extension of their lifetimes, facile molecular switching, and extremely large stabilization energies. The guests form threaded pseudorotaxanes. Complexation extends the radical lifetimes from 2 h to over 20 days without altering its electronic structure. Electrochemical studies show tetrazines thread inside a pair of cyanostar macrocycles following voltage-driven reduction (+e–) of the tetrazine at −1.00 V and that the complex disassembles after reoxidation (−e–) at −0.05 V. This...

Published

2016

5. Double Switching of Two Rings in Palindromic [3]Pseudorotaxanes: Cooperativity and Mechanism of Motion

Author

Andrew I. Share, Christopher R. Benson, Matthew G. Marzo, and Amar H. Flood

Subjects

010405 organic chemistry, Ligand, Chemistry, Stereochemistry, Double switching, Kinetics, Cooperativity, 010402 general chemistry, Ring (chemistry), Electrochemistry, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, Crystallography, Bipyridine, chemistry.chemical_compound, Tetrazine, Physical and Theoretical Chemistry

Abstract

The existence of two rings in [3]pseudorotaxanes presents opportunities for those rings to undergo double switching and cooperative mechanical coupling. To investigate this capability, we identified a new strategy for bringing two rings into contact with each other and conducted mechanistic studies to reveal their kinetic cooperativity. A redox-active tetrazine ligand bearing two binding sites was selected to allow for two mobile copper(I) macrocycle ring moieties to come together. To realize this switching modality, ligands were screened against their ability to serve as stations on which the rings are initially parked, ultimately identifying 5,5'-dimethyl-2,2'-bipyridine. The kinetics of switching a macrocycle in a single-site [2]pseudorotaxane between bipyridine and single-site tetrazine stations were examined using electrochemistry. The forward movement was rate-limited by the bimolecular reaction between reduced tetrazine and bipyridine [2]pseudorotaxane. Two bipyridines were then used with a double-site tetrazine to verify double switching of two rings. Our results indicated stepwise movements, with the first ring moving 4 times more frequently (faster) than the second. While this behavior is indicative of anticooperative kinetics, positive thermodynamic cooperativity sets the two rings in motion even though just one tetrazine is reduced with one electron. Double switching in this [3]pseudorotaxane uniquely demonstrates how a series of independent thermodynamic states and kinetic paths govern an apparently simple mechanical motion.

Published

2016

6. Inchworm movement of two rings switching onto a thread by biased Brownian diffusion represent a three-body problem

Author

Amar H. Flood, Abhishek Singharoy, Elisabeth M. Fatila, Christopher Maffeo, Yun Liu, Edward G. Sheetz, Aleksei Aksimentiev, and Christopher R. Benson

Subjects

Rotaxanes, Kinetics, Catenanes, Thread (computing), Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, Biophysical Phenomena, Artificial Molecular Machines Special Feature, Diffusion, Tetrazine, chemistry.chemical_compound, Motion, Electrochemistry, Brownian motion, Physics, Multidisciplinary, 010405 organic chemistry, Coupled motion, Models, Theoretical, Three-body problem, Molecular machine, 0104 chemical sciences, Classical mechanics, chemistry, Brownian dynamics, Thermodynamics, Algorithms

Abstract

The coordinated motion of many individual components underpins the operation of all machines. However, despite generations of experience in engineering, understanding the motion of three or more coupled components remains a challenge, known since the time of Newton as the “three-body problem.” Here, we describe, quantify, and simulate a molecular three-body problem of threading two molecular rings onto a linear molecular thread. Specifically, we use voltage-triggered reduction of a tetrazine-based thread to capture two cyanostar macrocycles and form a [3]pseudorotaxane product. As a consequence of the noncovalent coupling between the cyanostar rings, we find the threading occurs by an unexpected and rare inchworm-like motion where one ring follows the other. The mechanism was derived from controls, analysis of cyclic voltammetry (CV) traces, and Brownian dynamics simulations. CVs from two noncovalently interacting rings match that of two covalently linked rings designed to thread via the inchworm pathway, and they deviate considerably from the CV of a macrocycle designed to thread via a stepwise pathway. Time-dependent electrochemistry provides estimates of rate constants for threading. Experimentally derived parameters (energy wells, barriers, diffusion coefficients) helped determine likely pathways of motion with rate-kinetics and Brownian dynamics simulations. Simulations verified intercomponent coupling could be separated into ring–thread interactions for kinetics, and ring–ring interactions for thermodynamics to reduce the three-body problem to a two-body one. Our findings provide a basis for high-throughput design of molecular machinery with multiple components undergoing coupled motion.

Published

2018

7. Mechanistic Evaluation of Motion in Redox-Driven Rotaxanes Reveals Longer Linkers Hasten Forward Escapes and Hinder Backward Translations

Author

Bjørn La Cour Poulsen, Amar H. Flood, Stinne Wessel Hansen, Mads Kørner, Troels Duedal, Jan O. Jeppesen, Christopher R. Benson, Andrew I. Share, and Sissel S. Andersen

Subjects

Paraquat, Molecular switch, Rotaxanes, Bistability, MECHANICALLY INTERLOCKED MOLECULES RESOLVED VIBRATIONAL SPECTROSCOPY DONOR-ACCEPTOR UNIDIRECTIONAL ROTATION SWITCHING KINETICS MACHINE MOTOR RING THERMODYNAMICS RECOGNITION, Stereochemistry, Kinetics, General Chemistry, Ring (chemistry), Biochemistry, Catalysis, Motion, Homologous series, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Heterocyclic Compounds, Chemical physics, Thermodynamics, Cyclic voltammetry, Oxidation-Reduction, Linker, Tetrathiafulvalene

Abstract

Mechanistic understanding of the translational movements in molecular switches is essential for designing machine-like prototypes capable of following set pathways of motion. To this end, we demonstrated that increasing the station-to-station distance will speed up the linear movements forward and slow down the movements backward in a homologous series of bistable rotaxanes. Four redox-active rotaxanes, which drove a cyclobis(paraquat-p-phenylene) (CBPQT(4+)) mobile ring between a tetrathiafulvalene (TTF) station and an oxyphenylene station, were synthesized with only variations to the lengths of the glycol linker connecting the two stations (n = 5, 8, 11, and 23 atoms). We undertook the first mechanistic study of the full cycle of motion in this class of molecular switch using cyclic voltammetry. The kinetics parameters (k, ΔG(‡)) of switching were determined at different temperatures to provide activation enthalpies (ΔH(‡)) and entropies (ΔS(‡)). Longer glycol linkers led to modest increases in the forward escape (t(1/2) = 60 to7 ms). The rate-limiting step involves movement of the tetracationic CBPQT(4+) ring away from the singly oxidized TTF(+) unit by overcoming one of the thiomethyl (SMe) speed bumps before proceeding on to the secondary oxyphenylene station. Upon reduction, however, the return translational movement of the CBPQT(4+) ring from the oxyphenylene station back to the neutral TTF station was slowed considerably by the longer linkers (t(1/2) = 1.4 to69 s); though not because of a diffusive walk. The reduced rate of motion backward depended on folded structures that were only present with longer linkers.

Published

2014

8. Self-assembly snapshots of a 2 × 2 copper(I) grid

Author

Andrew I. Share, Douglas A. Vander Griend, Amar H. Flood, Hyunsoo Park, Lauren E. Manck, and Christopher R. Benson

Subjects

Chemistry, Ligand, Enthalpy, chemistry.chemical_element, General Chemistry, Copper, Gibbs free energy, Crystallography, symbols.namesake, symbols, Proton NMR, Titration, Self-assembly, Stoichiometry

Abstract

Self-assembled 2 × 2 grids have been characterised as high-fidelity species produced when the correct stoichiometric ratios are met, but rarely are the individual steps leading to and from their formation characterised. Here, we present such a study using equilibrium-restricted factor analysis to model a set of UV–vis spectra starting from a bis-bidentate ligand to the assembly of a 2 × 2 grid complex upon titration with 1 equiv. of [Cu(MeCN)4](PF6) and to disassembly upon further titration. Intermediate species [CuL2]+, [Cu2L3]2+, [Cu3L2]3+ and [Cu2L]2+ are evidenced along the assembly and disassembly pathways. Complementary 1H NMR titrations are consistent with the rich set of complexes and equilibria involved. Given the nature of the assembly process, the assembly is entropy driven and likely enthalpy driven as well. The disassembly process is both enthalpy and entropy driven according to the standard free energy values derived from the modelling of the spectrophotometric titration data.

Published

2014

9. Multiplying the electron storage capacity of a bis-tetrazine pincer ligand

Author

Richard L. Lord, Kumar Parimal, Brian J. Cook, Alice K. Hui, Kenneth G. Caulton, Christopher R. Benson, Chun-Hsing Chen, and Amar H. Flood

Subjects

Photochemistry, Redox, law.invention, Pincer movement, Inorganic Chemistry, Tetrazine, chemistry.chemical_compound, Crystallography, chemistry, law, Pyridine, Mössbauer spectroscopy, Cyclic voltammetry, Electron paramagnetic resonance, Pincer ligand

Abstract

An unexpected doubling in redox storage emerging from a new pincer ligand upon bis-ligation of iron(ii) is described. When tetrazine arms are present at the two ortho positions of pyridine, the resulting bis-tetrazinyl pyridine (btzp) pincer ligand displays a single one-electron reduction at ca. -0.85 V vs. Ag/AgCl. Complexation to iron, giving the cation Fe(btzp)2(2+), shows no oxidation but four reduction waves in cyclic voltammetry instead of the two expected for the two constituent ligands. Mossbauer, X-ray diffraction and NMR studies show the iron species to contain low spin Fe(ii), but with evidence of back donation from iron to the pincer ligands. CV and UV-Vis spectroelectrochemistry, as well as titration studies as monitored by CV, electronic spectra and EPR reveal the chemical reversibility of forming the reduced species. DFT and EPR studies show varying degrees of delocalization of unpaired spin in different species, including that of a btzp(-1) radical anion, partnered with various cations.

Published

2014

10. Bioinspired Molecular Machines

Author

Andrew I. Share, Christopher R. Benson, and Amar H. Flood

Subjects

Materials science, Nanotechnology, Molecular machine

Published

2012