Solvent-Independent Anharmonicity for Carbonyl Oscillators

Schneider, Sebastian; Kratochvil, Huong T.; Zanni, Martin T.; Boxer, Steven G.

doi:10.1021/acs.jpcb.7b00537

Cited by 46 publications

(60 citation statements)

References 64 publications

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“…Figure 3c reveals that the elemental ratios of C:N are 4.5:1 and 8.8:1 in the CD 0.33 and CD 5 samples, respectively. C 1s high-resolution XPS spectra of CD 0.33 and CD 5 (Figure 3d) show presence of CC bonds (≈285 eV), CN bonds (≈286 eV), and CN/CO coordination (≈288 eV), [21] with CD 0.33 possessing a higher CN bond content than CD 5 , which is well consistent with the decrease in the amount of −NH 2 groups. N 1s high-resolution…”

Section: Resultssupporting

confidence: 70%

Energy Level Modification with Carbon Dot Interlayers Enables Efficient Perovskite Solar Cells and Quantum Dot Based Light‐Emitting Diodes

Zhang

Zeng

Xiong

et al. 2020

Adv Funct Materials

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Controlling the transport and minimizing charge carrier trapping at interfaces is crucial for the performance of various optoelectronic devices. Here, how electronic properties of stable, abundant, and easy‐to‐synthesized carbon dots (CDs) are controlled via the surface chemistry through a chosen ratio of their precursors citric acid and ethylenediamine are demonstrated. This allows to adjust the work function of indium tin oxide (ITO) films over the broad range of 1.57 eV, through deposition of thin CD layers. CD modifiers with abundant amine groups reduce the ITO work function from 4.64 to 3.42 eV, while those with abundant carboxyl groups increase it to 4.99 eV. Using CDs to modify interfaces between metal oxide (SnO2 and ZnO) films and active layers of solar cells and light‐emitting diodes (LEDs) allows to significantly improve their performance. Power conversion efficiency of CH3NH3PbI3 perovskite solar cells increases from 17.3% to 19.5%; the external quantum efficiency of CsPbI3 perovskite quantum dot LEDs increases from 4.8% to 10.3%; and that of CdSe/ZnS quantum dot LEDs increases from 8.1% to 21.9%. As CD films are easily fabricated in air by solution processing, the approach paves the way to a simplified manufacturing of large‐area and low‐cost optoelectronic devices.

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Section: Resultssupporting

confidence: 70%

Energy Level Modification with Carbon Dot Interlayers Enables Efficient Perovskite Solar Cells and Quantum Dot Based Light‐Emitting Diodes

Zhang

Zeng

Xiong

et al. 2020

Adv Funct Materials

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“…In those works, vibrational frequency red-shifts were interpreted to imply that the bond probed is destabilized from strain (mechanically or electrostatically) imposed onto it by the enzyme. In contrast, data from our laboratory accrued over the past few years have supported the view that most vibrational frequency variation (in carbonyls, at least) can be explained through a static electric field–difference dipole effect (53, 91), not by bond weakening or strain (i.e., changes in the force constant) (103, 104). This represents a departure from how vibrational measurements (both infrared and Raman) have traditionally been interpreted in enzymology (105–107), and efforts are ongoing to reinterpret this corpus of biochemical data within this physical framework (108, 109).…”

Section: Stark Spectroscopy and Electric Field Measurementsmentioning

confidence: 86%

“…In other words, the recorded frequency shifts report on the electrostatic environment experienced by the ground state (as the excited state will not cause the environment to reorganize in any appreciable way). Second, |Δ μ⃗ | tends to be insensitive to the probe’s environment (another consequence of small Δ α ) (54, 91). Third, vibrations can be confined to as few as two atoms (to a good level of approximation), so the experiment provides a more local, higher-resolution description of electric fields (88, 92).…”

Section: Stark Spectroscopy and Electric Field Measurementsmentioning

confidence: 99%

Electric Fields and Enzyme Catalysis

Fried

Boxer

2017

Annu. Rev. Biochem.

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349

456

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What happens inside an enzyme’s active site to allow slow and difficult chemical reactions to occur so rapidly? This question has occupied biochemists’ attention for a long time. Computer models of increasing sophistication have predicted an important role for electrostatic interactions in enzymatic reactions, yet this hypothesis has proved vexingly difficult to test experimentally. Recent experiments utilizing the vibrational Stark effect make it possible to measure the electric field a substrate molecule experiences when bound inside its enzyme’s active site. These experiments have provided compelling evidence supporting a major electrostatic contribution to enzymatic catalysis. Here, we review these results and develop a simple model for electrostatic catalysis that enables us to incorporate disparate concepts introduced by many investigators to describe how enzymes work into a more unified framework stressing the importance of electric fields at the active site.

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“…Comparison of intrinsic activity of sputtered NPs using the i ss method. [32] a) Voltammograms of all sputtered NPs (Pt, binary, quaternary, and quinary Cr-Mn-Fe-Co-Ni) using an i ss normalized scale for activity comparison. "I" and "II" refer to repetition with same suspension, "new" to analysis of a sample prepared with an alloy target.…”

Section: Electrochemical Strategy For Activity Measurementsmentioning

confidence: 99%

“…Hence, we hypothesize that catalytic activity cannot be solely predicted based on the properties of the constituent elements, and superior multinary catalysts do not uniquely rely on the position of their elements in such volcano plots [26,27] alone. Strain effects [28][29][30] or interparticle distance [31,32] were shown to affect electrocatalytic activity. Strain effects can be strongly modulated in multinary solid solutions; however, more importantly, the homogeneous distribution of all elements induces a numerous amount of new active site configurations with different constitutions of neighboring atoms electronically interacting with each other.…”

mentioning

confidence: 99%

Discovery of a Multinary Noble Metal–Free Oxygen Reduction Catalyst

Löffler

Meyer

Savan

et al. 2018

Advanced Energy Materials

247

245

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four-electron/four-proton transfer, which causes sluggish kinetics. Pt-based materials are the state-of-the-art electrocatalysts for ORR due to their outstanding catalytic activity, selectivity, and long-term stability under operating conditions. [1] However, their scarcity and, thus, high cost limit their applications.Accordingly, research on non-noble metal catalysts increased substantially over the past decades. The most promising material classes so far are transitionmetal-nitrogen-carbon complexes [2][3][4] with Fe or Co as the metal center, [5,6] metal-N 4 organometallic complexes [7] or metal-free catalysts such as nitrogen-doped carbon species utilizing carbon nanotubes or graphene. [8][9][10] These catalysts show promising activity; however, they still fall short in their overall performance compared to Pt. Hence, new materials capable of replacing Pt-based catalysts for ORR are yet to be found.One approach in exploring novel materials is to increase their chemical complexity. Multinary metal alloys require a more challenging synthesis pathway, but enable a virtually unlimited amount of different compositions. For instance, over 2 × 10 6 combinations for quinary alloys selected from a list of 50 elements are possible, each with a different composition. Therefore, selection of candidate materials to be tested is necessary, e.g., based on abundance and toxicity of elements. Some of these largely unexplored multinary compositions might show unique physical and chemical properties. For many alloys, comprising typically five principal elements or more, an unexpected stability as a single solid solution phase was observed in spite of their chemical complexity. This stability is usually explained by the so-called high-entropy effect. [11][12][13] The proposed underlying rational include i) stabilization of the multinary single phase due to increasing entropy with an increasing number of constituents, ii) a lattice distortion effect, and iii) sluggish diffusion. [14] This special state of a complex solid solution may result in unusual properties which are not observed for heterogeneous multiphase alloys comprising intermetallic phases. Their advantages in mechanical, physical, and chemical properties such as structural stability [15] as well as corrosion [16] and oxidation resistance have been evaluated over the past years. [17] Potential applications in (electro)catalysis have only been reported for

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Solvent-Independent Anharmonicity for Carbonyl Oscillators

Cited by 46 publications

References 64 publications

Energy Level Modification with Carbon Dot Interlayers Enables Efficient Perovskite Solar Cells and Quantum Dot Based Light‐Emitting Diodes

Energy Level Modification with Carbon Dot Interlayers Enables Efficient Perovskite Solar Cells and Quantum Dot Based Light‐Emitting Diodes

Electric Fields and Enzyme Catalysis

Discovery of a Multinary Noble Metal–Free Oxygen Reduction Catalyst

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