Johannes Kaestner scite author profile

Johannes Kaestner

4Publications

65Citation Statements Received

182Citation Statements Given

How they've been cited

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141

176

Affiliations

University of Stuttgart, Clausthal University of Technology

Publications

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Activation and protonation of dinitrogen at the FeMo cofactor of nitrogenase

Kaestner

Hemmen

Bloechl

2005

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The protonation of N2 bound to the active center of nitrogenase has been investigated using state-of-the-art density-functional theory calculations. Dinitrogen in the bridging mode is activated by forming two bonds to Fe sites, which results in a reduction of the energy for the first hydrogen transfer by 123 kJ/mol. The axial binding mode with open sulfur bridge is less reactive by 30 kJ/mol and the energetic ordering of the axial and bridged binding modes is reversed in favor of the bridging dinitrogen during the first protonation. Protonation of the central ligand is thermodynamically favorable but kinetically hindered. If the central ligand is protonated, the proton is transferred to dinitrogen following the second protonation. Protonation of dinitrogen at the Mo site does not lead to low-energy intermediates.

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Electronic Structure Methods: Augmented Waves, Pseudopotentials and The Projector Augmented Wave Method

Blöchl

Kaestner

Foerst

2005

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The main goal of electronic structure methods is to solve the Schrödinger equation for the electrons in a molecule or solid, to evaluate the resulting total energies, forces, response functions and other quantities of interest. In this paper we describe the basic ideas behind the main electronic structure methods such as the pseudopotential and the augmented wave methods and provide selected pointers to contributions that are relevant for a beginner. We give particular emphasis to the Projector Augmented Wave (PAW) method developed by one of us, an electronic structure method for abinitio molecular dynamics with full wavefunctions. We feel that it allows best to show the common conceptional basis of the most widespread electronic structure methods in materials science.

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Understanding the Redox Mechanism of Sulfurized Poly(acrylonitrile) as Highly Rate and Cycle Stable Cathode Material for Sodium-Sulfur Batteries

Kappler¹,

Tonbul²,

Schoch³

et al. 2023

J. Electrochem. Soc.

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Room-temperature sodium-sulfur batteries are considered potential candidates for stationary power storage applications due to their low cost, broad active material availability, and low toxicity. Challenges, such as high volume expansion of the S-cathode upon discharge, low electronic conductivity of S as active material, and herewith limited rate capability as well as the shuttling of polysulfides (PSs) as intermediates often impede the cycle stability and practical application of Na-S batteries. Sulfurized poly(acrylonitrile) (SPAN) inherently inhibits the shuttling of PSs and shows compatibility with carbonate-based electrolytes; however, its exact redox mechanism remained unclear to date. Herein, we implement a commercially available and simple electrolyte into the Na-SPAN cell chemistry and demonstrate its high rate and cycle stability. Through the application of in situ techniques utilizing electronic impedance spectroscopy and X-ray absorption spectroscopy at different depths of charge and discharge, an insight into SPAN’s redox chemistry could be obtained.

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ChemInform Abstract: Theory and Simulation of Atom Tunneling in Chemical Reactions

Kaestner

2014

ChemInform

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