Thomas Krüger scite author profile

We investigated the performance of the approximative density functional method DFTB versus BLYP and G2 with respect to zero-point corrected reaction energies, vibrational frequencies, and geometry parameters for a set of 28 reactions and 22 representative molecules containing C, H, N, and O (DFTB--density-functional based tight-binding approximation). The DFTB reaction energies show a mean absolute deviation versus the G2 reference of 4.3 kcalmol only. The corresponding value for the vibrational frequencies amounts to 75 cm(-1) versus BLYP/cc-pVTZ. With very few exceptions bond lengths and angles are in excellent agreement with the results of higher-level methods.

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Subconscious Detection of Threat as Reflected by an Enhanced Response Bias

Windmann

Krüger

1998

Consciousness and Cognition

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Kinetics and systematics of structural phase transitions in the regular lanthanide metals under pressure

Krüger

Merkau

Grosshans

et al. 1990

High Pressure Research

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Single-Step Formation of a Low Work Function Cathode Interlayer and n-type Bulk Doping from Semiconducting Polymer/Polyethylenimine Blend Solution

Seidel

Lungwitz

Opitz

et al. 2020

ACS Appl. Mater. Interfaces

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The use of polyethylenimine (PEI) as a thin interlayer between cathodes and organic semiconductors in order to reduce interfacial Ohmic losses has become an important approach in organic electronics. It has also been shown that such interlayers can form spontaneously because of vertical phase separation when spin-coating a blended solution of PEI and the semiconductor. Furthermore, bulk doping of semiconducting polymers by PEI has been claimed. However, to our knowledge, a clear delineation of interfacial from bulk effects has not been published. Here, we report a study on thin films formed by spin-coating blended solutions of PEI and poly{[N,N′-bis(2-octyldodecyl)naphthalene-1,4,5,8-bis(dicarboximide)-2,6-diyl]-alt-5,5′-(2,2′-bithiophene)} [P(NDI2OD-T2)] on indium tin oxide. We observed the vertical phase separation in such films, where PEI accumulates at the bottom and the top, sandwiching the semiconductor layer. The PEI interlayer on ITO reduces the electron injection barrier to the minimum value determined by Fermi level pinning, which, in turn, reduces the contact resistance by 5 orders of magnitude. Although we find no evidence for doping-induced polarons in P(NDI2OD-T2) upon mixing with PEI from optical absorption, more sensitive electron paramagnetic resonance measurements provide evidence for doping and an increased carrier density, at a very low level. This, in conjunction with an increased charge carrier mobility due to trap filling, results in an increase in the mixed polymer conductivity by 4 orders of magnitude relative to pure P(NDI2OD-T2). Consequently, both interfacial and bulk effects occur with notable magnitude in thin films formed from blended semiconductor polymer/PEI solution. Thus, this facile one-step procedure to form PEI interlayers must be applied with attention, as modification of the bulk semiconductor polymer (here doping) may occur simultaneously and might go un-noticed if not examined carefully.

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Nickel Complexes Containing Sterically Demanding Thiolate Ligands: [Ni₈S(SC₄H₉)₉]^⊖, a Mixed‐Valence Nickel Sulfide Thiolate Cluster, and [Ni₄(SC₃H₇)₈], a Homoleptic Nickel Thiolate

Krüger

Krebs

Henkel

1989

Angew. Chem. Int. Ed. Engl.

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Thomas Krüger

Validation of the density-functional based tight-binding approximation method for the calculation of reaction energies and other data

Subconscious Detection of Threat as Reflected by an Enhanced Response Bias

Kinetics and systematics of structural phase transitions in the regular lanthanide metals under pressure

Single-Step Formation of a Low Work Function Cathode Interlayer and n-type Bulk Doping from Semiconducting Polymer/Polyethylenimine Blend Solution

Nickel Complexes Containing Sterically Demanding Thiolate Ligands: [Ni₈S(SC₄H₉)₉]^⊖, a Mixed‐Valence Nickel Sulfide Thiolate Cluster, and [Ni₄(SC₃H₇)₈], a Homoleptic Nickel Thiolate

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Thomas Krüger

Validation of the density-functional based tight-binding approximation method for the calculation of reaction energies and other data

Subconscious Detection of Threat as Reflected by an Enhanced Response Bias

Kinetics and systematics of structural phase transitions in the regular lanthanide metals under pressure

Single-Step Formation of a Low Work Function Cathode Interlayer and n-type Bulk Doping from Semiconducting Polymer/Polyethylenimine Blend Solution

Nickel Complexes Containing Sterically Demanding Thiolate Ligands: [Ni8S(SC4H9)9]⊖, a Mixed‐Valence Nickel Sulfide Thiolate Cluster, and [Ni4(SC3H7)8], a Homoleptic Nickel Thiolate

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Nickel Complexes Containing Sterically Demanding Thiolate Ligands: [Ni₈S(SC₄H₉)₉]^⊖, a Mixed‐Valence Nickel Sulfide Thiolate Cluster, and [Ni₄(SC₃H₇)₈], a Homoleptic Nickel Thiolate