Nanoindentation im Kristall‐Engineering: Quantifizierung mechanischer Eigenschaften von Molekülkristallen

Varughese, Sunil; Kiran, M. S. R. N.; Ramamurty, Upadrasta; Desiraju, Gautam R.

doi:10.1002/ange.201205002

Cited by 47 publications

(8 citation statements)

References 110 publications

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“…We employed the nanoindentation technique to provide further corroborative evidence for PIPT in 1. [9,24] In the recent past, the ability of nanoindentation to reflect PIPTs with signature discontinuity events in the load-depth of penetration (P-h) curves, such as "pop-in" during loading and "popout", "kink", or "elbow" formation during unloading, has been established fairly well. [25][26][27] Representative P-h curves obtained on the {100} and {001} faces of crystals of 1 with a spherical tipped indenter (tip radius ca.…”

mentioning

confidence: 99%

Pressure‐Induced Bond Rearrangement and Reversible Phase Transformation in a Metal–Organic Framework

et al. 2014

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Pressure-induced phase transformations (PIPTs) occur in a wide range of materials. In general, the bonding characteristics, before and after the PIPT, remain invariant in most materials, and the bond rearrangement is usually irreversible due to the strain induced under pressure. A reversible PIPT associated with a substantial bond rearrangement has been found in a metal-organic framework material, namely [tmenH2][Er(HCOO)4]2 (tmenH2(2+)=N,N,N',N'-tetramethylethylenediammonium). The transition is first-order and is accompanied by a unit cell volume change of about 10%. High-pressure single-crystal X-ray diffraction studies reveal the complex bond rearrangement through the transition. The reversible nature of the transition is confirmed by means of independent nanoindentation measurements on single crystals.

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confidence: 99%

Pressure‐Induced Bond Rearrangement and Reversible Phase Transformation in a Metal–Organic Framework

et al. 2014

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“…Desiraju’s research interests are in crystal engineering, hydrogen bonding, and structural chemistry. His most recent contributions to Angewandte Chemie include an Essay in the 125th Jubilee Issue on chemistry in India,3a and a Minireview on nanoindentation in crystal engineering 3b. Desiraju is on the International Advisory Board of Angewandte Chemie and was on the International Advisory Board of Chemistry—An Asian Journal from 2006–2011.…”

Section: Featured …︁mentioning

confidence: 99%

Mid‐Infrared Spectroscopy for Monitoring of Anaerobic Digestion Processes – Prospects and Challenges

Eccleston¹,

Wolf²,

Balsam

et al. 2016

Chem Eng & Technol

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To develop an online probe that is not only sufficiently robust, but also able to measure crucial process variables in biogas plants is a tough challenge. Therefore, a mid‐infrared (MIR) spectroscopic attenuated total reflection (ATR) probe and robust probe fitting were established. A fully automated probe control, calibration after probe cleaning, and analysis of the absorption spectra using machine learning were implemented in order to reduce maintenance of the probe to a minimum. The relevant wavelengths in the MIR spectrum for organic acids, total alkalinity, and ammonium nitrogen concentration were identified. Finally, intensive lab testing was carried out, followed by operation of the complete online measurement system at an industrial biogas plant. In order to improve signal strength and sensitivity, microelectronic mechanical system (MEMS)‐based Fabry‐Pérot interferometers were also investigated.

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“…We employed the nanoindentation technique to provide further corroborative evidence for PIPT in 1 9. 24 In the recent past, the ability of nanoindentation to reflect PIPTs with signature discontinuity events in the load‐depth of penetration ( P – h ) curves, such as “pop‐in” during loading and “pop‐out”, “kink”, or “elbow” formation during unloading, has been established fairly well 25–27. Representative P – h curves obtained on the {100} and {001} faces of crystals of 1 with a spherical tipped indenter (tip radius ca.…”

Section: Isothermal Axial Compressibilities For Phases I and Ii Of Frmentioning

confidence: 99%

Pressure‐Induced Bond Rearrangement and Reversible Phase Transformation in a Metal–Organic Framework

Spencer

Kiran

et al. 2014

Angewandte Chemie

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Pressure‐induced phase transformations (PIPTs) occur in a wide range of materials. In general, the bonding characteristics, before and after the PIPT, remain invariant in most materials, and the bond rearrangement is usually irreversible due to the strain induced under pressure. A reversible PIPT associated with a substantial bond rearrangement has been found in a metal–organic framework material, namely [tmenH2][Er(HCOO)4]2 (tmenH22+=N,N,N′,N′‐tetramethylethylenediammonium). The transition is first‐order and is accompanied by a unit cell volume change of about 10 %. High‐pressure single‐crystal X‐ray diffraction studies reveal the complex bond rearrangement through the transition. The reversible nature of the transition is confirmed by means of independent nanoindentation measurements on single crystals.

show abstract

Nanoindentation im Kristall‐Engineering: Quantifizierung mechanischer Eigenschaften von Molekülkristallen

Cited by 47 publications

References 110 publications

Pressure‐Induced Bond Rearrangement and Reversible Phase Transformation in a Metal–Organic Framework

Pressure‐Induced Bond Rearrangement and Reversible Phase Transformation in a Metal–Organic Framework

Mid‐Infrared Spectroscopy for Monitoring of Anaerobic Digestion Processes – Prospects and Challenges

Pressure‐Induced Bond Rearrangement and Reversible Phase Transformation in a Metal–Organic Framework

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