Your search keyword '"Smernik RJ"' showing total 3 results

1. Fire-derived organic matter retains ammonia through covalent bond formation

Author

Hestrin, R, Torres-Rojas, D, Dynes, JJ, Hook, JM, Regier, TZ, Gillespie, AW, Smernik, RJ, Lehmann, J, Hestrin, R, Torres-Rojas, D, Dynes, JJ, Hook, JM, Regier, TZ, Gillespie, AW, Smernik, RJ, and Lehmann, J

Abstract

Fire-derived organic matter, often referred to as pyrogenic organic matter (PyOM), is present in the Earth’s soil, sediment, atmosphere, and water. We investigated interactions of PyOM with ammonia (NH 3 ) gas, which makes up much of the Earth’s reactive nitrogen (N) pool. Here we show that PyOM’s NH 3 retention capacity under ambient conditions can exceed 180 mg N g −1 PyOM–carbon, resulting in a material with a higher N content than any unprocessed plant material and most animal manures. As PyOM is weathered, NH 3 retention increases sixfold, with more than half of the N retained through chemisorption rather than physisorption. Near-edge X-ray absorption fine structure and nuclear magnetic resonance spectroscopy reveal that a variety of covalent bonds form between NH 3 -N and PyOM, more than 10% of which contained heterocyclic structures. We estimate that through these mechanisms soil PyOM stocks could retain more than 600-fold annual NH 3 emissions from agriculture, exerting an important control on global N cycling.

Published

2019

2. Aromaticity and degree of aromatic condensation of char

Author

Wiedemeier, DB, Wiedemeier, DB, Abiven, S, Hockaday, WC, Keiluweit, M, Kleber, M, Masiello, CA, McBeath, AV, Nico, PS, Pyle, LA, Schneider, MPW, Smernik, RJ, Wiesenberg, GLB, Schmidt, MWI, Wiedemeier, DB, Wiedemeier, DB, Abiven, S, Hockaday, WC, Keiluweit, M, Kleber, M, Masiello, CA, McBeath, AV, Nico, PS, Pyle, LA, Schneider, MPW, Smernik, RJ, Wiesenberg, GLB, and Schmidt, MWI

Abstract

The aromatic carbon structure is a defining property of chars and is often expressed with the help of two concepts: (i) aromaticity and (ii) degree of aromatic condensation. The varying extent of these two features is assumed to largely determine the relatively high persistence of charred material in the environment and is thus of interest for, e.g., biochar characterization or carbon cycle studies. Consequently, a variety of methods has been used to assess the aromatic structure of chars, which has led to interesting insights but has complicated the comparison of data acquired with different methods. We therefore used a suite of seven methods (elemental analysis, MIR spectroscopy, NEXAFS spectroscopy, 13C NMR spectroscopy, BPCA analysis, lipid analysis and helium pycnometry) and compared 13 measurements from them using a diverse sample set of 38 laboratory chars. Our results demonstrate that most of the measurements could be categorized either into those which assess aromaticity or those which assess the degree of aromatic condensation. A variety of measurements, including relatively inexpensive and simple ones, reproducibly captured the two aromatic features in question, and data from different methods could therefore be compared. Moreover, general patterns between the two aromatic features and the pyrolysis conditions were revealed, supporting reconstruction of the highest heat treatment temperature (HTT) of char.

Published

2015

3. Aromaticity and degree of aromatic condensation of char

Author

Wiedemeier, DB, Wiedemeier, DB, Abiven, S, Hockaday, WC, Keiluweit, M, Kleber, M, Masiello, CA, McBeath, AV, Nico, PS, Pyle, LA, Schneider, MPW, Smernik, RJ, Wiesenberg, GLB, Schmidt, MWI, Wiedemeier, DB, Wiedemeier, DB, Abiven, S, Hockaday, WC, Keiluweit, M, Kleber, M, Masiello, CA, McBeath, AV, Nico, PS, Pyle, LA, Schneider, MPW, Smernik, RJ, Wiesenberg, GLB, and Schmidt, MWI

Abstract

The aromatic carbon structure is a defining property of chars and is often expressed with the help of two concepts: (i) aromaticity and (ii) degree of aromatic condensation. The varying extent of these two features is assumed to largely determine the relatively high persistence of charred material in the environment and is thus of interest for, e.g., biochar characterization or carbon cycle studies. Consequently, a variety of methods has been used to assess the aromatic structure of chars, which has led to interesting insights but has complicated the comparison of data acquired with different methods. We therefore used a suite of seven methods (elemental analysis, MIR spectroscopy, NEXAFS spectroscopy, 13C NMR spectroscopy, BPCA analysis, lipid analysis and helium pycnometry) and compared 13 measurements from them using a diverse sample set of 38 laboratory chars. Our results demonstrate that most of the measurements could be categorized either into those which assess aromaticity or those which assess the degree of aromatic condensation. A variety of measurements, including relatively inexpensive and simple ones, reproducibly captured the two aromatic features in question, and data from different methods could therefore be compared. Moreover, general patterns between the two aromatic features and the pyrolysis conditions were revealed, supporting reconstruction of the highest heat treatment temperature (HTT) of char.

Published

2015