Catalytic reduction of dinitrogen to ammonia at a single molybdenum center

Weare, Walter W.; Dai, Xiujuan J.; Byrnes, Matthew John; Chin, Jia Min; Schrock, Richard R.; Müller, Péter

doi:10.1073/pnas.0602778103

Cited by 129 publications

(154 citation statements)

References 25 publications

Supporting

Mentioning

137

Contrasting

Unclassified

Order By: Relevance

“…[31,32] Wir wendeten uns dann Molybdänkomplexen mit dem [HIPTN 3 N] 3À -Liganden zu (HIPT = 3,5-(2,4,6-iPr 3 C 6 H 2 ) 2 C 6 H 3 , Hexaisopropylterphenyl; Schema 1), [33,34] Für eine hypothetische "lineare" Reduktion von N 2 wurden Intermediate vorgeschlagen (Schema 2), von denen die folgenden acht synthetisiert und kristallographisch und mit anderen Verfahren charakterisiert wurden: [33][34][35][36] 3À leicht modifiziert waren, [40,41] und neuere Befunde bei der Reduktion von Distickstoff zusammengefasst. [42][43][44] Die eingesetzte Säure beeinflusst den Erfolg der Reduktion sehr stark. [42] Auch mit einem schwächeren Reduktionsmittel (CoCp 2 ) verläuft die Reaktion noch katalytisch, die Ausbeute an Ammoniak ist dann aber nur etwa halb so groß.…”

Section: Introductionunclassified

“…[45][46][47][48][49][50][51][52][53][54][55] [51] Es gibt Hinweise auf eine Beschleunigung der Zersetzung von Mo-N=NH durch Lutidiniumionen, [34] + neutrale Komplexe MoL zu synthetisieren (L = THF oder 2,6-Lutidin), lieferten nur Mo(N 2 ). [42] Selbst bei CVUntersuchungen in Fluorbenzol war Mo(THF) nicht nachweisbar, weil es sofort zu Mo(N 2 ) weiterreagierte. Die CVDaten deuten darauf hin, dass die Umsetzung von Mo(THF) zu Mo(N 2 ) drei oder mehr Größenordnungen schneller verläuft als die Reaktion von Mo(NH 3 ) zu Mo(N 2 ).…”

Section: Introductionunclassified

See 1 more Smart Citation

Die katalytische Reduktion von Distickstoff zu Ammoniak mit Molybdän: Theorie und Experiment

Schrock

2008

Angewandte Chemie

View full text Add to dashboard Cite

Molybdänkomplexe mit dem Triamidoamin‐Liganden [(RNCH2CH2)3N]3− (R=3,5‐(2,4,6‐iPr3C6H2)2C6H3) katalysieren die Reduktion von Distickstoff unter Einwirkung von Protonen und Elektronen zu Ammoniak. Die Protonen stammen dabei aus 2,6‐Dimethylpyridinium‐Ionen, die Elektronen aus Decamethylchromocen, die Reaktion verläuft bei 22 °C und 1 atm Druck. Mögliche Intermediate dieser Reduktion und ihre Reaktionscharakteristik wurden in mehreren theoretischen Arbeiten untersucht. So wurden DFT‐Rechnungen des Mo‐Komplexes [(HIPTNCH2CH2)3N]Mo (HIPT=Hexaisopropylterphenyl=3,5‐(2,4,6‐iPr3C6H2)2C6H3) durchgeführt, der wie die katalytisch wirksamen Intermediate den Liganden Triamidoamin enthält. In diesem Kurzaufsatz vergleichen wir für jeden angenommenen Teilschritt der Katalysereaktion aktuelle theoretische Befunde und experimentelle Ergebnisse.

show abstract

Section: Introductionunclassified

Die katalytische Reduktion von Distickstoff zu Ammoniak mit Molybdän: Theorie und Experiment

Schrock

2008

Angewandte Chemie

View full text Add to dashboard Cite

show abstract

“…More efficient catalysts are known, which can catalyze the formation of ammonia from elemental nitrogen and hydrogen gases at 500 K and standard pressure (Yue et al 2006;Avanier et al 2007). Others catalyze the formation of ammonia from nitrogen gas and a proton (Yandulov & Schrock 2003;Shilov 2003;Weare et al 2006) or from an activated nitrogen molecule and hydrogen gas (Nishibayashi et al 1998), in water at room temperature and pressure. The final step of combining a room temperature nitrogen reduction catalyst with a room temperature hydrogen splitting catalyst has not been achieved in the lab but is believed to be a realistic goal (Weare et al 2006).…”

Section: Nh 3 As a Biosignature Gas In A Reducingmentioning

confidence: 99%

“…Others catalyze the formation of ammonia from nitrogen gas and a proton (Yandulov & Schrock 2003;Shilov 2003;Weare et al 2006) or from an activated nitrogen molecule and hydrogen gas (Nishibayashi et al 1998), in water at room temperature and pressure. The final step of combining a room temperature nitrogen reduction catalyst with a room temperature hydrogen splitting catalyst has not been achieved in the lab but is believed to be a realistic goal (Weare et al 2006). Such a combined catalyst would make NH 3 from H 2 and N 2 and would generate energy (heat) from the reaction.…”

Section: Nh 3 As a Biosignature Gas In A Reducingmentioning

confidence: 99%

A Biomass-Based Model to Estimate the Plausibility of Exoplanet Biosignature Gases

Seager

Bains

2013

ApJ

114

144

View full text Add to dashboard Cite

Biosignature gas detection is one of the ultimate future goals for exoplanet atmosphere studies. We have created a framework for linking biosignature gas detectability to biomass estimates, including atmospheric photochemistry and biological thermodynamics. The new framework is intended to liberate predictive atmosphere models from requiring fixed, Earth-like biosignature gas source fluxes. New biosignature gases can be considered with a check that the biomass estimate is physically plausible. We have validated the models on terrestrial production of NO, H 2 S, and CH 4 , CH 3 Cl, and DMS. We have applied the models to propose NH 3 as a biosignature gas on a "cold Haber World" a planet with an N 2 -H 2 atmosphere, and to demonstrate why gases such as CH 3 Cl must have too great of a biomass to be a plausible biosignature gas on planets with Earth or early-Earth-like atmospheres orbiting a sun-like star. To construct the biomass models we developed a functional classification of biosignature gases, and found that gases (such as CH 4 , H 2 S, N 2 O) produced from life that extracts energy from chemical potential energy gradients will always have false positives because geochemistry has the same gases to work with as life does, and gases (such as DMS, CH 3 Cl) produced for secondary metabolic reasons are far less likely to have false positives, but because of their highly specialized origin are more likely to be produced in small quantities. The biomass model estimates are valid to one or two orders of magnitude; the goal is an independent approach to testing whether a biosignature gas is plausible rather than on a precise quantification of atmospheric biosignature gases and their corresponding biomasses.

show abstract

“…[1,[3][4][5]7,8] Even full catalytic cycles with molybdenum have been devised by Schrock et al with triamidoamine π-donor ligands (Scheme 1, A) [11] and by Nishibayashi et al with PNP-type pincer ligands (Scheme 1, B). [12] Complexes of the type trans-Mo 0 (N 2 ) 2 L 4 (L = phosphane) were investigated by Chatt, and they produce ammonia upon protonation with mineral acids, [1,2,13] whereas the analogous polymer-immobilized complexes [14] (characterized by the IR signature of end-on-coordinated N 2 ligands and gel-phase 31 P NMR spectroscopy) [15,16] fail to release ammonia.…”

Section: Introductionmentioning

confidence: 97%

Proton and Electron Transfer to a Polymer‐Supported Nitrido Molybdenum(VI) Complex

et al. 2013

View full text Add to dashboard Cite

Keywords: Molybdenum / N ligands / Nitrogen fixation / Supported catalysts / ImmobilizationThe protonation and reduction of nitrido and imido complexes are important steps during the reduction of dinitrogen to NH 3 mediated by transition-metal complexes. A polymerimmobilized analogue (P-2) of the Schrock-Yandulov nitrido molybdenum(VI) complex has been prepared from a sterically unencumbered polymer-anchored triamidoamine ligand (P-1) and [MoCl 3 N(CH 3 CN)] 4 as an "MoN" source. The polymer-confined nitrido complex has been protonated by [2,6-lutH][Al{OC(CF 3 ) 3 } 4 ] (2,6-lut = 2,6-lutidine) at the nitrido ligand to form the corresponding imido complex P-3, as shown by a variety of spectroscopic techniques and DFT calculations. Specifically, the NH stretching vibration of P-3 and the ND stretching vibration of the N-deuterated analogue P-3 D as well as the vibrations of the counterion are

show abstract

Catalytic reduction of dinitrogen to ammonia at a single molybdenum center

Cited by 129 publications

References 25 publications

Die katalytische Reduktion von Distickstoff zu Ammoniak mit Molybdän: Theorie und Experiment

Die katalytische Reduktion von Distickstoff zu Ammoniak mit Molybdän: Theorie und Experiment

A Biomass-Based Model to Estimate the Plausibility of Exoplanet Biosignature Gases

Proton and Electron Transfer to a Polymer‐Supported Nitrido Molybdenum(VI) Complex

Contact Info

Product

Resources

About