2704-78-1Relevant articles and documents
Nitrate ion photochemistry at interfaces: A new mechanism for oxidation of α-pinene
Yu, Yong,Ezell, Michael J.,Zelenyuk, Alla,Imre, Dan,Alexander, Liz,Ortega, John,Thomas, Jennie L.,Gogna, Karun,Tobias, Douglas J.,D'Anna, Barbara,Harmon, Chris W.,Johnson, Stanley N.,Finlayson-Pitts, Barbara J.
, p. 3063 - 3071 (2008)
The photooxidation of 0.6-0.9 ppm α-pinene in the presence of a deliquesced thin film of NaNO3, and for comparison increasing concentrations of NO2, was studied in a 100 L Teflon chamber at relative humidities from 72-88% and temperatures from 296-304 K. The loss of α-pinene and the formation of gaseous products were followed with time using proton transfer mass spectrometry. The yields of gas phase products were smaller in the NaNO3 experiments than in NO2 experiments. In addition, pinonic acid, pinic acid, trans-sobrerol and other unidentified products were detected in the extracts of the wall washings only for the NaNO3 photolysis. These data indicate enhanced loss of α-pinene at the NaNO3 thin film during photolysis. Supporting the experimental results are molecular dynamics simulations which predict that α-pinene has an affinity for the surface of the deliquesced nitrate thin film, enhancing the opportunity for oxidation of the impinging organic gas during the nitrate photolysis. This new mechanism of oxidation of organics may be partially responsible for the correlation between nitrate and the organic component of particles observed in many field studies, and may also contribute to the missing source of SOA needed to reconcile model predictions and field measurements. In addition, photolysis of nitrate on surfaces in the boundary layer may lead to oxidation of co-adsorbed organics. the Owner Societies.
Nickel-Catalyzed Selective Reduction of Carboxylic Acids to Aldehydes
Iosub, Andrei V.,Morav?ík, ?tefan,Wallentin, Carl-Johan,Bergman, Joakim
supporting information, p. 7804 - 7808 (2019/10/14)
The direct reduction of carboxylic acids to aldehydes is a fundamental transformation in organic synthesis. The combination of an air-stable Ni precatalyst, dimethyl dicarbonate as an activator, and silane reductant effects this reduction for a wide variety of substrates, including pharmaceutically relevant structures, in good yields and with no overreduction to alcohols. Moreover, this methodology is scalable, allows access to deuterated aldehydes, and is also compatible with one-pot utilization of the aldehyde products.
A selective, efficient and environmentally friendly method for the oxidative cleavage of glycols
García, Nuria,Rubio-Presa, Rubén,García-García, Patricia,Fernández-Rodríguez, Manuel A.,Pedrosa, María R.,Arnáiz, Francisco J.,Sanz, Roberto
, p. 2335 - 2340 (2016/05/19)
A catalytic methodology for the oxidative cleavage of vicinal diols is described as an advantageous alternative in terms of the environmental impact on classical methods involving toxic oxidants. The novel strategy is based on the use of dioxomolybdenum(vi) complexes as catalysts and dimethyl sulfoxide (DMSO) as an oxidant and displays high selectivity and a broad scope for glycol cleavage. In addition, the developed system is also useful for the oxidation of acyloins to diketones.
