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Coordination compounds of boron trifluoride with cyclicimines.Vandrish, George Edward. January 1968 (has links)
No description available.
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Coordination compounds of boron trifluoride with cyclicimines.Vandrish, George Edward. January 1968 (has links)
No description available.
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(1) Synthetic Application of 4-Hydroxypiperidine (2) Synthetic Application of 4-HydroxyprolinePai, Chun-Li 08 June 2006 (has links)
We present the synthetic studies of coerulescine, horsfiline, and
streptorubin B in this report. And we also present the new
synthesis of 3-arylpyrrolines and cis-3,4-diarylpyrrolidines via
an easy and straightforward pathway in this report. All of these
researches are using 4-hydroxypiperidine and 4-hydroxyproline
as the starting material.
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New methods for nucleophilic fluorinationCresswell, Alex January 2011 (has links)
This thesis describes investigations into the utility of boron fluorides and tetrafluoroborates as sources of nucleophilic fluorine. Chapter 1 discusses the history and importance of the field of organofluorine chemistry and outlines some of the principle motivations for the site-selective fluorination of organic molecules. Some of the most commonly useed methods of nucleophilic fluorination are briefly surveyed, with an emphasis on the formation of fluorinated stereogenic centres. Literature precedent for the use of tetrafluoroborates and boron trifluoride as nucleophilic fluorinating agents is also presented. Chapter 2 describes the development of a highly regio- and stereoselective S<sub>N</sub>i-type ring-opening fluorination of trans-β-substituted aryl epoxides using BF₃●OEt₂ as a nucleophilic fluorinating agent. This robust and scalable protocol grants efficient access to a variety of functionalised benzylic fluoride building blocks, and provides a solution to the problem of stereocontrol in the synthesis of this class of compounds. To highlight the utility of the resultant syn-fluorohydrins in the synthesis of stereodefined β-fluoro β-aryl amines, their elaboration to a range of aryl-substituted β-fluoroamphetamines is demonstrated. Chapter 3 introduces the concept of tuning the reactivity of BF₃ by replacing one or two of the fluoro ligands on boron for electron-donating alkoxy group(s). On this basis, pinacolatoboron fluoride (pinBF) [which may be prepared in situ by pre-mixing BF₃●OEt₂ and bis(O-trimethylsilyl)pinacol] is identified as a superior reagent to BF₃●OEt₂ for the ring-opening fluorination of trans-β-substituted aryl epoxides bearing electron-rich aryl groups. Chapter 4 details a highly regioselective and stereospecific S<sub>N</sub>2-type ring-opening fluorination of 2,3- and 3,4-epoxy amines using HBF₄●OEt₂ as a nucleophilic flurine source. The reactions are both operationally simple to perform and readily scalable, and proceed to completion within 5 min at ambient temperature, providing a highly practical and economical route to stereodefined amino fluorohydrins. To highlight the synthetic utility of this reaction in the preparation of pharmaceutically-important β-fluoro amines, a concise de novo asymmetric synthesis of (S,S)-3-deoxy-3-fluorosafingol is performed. Chapter 5 chronicles the successful development of a protocol for the direct hydroxyfluorination of allylic amines to the corresponding amino fluorohydrins, using m--CPBA as the oxidant and HBF₄●OEt₂ in a dual role as both the Brønstead acid N-protecting agent and nucleophilic fluorine source. With chiral allylic amines which are conformationally biased or constrained, the diastereofacial selectivity of the reaction can be controlled by altering the concentration of HBF₄●OEt₂ employed in the reaction, allowing for a diastereodivergent hydroxyfluorination process. The synthetic utility of this methodology is demonstrated via its application to the diastereodivergent synthesis of 4-deoxy-4-fluoro-L-xylo-phytosphingosine and 4-deoxy-4-fluoro-L-lyxo-phytosphingosine, each in 5 steps from Garner's aldehyde. Chapter 6 contains full experimental procedures and characterisation data for all compounds synthesised in chapters 2, 3, 4 and 5.
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Interaction of Acid/Base Probe Molecules with Specific Features on Well-Defined Metal Oxide Single-Crystal SurfacesAbee, Mark Winfield 24 September 2001 (has links)
Acid/Base characterizations of metal oxide surfaces are often used to explain their catalytic behavior. However, the vast majority of these studies have been performed on powders or supported oxides, and there is very little information available in the literature on the interaction of acid/base probe molecules with well-defined oxide surfaces of known coordination geometry and oxidation state. The well-defined, single crystal surfaces of Cu₂O (111), SnO₂ (110), and Cr₂O₃ (101̲2) were investigated for their acid/base properties by the interactions between the probe molecules and the well-defined surface features. The adsorption of NH₃ at cation sites was used to characterize the Lewis acidity of SnO₂ (110) and Cu₂O (111) surfaces. The adsorption of CO₂, a standard acidic probe molecule, was used to characterize the Lewis basicity of the oxygen anions on SnO₂ (110), Cu₂O (111) , and Cr₂O₃ (101̲2) surfaces. BF₃, while not a standard probe molecule, has been tested as a probe of the Lewis basicity of the oxygen anions on SnO₂ (110) and Cr₂O₃ (101̲2).
By studying probe molecules on well-defined metal oxide surfaces with known coordination geometry and oxidation state, an overall evaluation of NH₃, CO₂, and BF₃ as probe molecules can be made using the surfaces studied. NH₃ probed differences in Lewis acidity of Sn cations on SnO₂ (110), which had differences in coordination environments and oxidation states. But, NH₃ adsorption failed to provide any direct information on differences in Lewis acidity of Cu cations in different local coordination geometries on Cu₂O (111). CO₂ is a poor probe of the Lewis basicity of oxygen anions on the metal oxide surfaces studied here. CO₂ does not strongly adsorb to either SnO₂ (110) or Cu₂O (111). On Cr₂O₃ (101̲2), CO₂ does interact with oxygen sites but in two different coordinations, which vary with surface condition, making a comparison of basicity difficult. In the cases studied here, CO₂ either does not adsorb, or it does not provide a clear set of results that can be related simply to Lewis basicity. BF₃ seems to be a much better probe of the Lewis basicity than CO₂ for the well-defined metal oxide surfaces studied here. On SnO₂ (110) and Cr₂O₃ (101̲2), the boron atom of BF₃ directly interacts with oxygen sites by accepting their electrons. BF₃ thermal desorption seems to provide a direct measure of the Lewis basicity of different surface oxygen species as long as they are thermally-stable in vacuum. / Ph. D.
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