Organometallic Approaches to Nitrogen Fixation

固氮的有机金属方法

• 批准号: RGPIN-2014-04220
• 负责人: Fryzuk, Michael
• 金额: $ 7.29万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=587676
• 关键词: Organometallic; Approaches; Nitrogen; Fixation

One of the grand challenges in chemistry is the discovery of a mild process for conversion of molecular nitrogen (N2) into higher value organo-nitrogen containing species, such as amines. Ammonia (NH3) is produced worldwide by the Haber-Bosch process, which is over 100 years old, and is still the only process that uses N2 as a feedstock on an industrial scale. In contrast, the isoelectronic molecule carbon monoxide (CO) is used in a variety of different industrial processes, such as hydroformylation, the acetic acid synthesis, and carbonylation. The fact that even after 100 years we have not been successful at developing a new industrial process for molecular nitrogen is embarrassing, but at the same time, a reminder of the level of difficulty of the problem of using this unreactive small molecule in an industrial setting. On the biological side, nature produces ammonia from atmospheric N2 using the enzyme Nitrogenase in a process referred to as nitrogen fixation; information about the active site of this enzyme, the Fe-Moco factor, is known but the details on how this process occurs at the active site are unknown. However, there have been some exciting recent developments in nitrogen fixation chemistry that keep this dream alive. A number of homogeneous model systems have been developed that produce ammonia from N2 using stoichiometric amounts of protons and reductants; these are not industrially relevant but do illustrate ingenious ways to approach this problem and speak to the importance of ligand design in the makeup of the metal complex that acts as the catalyst. From the biological side, the recent determination of the bridging carbide at the active site of the Fe-Moco enzyme is particularly elegant. More recently, it has been proposed that the hydrogen production that accompanies ammonia formation by nitrogenase is relevant to the N2 binding step and implicates Fe hydrides. This proposal will explore new avenues of research that take advantage of great advances made in the realm of organometallic chemistry and apply them to the area of dinitrogen activation. It is anticipated that new fundamental knowledge will accrue that will expand our present understanding of how the ubiquitous N2 molecule can be harnessed for future generations. It is also expected that this research will provide training to new scientists that will be relevant to green chemistry and sustainability.

化学中的重大挑战之一是发现用于将分子氮（N2）转化为更高价值的含有机氮物质（例如胺）的温和方法。 氨（NH3）在全球范围内通过哈伯-博世工艺生产，该工艺已有100多年的历史，并且仍然是唯一一种在工业规模上使用N2作为原料的工艺。 相比之下，等电子分子一氧化碳（CO）用于各种不同的工业过程，如加氢裂化、乙酸合成和羰基化。 事实上，即使在100年后，我们还没有成功地开发出一种新的分子氮工业工艺，这是令人尴尬的，但与此同时，提醒人们在工业环境中使用这种不反应的小分子的困难程度。在生物学方面，自然界使用固氮酶从大气N2中产生氨，这一过程被称为固氮;关于这种酶的活性位点的信息，Fe-Moco因子，是已知的，但关于这个过程如何在活性位点发生的细节是未知的。然而，最近在固氮化学方面取得了一些令人兴奋的进展，使这个梦想得以实现。 已经开发了许多均相模型系统，使用化学计量的质子和还原剂从N2生产氨;这些与工业无关，但确实说明了解决这个问题的巧妙方法，并说明了配体设计在构成作为催化剂的金属络合物中的重要性。从生物学的角度来看，最近确定的桥碳化物的活性位点的铁-Moco酶是特别优雅的。 最近，有人提出，伴随固氮酶形成氨的氢产生与N2结合步骤有关，并暗示Fe的存在。 该提案将探索新的研究途径，利用有机金属化学领域取得的巨大进展，并将其应用于二氮活化领域。 预计新的基础知识将不断积累，这将扩大我们目前对无处不在的N2分子如何为后代利用的理解。 预计这项研究还将为与绿色化学和可持续性有关的新科学家提供培训。