洞見 - Catalysis - # Hydroamination of Alkenes with Dinitrogen and Titanium Polyhydrides

Direct Hydroamination of Alkenes Using Dinitrogen and Titanium Polyhydrides

Q: What are the potential limitations or challenges in scaling up this hydroamination process for industrial-scale production of alkyl amines?

Scaling up the hydroamination process for industrial-scale production of alkyl amines may face challenges such as the need for efficient catalyst recovery and recycling, as the use of titanium polyhydrides could pose difficulties in this aspect. Additionally, the cost associated with the synthesis and maintenance of the multinuclear hydride framework could be a limiting factor. Moreover, the selectivity and yield of the reaction at a larger scale need to be carefully optimized to ensure economic viability. The potential safety concerns related to handling reactive nitrogen species and the need for specialized equipment for large-scale N2 activation could also be significant challenges in industrial implementation.

Q: How does the selectivity and efficiency of this method compare to other existing approaches for the synthesis of alkyl amines?

The hydroamination method using a trititanium hydride framework exhibits high selectivity and efficiency compared to other existing approaches for alkyl amine synthesis. The ability of the catalyst to activate both alkenes and N2, leading to selective C-N bond formation, is a significant advantage. This method offers a direct route to alkyl amines from abundant and easily accessible molecules like dinitrogen and feedstock alkenes, eliminating the need for prefunctionalized electrophilic carbon sources. The computational studies revealing key mechanistic details further support the selectivity and efficiency of this approach, making it a promising alternative to traditional methods relying on Haber-Bosch-derived ammonia.

Q: What other types of abundant feedstocks and small molecules could be leveraged in a similar multinuclear hydride framework to produce a wider range of nitrogen-containing organic compounds?

In addition to dinitrogen and alkenes, other abundant feedstocks and small molecules that could be leveraged in a multinuclear hydride framework for the production of a wider range of nitrogen-containing organic compounds include carbon monoxide (CO), carbon dioxide (CO2), and various unsaturated hydrocarbons. By utilizing these readily available molecules, it may be possible to synthesize diverse nitrogen-containing compounds such as amides, imines, and heterocycles through selective C-N bond formation. The versatility of the multinuclear hydride framework in activating and functionalizing different small molecules opens up opportunities for the sustainable synthesis of various nitrogen-containing organic compounds with potential applications in pharmaceuticals, materials, and agrochemicals.

核心概念

A novel strategy for the direct transformation of dinitrogen and simple alkenes into alkyl amines using a trititanium hydride framework.

摘要

The content describes a new approach for the direct hydroamination of alkenes using dinitrogen (N2) and titanium polyhydrides. The key highlights are:

Conventional alkyl amine synthesis relies on the Haber-Bosch process and prefunctionalized electrophilic carbon sources, which is challenging.
The authors report a method to activate both N2 and simple alkenes simultaneously using a trititanium hydride framework, leading to selective C-N bond formation.
The resulting alkyl amines are obtained after further hydrogenation and protonation steps.
Computational studies provide insights into the mechanism of N2 activation and selective C-N bond formation within the multinuclear hydride framework.
This work demonstrates a novel strategy to transform abundant feedstocks like N2 and hydrocarbons into nitrogen-containing organic compounds.

客製化摘要

使用 AI 重寫

產生引用格式

翻譯原文

翻譯成其他語言

產生心智圖

從原文內容

前往原文

www.nature.com

統計資料

The article does not provide any specific numerical data or metrics to extract.

引述

"An ideal synthesis of alkyl amines would involve the direct use of abundant and easily accessible molecules such as dinitrogen (N2) and feedstock alkenes1-4."
"This work demonstrates a strategy for the transformation of N2 and simple hydrocarbons into nitrogen-containing organic compounds mediated by a multinuclear hydride framework."

從以下內容提煉的關鍵洞見

Hydroamination of alkenes with dinitrogen and titanium polyhydrides - Nature

by Takanori Shi... 於 www.nature.com 06-17-2024

https://www.nature.com/articles/s41586-024-07694-5

Hydroamination of alkenes with dinitrogen and titanium polyhydrides - Nature

深入探究

What are the potential limitations or challenges in scaling up this hydroamination process for industrial-scale production of alkyl amines?

Scaling up the hydroamination process for industrial-scale production of alkyl amines may face challenges such as the need for efficient catalyst recovery and recycling, as the use of titanium polyhydrides could pose difficulties in this aspect. Additionally, the cost associated with the synthesis and maintenance of the multinuclear hydride framework could be a limiting factor. Moreover, the selectivity and yield of the reaction at a larger scale need to be carefully optimized to ensure economic viability. The potential safety concerns related to handling reactive nitrogen species and the need for specialized equipment for large-scale N2 activation could also be significant challenges in industrial implementation.

How does the selectivity and efficiency of this method compare to other existing approaches for the synthesis of alkyl amines?

The hydroamination method using a trititanium hydride framework exhibits high selectivity and efficiency compared to other existing approaches for alkyl amine synthesis. The ability of the catalyst to activate both alkenes and N2, leading to selective C-N bond formation, is a significant advantage. This method offers a direct route to alkyl amines from abundant and easily accessible molecules like dinitrogen and feedstock alkenes, eliminating the need for prefunctionalized electrophilic carbon sources. The computational studies revealing key mechanistic details further support the selectivity and efficiency of this approach, making it a promising alternative to traditional methods relying on Haber-Bosch-derived ammonia.

What other types of abundant feedstocks and small molecules could be leveraged in a similar multinuclear hydride framework to produce a wider range of nitrogen-containing organic compounds?

In addition to dinitrogen and alkenes, other abundant feedstocks and small molecules that could be leveraged in a multinuclear hydride framework for the production of a wider range of nitrogen-containing organic compounds include carbon monoxide (CO), carbon dioxide (CO2), and various unsaturated hydrocarbons. By utilizing these readily available molecules, it may be possible to synthesize diverse nitrogen-containing compounds such as amides, imines, and heterocycles through selective C-N bond formation. The versatility of the multinuclear hydride framework in activating and functionalizing different small molecules opens up opportunities for the sustainable synthesis of various nitrogen-containing organic compounds with potential applications in pharmaceuticals, materials, and agrochemicals.