#olefin

Dissolution of a Grubbs type olefin metathesis catalyst in dichloromethane. 

Olefin metathesis reaction is a “modern” transformation used in organic chemistry. This reaction allows the exchange of substituents between different olefins. As a simplified scheme this happens: 

This reaction was first used in petroleum reformation for the synthesis of higher olefins (Shell higher olefin process - SHOP), with nickel catalysts under high pressure and high temperatures. Nowadays, even polyenes with MW > 250,000 are produced industrially in this way.

Grubbs' catalysts are a series of transition metal carbene complexes used as catalysts for olefin metathesis. They are named after Robert H. Grubbs, the chemist who supervised their synthesis. Several generations of the catalyst have been developed. Grubbs' catalysts tolerate many functional groups in the alkene substrates, are air-tolerant, and are compatible with a wide range of solvents. For these reasons, Grubbs' catalysts have become popular in synthetic organic chemistry. Some of the most popular Grubbs catalysts: 

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Production Engineer (Olefin/Aromatics) at Sofomation FZ – Jubail

Job Description Chemical engineering degree from an approved university. Total industrial experience shall not be less than 12 years. • Experience on Thermal Steam Cracker (olefin units) and Pygas Hydrogenation / Extraction for Aromatics technology with operation of not less than 10 years. Required to have an understanding of a DCS system. Must be able to provide development and review of…

​Pernah mendengar istilah petrokimia? Apa ya yang dimaksud petrokimia itu? Petrokimia adalah suatu industri yang bergerak pada pengolahan bahan kimia dengan mengunakan bahan baku dari hasil dari proses pengolahan minyak bumi dan gas bumi, dari pengertian tersebut jelas kita telah mengerti mengapa kedua industri tersebut memiliki hubungan yaang erat. Pola perkembangan industri petrokimia…

New method dramatically simplifies olefin synthesis

Chemists at The Scripps Research Institute (TSRI) have discovered a new method that greatly simplifies, and in many cases enables for the first time, the making of a vast range of organic molecules.

The new method, decarboxylative alkenylation, easily turns carboxylic acids, a relatively cheap, abundant and diverse class of compounds, into alkenes (also called olefins), another large family of compounds commonly used for pharmaceuticals and other applications. It thus should facilitate the discovery and development of a great variety of new drugs and other chemical products.

“This method dramatically simplifies the syntheses of olefins; in fact, it has really changed the way I think about making molecules,” said principal investigator Phil Baran, Darlene Shiley professor of chemistry at TSRI.

The method, published in the edition of Nature, essentially supersedes reactions that have been in chemistry textbooks and in widespread industrial and academic use for decades. Chief among these is the Wittig reaction, discovered in 1954, for which Germany’s Georg Wittig was awarded a share of the Nobel Prize for Chemistry in 1979. The Wittig reaction enables the making of many olefins from precursor compounds, and even though it tends to require a many-step process, chemists have continued to rely heavily on it up to the present.

“Organic chemists have endured this burdensome 'analog' process for decades with little complaint,” Baran said. “Now with this new method we’re bringing olefination into the digital era.”

The new method originated with a breakthrough by Baran and his laboratory that was described a year ago in the Journal of the American Chemical Society. That transformation allowed the building of many complex drug and other molecules starting from carboxylic acids, using inexpensive metal catalysts.

The new method enables chemists to turn carboxylic acids into olefins in relatively few steps, using nickel or iron catalysts. In one demonstration, Baran’s team produced sterol acetate, a natural olefin with potential as a drug building block, from a standard precursor in two steps-whereas the traditional procedure using the Wittig reaction requires seven steps. To show the vast scope of the new method, Baran’s team employed it to make nearly 70 diverse olefins with reactions that were greatly streamlined and simplified compared to traditional methods.

The new method allows chemists much better control over the geometry of the resulting molecules, and moreover simplifies the conceptual side of olefin synthesis.

The paper includes 15 other total or near-total syntheses from cheap starting compounds of natural products that were previously difficult or impractical to synthesize, including prostaglandins, aureonitol and tocotrienols.

The pharmaceutical company Bristol-Myers Squibb, which has a Research Agreement with TSRI, works with the Baran Laboratory under the Agreement and is already using the new method in at least one of its drug development programs.

Baran noted that another collaborator, the contract drug-maker Asymchem, has also demonstrated the suitability of the new method for pharmaceutical manufacturing by scaling up a sample reaction to yields on the order of a kilogramme.

The co-lead authors of the paper, “Decarboxylative Alkenylation,” were Jacob Edwards and Rohan Merchant, doctoral candidates in the Baran Laboratory. Other co-authors were Kyle McClymont, Kyle Knouse, Tian Qin and Lara Malins of TSRI; Benjamin Vokits, Scott Shaw and Martin Eastgate of Bristol-Myers Squibb; and Deng-Hui Bao, Fu-Liang Wei and Ting Zhou of Asymchem.