Advanced separation and detection methods for supercritical fluid chromatography

超临界流体色谱的先进分离和检测方法

• 批准号: 239058-2011
• 负责人: Thurbide, Kevin
• 金额: $ 4.01万
• 依托单位: University of Calgary
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2013
• 资助国家: 加拿大
• 起止时间: 2013-01-01 至 2014-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=524552
• 关键词: Advanced; separation; detection; methods; supercritical

Replacing organic solvents with environmentally clean solvents is a growing area of concern and research. Supercritical fluids are widely used in this regard. They have gas and liquid-like properties that yield remarkable solvating and mass transport capabilities. Many laboratories coping with mounting hazardous waste and slow sample throughput are now using them to replace conventional isolation and analysis methods. Supercritical carbon dioxide is very popular due to its low cost, relative environmental compatibility and mild critical parameters. In supercritical fluid chromatography (SFC), it is used to transport sample components through a column that separates them for analysis, before it decompresses into a gas. In this way, SFC unites the dissolving power of liquid chromatography with a speed and separation capability similar to that of gas chromatography. However, supercritical carbon dioxide is non-polar and cannot well dissolve and separate polar molecules unless a polar modifier such as methanol is added. The flame ionization detector (FID) is very widely used in chromatography due to its excellent universal response towards organic compounds. Since methanol creates a noisy background signal in the FID, this detector cannot be used with modified SFC. Presently, the ability to separate polar compounds using modified supercritical carbon dioxide and detect them with the FID, or other novel universal detectors, would greatly assist various laboratories using SFC to monitor their processes and products. Frequent SFC users include the pharmaceutical, petroleum, and polymer industries, which are prevalent in Canada. Our research will: 1. Develop a new universal acoustic detector for modified SFC that can operate in the presence of methanol. 2. Evolve new methods of using only water (it has no FID response) and carbon dioxide to separate/analyze polar analytes with FID. 3. Exploit using short column SFC-FID methods to elute polar compounds without modifiers. And 4. Advance a potential new multiple flame detector for SFC to selectively sense sulfur and phosphorus analytes in organic solvents. We will compare the developed methods with current techniques, and validate them by analyzing various samples.

用环境清洁的溶剂代替有机溶剂是一个日益受到关注和研究的领域。超临界流体在这方面被广泛使用。它们具有类似气体和液体的性质，产生显着的溶剂化和质量传输能力。许多实验室正在处理日益增多的危险废物和缓慢的样品处理量，现在正在使用它们来取代传统的分离和分析方法。超临界二氧化碳由于其成本低、相对环境相容性和温和的临界参数而非常受欢迎。在超临界流体色谱（SFC）中，它用于将样品组分输送通过分离它们的柱进行分析，然后将其减压成气体。通过这种方式，SFC将液相色谱的溶解能力与气相色谱的速度和分离能力相结合。然而，超临界二氧化碳是非极性的，除非加入极性改性剂如甲醇，否则不能很好地溶解和分离极性分子。火焰离子化检测器（FID）因其对有机化合物具有良好的普适性响应，在色谱分析中得到了广泛的应用。由于甲醇在FID中产生噪声背景信号，因此该检测器不能与改进的SFC一起使用。目前，使用改进的超临界二氧化碳分离极性化合物并使用FID或其他新型通用检测器检测它们的能力将极大地帮助使用SFC的各种实验室监控其过程和产品。SFC的频繁用户包括制药、石油和聚合物行业，这些行业在加拿大很普遍。我们的研究将：1。开发一种新的通用声学检测器，用于改进的SFC，可以在甲醇的存在下工作。2.开发仅使用水（无FID响应）和二氧化碳的新方法，以使用FID分离/分析极性分析物。3.探索使用短柱SFC-FID方法在没有改性剂的情况下对极性化合物进行分离。和4.提出一种潜在的新型多火焰检测器，用于SFC选择性地检测有机溶剂中的硫和磷分析物。我们将比较开发的方法与当前的技术，并通过分析各种样品验证它们。