Max. Pressure | 1500 bar (22,000 psi) depending on configuration | up to 1000 bar (15,000psi) | 103.4 Mpa or 1034 bar or 15000 psi | Up to 1500 bar (22,000 psi) | up to 1000 bar (15,000psi) |
Description | Experience the high-resolution fractionation of the Thermo Scientific™ Vanquish™ Analytical Purification LC Systems featuring the integrated Thermo Scientific™ Vanquish™ Fraction Collector. Achieve efficient purification by combining the separation power of the Thermo™ Experience the high-resolution fractionation of the Thermo Scientific™ Vanquish™ Analytical Purification LC Systems featuring the integrated Thermo Scientific™ Vanquish™ Fraction Collector. Achieve efficient purification by combining the separation power of the Thermo™ Scientific™ Vanquish HPLC or UHPLC Systems with precise fractionation allowing for compound characterization or purification tailored for your processes.... Read More | The Thermo Scientific™ UltiMate™ 3000 Rapid Separation Quaternary System supports the use of up to four solvents at up to 15,000 psi (100 MPa, 1000 bar) for fast routine applications or method development. With excellent flow stability, a large choice of detection technologies and a recommended flowThe Thermo Scientific™ UltiMate™ 3000 Rapid Separation Quaternary System supports the use of up to four solvents at up to 15,000 psi (100 MPa, 1000 bar) for fast routine applications or method development. With excellent flow stability, a large choice of detection technologies and a recommended flow rate range from 200µL/min to 8.0mL/min, it adapts easily for multiple users running diverse methods in routine environments as well as research and development laboratories. It is your most flexible system choice for established and novel liquid chromatography workflows.... Read More | The Thermo Scientific ™ UltiMate™ 3000 Rapid Separation RS Dual System can, for example, inject the same sample into 2 flow paths and columns. With its two fully integrated, independently operating gradient pumps and smart column switching, it allows fast configuration of online-SPE, parallel or The Thermo Scientific ™ UltiMate™ 3000 Rapid Separation RS Dual System can, for example, inject the same sample into 2 flow paths and columns. With its two fully integrated, independently operating gradient pumps and smart column switching, it allows fast configuration of online-SPE, parallel or tandem (UHP)LC, inverse gradient operation and fast application switching. Rapid Separation Systems fully support longer (up to 250mm) sub-2µm particle column technologies and can, by default, also operated as regular single flowpath system.... Read More | Use the Thermo Scientific™ Vanquish™ Duo UHPLC Systems to support four workflows (Dual LC, Tandem LC or LC-MS, Transcend Duo LX-2 and Inverse Gradient) by combining two flow paths in one integrated UHPLC solution. These workflows improve your productivity by saving time, reducing cost per sample, Use the Thermo Scientific™ Vanquish™ Duo UHPLC Systems to support four workflows (Dual LC, Tandem LC or LC-MS, Transcend Duo LX-2 and Inverse Gradient) by combining two flow paths in one integrated UHPLC solution. These workflows improve your productivity by saving time, reducing cost per sample, increasing capacity and using your resources more efficiently. Vanquish Duo UHPLC Systems expand the benefits of the Vanquish platform without compromising performance, robustness, or ease-of-use.... Read More | The Thermo Scientific™ Vanquish™ Flex Quaternary system provides state-of-the-art quaternary solvent blending. As a member of the Thermo Scientific Vanquish UHPLC product line, the Vanquish Flex Quaternary system delivers new benchmarks in accuracy, precision, and sensitivity with a state-of-the-artThe Thermo Scientific™ Vanquish™ Flex Quaternary system provides state-of-the-art quaternary solvent blending. As a member of the Thermo Scientific Vanquish UHPLC product line, the Vanquish Flex Quaternary system delivers new benchmarks in accuracy, precision, and sensitivity with a state-of-the-art quaternary low-pressure pump.... Read More |