The DSC 6000 gives you all the advantages of the DSC 4000 and more. Designed for research application, it comes with Modulated Temperature DSC (MT-DSC) technology for easier data interpretation and new capabilities for product development.
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Typical applications for the DSC 6000:
|21 CFR Part 11 Compatible||Yes|
|Maximum Temperature||450 °C|
|Minimum Temperature||-180 °C|
|Technology Type||Thermal Analysis|
Differential scanning calorimetry (DSC) is a commonly used technique for studying polymeric; pharmaceutical; and energetic; materials. When considering which type of DSC to use to perform a specified measurement one typically chooses either a Power Compensation, or heat flux design.
A commonly studied sample by Differential Scanning Calorimetry (DSC) is thermoset epoxy materials where the sample is heated to an elevated temperature, at which point it starts to cross-link. When studying these types of materials, multiple transitions are typically sought after. This application note shows why PerkinElmer® DSC 6000 is an excellent tool for measuring these thermal events, not only in the typical testing methods, but also thanks to the expanded StepScan (MT-DSC) capability of the instrument.
This application note describes HyperDSC™ as a DSC analysis technique by PerkinElmer with fast scanning rates enabling increased sensitivity and high throughput for applications in polymers and pharmaceuticals.
One of the more commonly used thermoplastics is polypropylene because of its versatility. As with all thermoplastics, it is important to characterize the thermophysical properties of polypropylene, including melting temperature, percent crystallinity, crystallization when cooling from the melt, and the glass transition temperature, Tg. It is essential to analyze the thermophysical properties of the end product for quality assurance purposes. Thermal analysis provides an ideal means of characterizing the properties of polymers, including polypropylene. Differential Scanning Calorimetry (DSC) is a particularly useful technique for the characterization of polypropylene. This application note demonstrates how the high performance DSC from PerkinElmer® can readily detect the Tg of polypropylene.
Today’s plastics are some of the most used materials on a global volume basis. Broadly integrated into today’s industrial and commercial lifestyles, they make a major, irreplaceable contribution to virtually every product category.
In this compendium you will find a wide range of applications for polymers, plastics, rubbers and advanced materials. Discover how to put these applications to work for you simply and efficiently.
This application note details the practical aspects of purity determination by differential scanning calorimetry (DSC) and explains the way that the purity calculation works. This will give thermal analysts sufficient information to make successful purity determinations using their calorimeters and understand how to avoid some of the common errors that may be encountered.
Quality control-monitoring and testing are important in ensuring the quality of palm oil. The quality control parameters are used to judge the quality of palm oil products and it can be monitored and tested to ensure that the palm oil is not deliberately or accidentally adulterated.
The regulations of 21 CFR Part 11 cover overall system compliance and include administrative, procedural and technical elements. Software alone cannot be compliant without the development and implementation of the other elements. PerkinElmer’s Pyris™ Enhanced Security software for Thermal Analysis instruments provide features that, when coupled with appropriate policies and procedures, fulfill the requirements for 21 CFR Part 11 compliance.
The differential scanning calorimeter (DSC) is a fundamental tool in thermal analysis. It can be used in many industries - from pharmaceuticals to polymers and from nanomaterials to food products. The information these instruments generate is used to understand amorphous and crystalline behavior, polymorph and eutectric transitions, curing and degree of cure, and many other material properties used to design, manufacture and test products.
The needs for polymer, pharmaceutical, chemicals, food and beverage, and environmental analyses are constantly changing due to innovation demands and regulation changes.
Evolved Gas Analysis (EGA) solutions combine multiple analytical technologies to empower speed and advanced information acquisition. Coupling Thermogravimetric Analyzer (TGA) systems with other analytical systems such as Gas Chromatography Mass Spectrometry (GC/MS) and Fourier Transform Infrared (FT-IR) Spectroscopy represents the most complete and advanced EGA solutions for gaining insights beyond decomposition of materials, by carrying out in-depth characterization of the evolved gases.
This comprehensive technology guide is your guide to understanding how hyphenation provides the insights - not just WHEN something has happened, but also WHAT happened.
Guide describing all UV/Vis spectroscopy, FT-IR spectroscopy, thermal analysis, hyphenation technique solutions for material characterization.
The DSC 6000 Installation and Hardware Guide provides an overview of instructions for the safe and proper installation of DSC 6000.
Poster summarizing solutions of thermal analysis, molecular spectroscopy, chromatography and hyphenated techniques for polymers focused on providing more insight into product performance and process optimization that make easier
The Polymer Market consists of a huge diversity of manufacturers of industrial products running many different processes yet still facing similar challenges. There is more and more pressure to achieve high product quality and reduce costs in order to stay one step ahead of the competition.
Product Certificate for DSC 4000 and DSC 6000