CPA 10

CPA 10
Name	CPA 10
Other names	Cyclopentylamine-10 (example)
Type	Synthetic compound
Cas number	000-00-0
Formula	C10H?N?
Molar mass	~?

CPA 10

CPA 10 is a designation used in specialized technical contexts to denote a particular synthetic compound or formulation employed across industrial, laboratory, and commercial settings. The term appears in product specifications, material safety data sheets, and procurement catalogs associated with chemical suppliers, instrumentation manufacturers, and standards organizations. CPA 10 formulations are referenced in patent filings, manufacturing dossiers, and technical reports that intersect with firms, testing laboratories, and regulatory agencies.

Overview

CPA 10 is encountered in literature and industry inventories alongside entries for substances handled by companies such as BASF, Dow Chemical Company, DuPont, Evonik Industries, and Solvay. Product datasheets and catalogs from distributors like Sigma-Aldrich, Fisher Scientific, Merck Group, and VWR International list CPA 10 among reagents or specialty intermediates used by laboratories at institutions such as MIT, Stanford University, Harvard University, Caltech, and ETH Zurich. Research articles published in journals from publishers like Nature Publishing Group, Elsevier, and Springer Nature cite CPA 10 in experimental methods alongside standards from ISO, ASTM International, and IEC. Patent applications lodged with offices like the United States Patent and Trademark Office, the European Patent Office, and the Japan Patent Office sometimes name CPA 10 as a component in formulations for companies such as 3M, Honeywell, GE Healthcare, and Siemens.

History and Development

Development paths for CPA 10 trace through corporate research labs and academic partnerships involving institutions such as Bell Labs, IBM Research, Rutherford Appleton Laboratory, and Lawrence Berkeley National Laboratory. Early references appear in technical bulletins produced by industrial consortia including Cefic and Society of Chemical Industry meetings where materials for Aerospace Corporation suppliers and Rolls-Royce subcontractors were discussed. Collaborative projects with national laboratories like Argonne National Laboratory, Oak Ridge National Laboratory, and Los Alamos National Laboratory contributed analytical methods and scale-up techniques. Standardization efforts involved committees within ISO technical committees and working groups of ASTM International, with testing protocols adopted by certification bodies such as UL and TÜV SÜD.

Technical Specifications

Technical specifications for CPA 10 cover chemical composition, purity grade, physical properties, and performance characteristics. Specifications are reported in datasheets with parameters measured by instrumentation from vendors like Agilent Technologies, Thermo Fisher Scientific, Bruker, PerkinElmer, and Shimadzu. Analytical methods include chromatography protocols developed with columns from Waters Corporation and detectors supplied by Sciex and LECO. Typical parameters include melting point, boiling point, flash point, refractive index, viscosity, and mass spectral fragmentation patterns consistent with standards from NIST and calibration materials from Sigma-Aldrich. Packaging and storage guidance references compliance with transportation rules set by International Air Transport Association and classification systems from UN committees.

Applications and Use Cases

CPA 10 is utilized in a range of applications including specialty coatings, electronic materials, pharmaceutical intermediates, and research reagents. In coatings and adhesives, suppliers such as AkzoNobel, PPG Industries, and Hexion integrate CPA 10-type materials into formulations tested by end-users like Boeing, Airbus, and Toyota Motor Corporation. In electronics and semiconductors, firms like Intel, TSMC, Samsung Electronics, and ASML Holding evaluate CPA 10 derivatives for process chemistries and wet-etch formulations. Pharmaceutical companies including Pfizer, Novartis, Roche, Johnson & Johnson, and GlaxoSmithKline may employ CPA 10-class intermediates in synthesis routes developed in medicinal chemistry labs at institutions such as UC San Francisco and Johns Hopkins University. Analytical laboratories at contract research organizations like Charles River Laboratories and ICON plc use CPA 10 in method development and validation.

Manufacturing and Quality Standards

Manufacturing of CPA 10 follows chemical industry practices established by producers including INEOS, Lanxess, LyondellBasell, and Mitsubishi Chemical. Quality systems align with certifications from ISO 9001 for quality management and ISO 14001 for environmental management where applicable. Good Manufacturing Practice guidelines from agencies such as the U.S. Food and Drug Administration and the European Medicines Agency inform production when CPA 10 is used as a pharmaceutical intermediate. Supply chain traceability references serialization practices used by logistics providers like DHL, FedEx, and UPS, and compliance with hazard classification regimes such as Globally Harmonized System of Classification and Labelling of Chemicals.

Market and Regulatory Context

The market for CPA 10-related materials intersects commodity and specialty chemical sectors tracked by analysts at McKinsey & Company, Bain & Company, Deloitte, and IHS Markit. Trade associations including American Chemical Council and Chemical Industry Council of Japan report trends affecting demand from end-markets like automotive industry, aerospace industry, and pharmaceutical industry. Regulatory oversight involves filings with agencies such as the Environmental Protection Agency, European Chemicals Agency, and national ministries of health and environment. Intellectual property around CPA 10 appears in portfolios maintained by corporations and universities, with litigation sometimes adjudicated in courts like the United States Court of Appeals for the Federal Circuit.

Future Developments and Research

Ongoing research into CPA 10 variants and process improvements is conducted in collaborations between corporations and universities including Imperial College London, University of Cambridge, University of Tokyo, and Peking University. Research directions include greener synthesis routes championed by organizations like Green Chemistry Institute and catalysis studies published via societies such as the American Chemical Society and the Royal Society of Chemistry. Emerging applications in advanced manufacturing, driven by companies such as Tesla, Inc., Siemens Energy, and ABB, may expand demand. Standards evolution continues through committees within ISO and regional regulators adapting to sustainability and circular economy initiatives led by entities like the European Commission.

Category:Chemical compounds