Traceability in Chemical Measurement

P. De Bievre: Editorial/Introduction to this volume.- P. De Bievre, R. Kaarls, H.S. Peiser, S.D. Rasberry, W.P. Reed: Measurement principles for traceability in chemical analysis.- P. De Bievre: et al.: Protocols for traceability in chemical analysis, Part 1.- P. De Bievre et al.: Protocols for traceability in chemical analysis, Part 2.- R. Dybkaer: Metrological traceability in laboratory medicine.- F. Adams: Traceability and analytical chemistry.- P. De Bievre: Do interlaboratory comparisons provide traceability?.- R. Dybkaer: From total allowable error via metrological traceability to uncertainty of measurement of the unbiased result.- M. Buzoianu: Practical considerations on the traceability to conventional scales.- P. De Bievre: Traceability of (values carried by) reference materials.- A. Williams: What can we learn from traceability in physical measurements?.- W. Richter: How to achieve international comparability for chemical measurements?.- P. De Bievre: The key elements of traceability in chemical measurement: agreed or still under debate?.- B. King: The practical realization of the traceability of chemical measurements standards.- M. Mariassy et al.: Link to the SI via primary direct methods.- A. Zschunke: The role of reference materials.- B. Belanger: The measurement assurance concept in calibration and traceability at NBS/NIST.- I. Kuselman et al.: Lifetime of the traceability chain in chemical measurement.- St. Rasberry: Proficiency evaluation as a traceability link in chemical metrology.- P. Armishaw, B. King, R.G. Millar: Achieving traceability in chemical measurement - a metrological approach to proficiency testing.- A. Wallard: Traceability issues in physics.- W. Richter: Comparative study of the presentations at the CCQM Workshop on Traceability.- M. Muller: Traceability in Laboratory Medicine.- M. Lipp: Testing for foods derived from modern biotechnology: Opportunities and limitations for metrology.- W. Richter, Guttler: A nationaltraceability system for chemical measurements.- L. Siekmann: Establishing Measurement Traceability in Clinical Chemistry.- M. Kimberly: Clinical laboratory reference networks.- Ph. Taylor: One way of disseminating Reference Values with demonstrated Traceability and demonstrated Uncertainty to Field Laboratories: IMEP.- E. Volkert: Implementation of Traceability - Needs and Perspective of the IVD Industry.- G. Holcombe, R. Lawn, M. Sargent: Improvements in efficiency of production and traceability for certification of reference materials.- M. Buzoianu, H.Y. Aboul-Enein: Traceable measurement in clinical laboratories.- Ch. M. Beck: A traceability protocol to the SI by gravimetric analysis.- V.P. Antipin, A.A. Grigorieva: Reference Samples for analysis of gas impurities in aluminium and titanium alloys: Features of production, certification and usage to ensure traceability of results.- S. Duta: The use of certified reference materials in the Romanian traceability scheme.- P. Spitzer: Traceable measurements of pH.- P.E. Holland et al.: The development of gas standards and calibration techniques for measurement of vehicle, aircraft and industrial emissions, natural gas, occupational exposure and air quality.- I. Sperlingova et al.: Problems of traceability of total protein and catecholamine determinations in human urine.- M. Sega: Traceability in routine chemical measurements: an example of application in the determination of CO2 at atmospheric concentration.- Glavic-Cindro et al.: Traceability of measurement results of the effective acquisition time in gamma-ray spectrometry implemented by the pulser method.- Y. Mitani et al.: Traceability and Practice in Metrology in Chemistry.- P. Charlet, A. Marschal: Benefits of the implementation of a metrological structure for water analyses.- L. Bruggemann, R. Wennrich: Traceability of results of chemical measurements concerning a linear calibration.- W.P. Reed: Traceability, is it what we really want in our