National Institute of Standards and Technology (NIST) fossil fuel Standard Reference Materials (SRMs) continue to be in high demand by the petroleum industry and the fossil fuel-based electric utility industries. In the past, the measurement of sulfur in fuels and combustion systems has received principal attention, but mercury emissions are now attracting regulatory interest because of the potential risk to human health. Measurements of carbon will also become more important as trading systems come into effect to combat climate change effects from the release of carbon dioxide into the atmosphere. The generation of large quantities of coal combustion by-products, having significant levels of unwanted contaminants, also represents a significant measurement challenge.
Until newer sustainable energy technologies can be deployed, fossil fuels will remain the principal source of energy for the developed world. Coal, oil, and natural gas account for over 85 % of the energy consumed by the U.S. Along with the need for more efficient utilization of these resources, there is a need for the environmental management of electric utility combustion emissions and waste products, and pollutant emissions from vehicles using liquid fuels. Sulfur, mercury, and carbon are (or will likely be) subject to environmental regulations. Management of energy production from the specification of fossil fuel raw materials to the release of environmental pollutants from combustion processes, together with risk assessment of bulk waste products, such as fly-ash and flue gas de-sulfurization (FGD) gypsum, will require accurate analytical measurements, and there will undoubtedly be increasing demand for relevant reference materials to support the emerging needs of these markets.
Additional Technical Details:
The fossil fuel SRM program is now 40 years old, and the current inventory of fossil fuel reference materials includes coals, cokes, residual fuel oils, distillates and gasolines. Many of these have been certified, and will continue to be certified, using high-accuracy methods such as isotope dilution mass spectrometry. A challenge in recent years has been the assignment of accurate mercury concentrations in bituminous and sub-bituminous coals and at lower levels in unrefined crude oil and diesel fuel. This has been achieved through the development of a method using high-pressure Carius digestion coupled with isotope dilution mass spectrometry. Similarly, new methods for the determination of chlorine in coals using instrumental neutron activation and thermal ionization mass spectrometry have resulted in the provision of certified values for this element in several of the coal SRMs. In anticipation of demand for standards to support carbon accounting activities, new methods for the high-accuracy measurement of carbon in new and existing fossil fuel SRMs will be a priority in the near future. New instrumentation consisting of multi-collector inductively coupled plasma mass spectrometry has recently been acquired, and this will be assessed for the measurement of carbon in fossil fuels by isotope dilution.
Click on an SRM below to be transferred to a page from which you can access its Certificate of Analysis.
1635 Trace Elements in Coal (Sub-bituminous)
Start Date:January 1, 1970
Lead Organizational Unit:mml
Franklin R. Guenther
John L. Molloy
John R. Sieber
Robert D. Vocke
Related Programs and Projects:
Paulsen, P. J. and Kelly, W. R., Determination of Sulfur as Arsenic Mono-sulfide Ion by Isotope Dilution Thermal Ionization Mass Spectrometry, Anal. Chem., 56:708-713 (1984).
Fassett, J. D. and Kelly, W. R., Interlaboratory Isotopic Ratio Measurement of Nanogram Quantities of Uranium and Plutonium on Resin Beads by Thermal Ionization Mass Spectrometry, Anal. Chem., 56:550-556 (1984).
Kelly, W. R. and Paulsen, P. J., Precise and Accurate Determination of High Concentrations of Sulfur by Isotope Dilution Thermal Ionization Mass Spectrometry, Talanta, 31:1063-1068 (1984).
Kelly, W. R. and Paulsen, P. J., Determination of Sulfur in NBS Coals by Isotope Dilution Thermal Ionization Mass Spectrometry, in Methods and Procedures used at the National Bureau of Standards to Certify Sulfur in Coal SRMs for Sulfur Content, Calorific Value, Ash Content, T. E. Gills, Ed., National Bureau of Standards (U.S.), Spec. Publ. 260-94:7-13 (1984).
Kelly, W. R., Murphy, K. E., Paulsen, P. J., Vocke, R. D., Accurate and Precise Determination of Sulfur in Coal SRMs by Thermal Ionization Mass Spectrometry, Fuel, 72:713 (1993).
Kelly, W. R., Paulsen, P. J., Murphy, K. E., Vocke, Jr., R. D., and Chen, L.-T., Determination of Sulfur in Fossil Fuels by Isotope Dilution-Thermal Ionization Mass Spectrometry, Anal. Chem., 66:2505-2513 (1994).
Yu, L. L., Kelly, W. R., Fassett, J. D., and Vocke, R. D., Determination of Sulfur in Fossil Fuels by Isotope Dilution Electrothermal Vaporization Inductively Coupled Plasma Spectrometry, J. Anal. At. Spectrom., 16:140-145 (2001).
Winchester, M. R., Kelly, W. R., Mann, J. L., Guthrie, W. F., and MacDonald, B. S., and Turk G. C., An Alternative Method for the Certification of Sulfur Mass Fraction in Coal Standard Reference Materials, Fres. J. Anal. Chem., 370:234-240 (2001).
Christopher, S.J., Long S.E., and Rearick, M.S., Development of High Accuracy Vapor Generation Inductively Coupled Plasma Mass Spectrometry and its Application to the Certification of Mercury in Standard Reference Materials, Anal. Chem.,73:2190-2199 (2001).
Mann, J. L., Kelly, W. R., and MacDonald, B. S., Observations of Anomalous Mass-Loss Behavior in SRM Coals and Cokes on Drying, Anal. Chem., 74:3585-3591 (2002).
Long, S.E., and Kelly, W.R., Determination of Mercury in Coal by Isotope Dilution Cold-Vapor Generation Inductively Coupled Plasma Mass Spectrometry, Anal. Chem., 74:1477-1483 (2002).
Kelly, W.R., S.E. Long, S.E., and Mann, J.L., Determination of Mercury in SRM Crude Oils and Refined Products by Isotope Dilution Cold Vapor ICP-MS Using Closed-System Combustion, Anal. Bioanal. Chem., 376:753-758 (2003).
Long, S.E., Davis, W.C., Day, R., Christopher, S.J., Mann J.L., and Kelly, W.R., Improved Certified Values for Total Mercury and Speciated Mercury in NIST Standard Reference Materials Using Isotope Dilution ICP-MS, Am. Lab., 39:26-27(2007).
Stephen E. Long