Lowering barriers to the use of bio-based feedstocks for polymer products

Using more bio-based feedstocks in the manufacture of polymeric products has several advantages, including increasing the use of renewable plant-based sources and decreasing the dependence on the volatile oil market, while meeting increasing consumer demand. Many bio-based polymer materials are also biodegradable and could thus dramatically reduce the amount of plastics-based solid waste. A 2009 analysis showed that bio-based polymers could provide technically suitable replacements for nearly 90% of petroleum-based plastics.Reference Shen, Haufe and Patel⁷ However, if these potential applications of bio-based polymers are to be realized, proper data sets, quality-control systems, and manufacturing infrastructure must be built. A number of life-cycle assessments (LCAs) have demonstrated a significant net reduction in GHG emissions and fossil energy consumption in the case of bio-based replacements for fossil energy sources.Reference Cherubini and Strømman⁸ However, in the case of bio-based polymer products, a recent study demonstrated that LCAs of these complex systems can be highly sensitive to the type and quality of materials data employed, which can lead to conflicting conclusions about environmental impacts, such as GHG emissions and energy consumption.Reference Tabone, Cregg, Beckman and Landis⁹

To validate environmental claims about their products, polymer manufacturers need reliable measures of the bio-based content in their feedstocks, which can also contain petroleum-based sources. The accepted measure of bio-based content is the level of ¹⁴C isotope in the feedstock (basically, carbon dating), because ancient petroleum has lost its ¹⁴C through radioactive decay whereas feedstocks derived from recently living organisms have a ¹⁴C content related to the current equilibrium concentration in the atmosphere. ASTM has developed a protocol to quantify the bio-based content in materials by comparing the ¹⁴C/¹²C ratio to that of a standard specimen typical of living organisms.¹⁰

Measurement protocols have also been established to assess the biodegradability of bio-based polymers in various environments. For example, ASTM D5526 and a related set of documentary standards detail test methods to measure biodegradation of polymers under a variety of environments, including landfills and compost systems.¹¹ The European Union has developed similar documentary standards for labeling a polymer product as biodegradable.¹² These standard specifications and test methods validate claims made about bio-based products, thereby increasing consumers’ confidence in such products.

Automotive lightweighting

Lighter cars are more fuel-efficient, resulting in lower emissions and fuel consumption.¹³ The auto industry is moving to replace traditional die-pressed sheet steels with new lightweight alloys (specifically, aluminum alloys, magnesium alloys, and high-strength steels) to help meet emerging fuel-economy regulations. However, the forming equipment, processes, and models used by the auto industry were designed for traditional die-pressed sheet steels. Material data, models, and standard tests are helping industry achieve its lightweighting goals.¹⁴ For example, in contrast to current industry design practice, which limits the maximum strain during forming, a more useful measure for the new materials is the stress. In response, NIST has leveraged an ASTM springback test¹⁵ and outfitted forming equipment with x-ray-based instrumentation to measure stresses in sheets as they are shaped under actual manufacturing conditions.Reference Iadicola, Foecke and Banovic¹⁶ This work has provided time-saving measurement data and predictive models to automotive manufacturers and associations including Ford, General Motors, Volvo, and the United States Council for Automotive Research, as well as sheet metal manufactures such as Alcoa and U.S. Steel.

ASTM has a number of documentary standards relevant to lightweighting, for example, for radiographic inspection of magnesium castings.¹⁷ In principle, such standards could ensure the quality of engine blocks and other components cast from lightweight magnesium alloys, although one study suggests that these standards must be updated to be useful for automotive parts.Reference Das, Peretz and Tonn¹⁸ The European Council for Automotive Research and Development highlighted the needs for lightweight composite, alloy, and hybrid materials in a 2011 position paper focusing on materials replacements in automotive interiors.¹⁹ Japan’s National Institute for Materials Science has also highlighted automotive lightweighting, but has not yet issued standards.Reference Rosalie²⁰ Indeed, the U.S. Department of Energy (DOE) Vehicle Technology Program Materials Research Roadmap, updated in 2010, suggests the need for at least five additional years of fundamental research for many substitute materials classes.²¹

Reuse of fly ash for concrete production

Fly ash is a well-suited replacement for siliceous and calcareous components of concrete when it has the correct composition and particulate properties. However, fly ash varies dramatically in composition depending on the quality of the coal from which it is derived and its combustion conditions, which complicates its use as a substitute feedstock. In part to meet this challenge, the U.S. EPA has issued guidelines on the levels of fly ash that can be used in concrete applications.²² In addition, ASTM has provided key quality-control measures by defining standard procedures for sampling and testing fly ash and has classified fly-ash feedstocks based on general ranges of composition, related mainly to the type of coal from which they are derived. Existing standards enable industry to reliably assess fly-ash feedstocks for their suitability in concrete. Ongoing measurement research in the United States and Europe targets guidelines and standards to support the even higher volume fractions of fly ash. NIST aims to establish measurement protocols (Figure 2) and models to better predict the short-term setting of high-volume-fly-ash cement binder formulations.²³ Similar efforts to measure structure–property–performance relationships in fly-ash cement are underway in Europe. For example, Germany’s Federal Institute for Materials Research and Testing is characterizing enhanced chemical degradation that has been observed in fly-ash cements to provide guidelines for formulations that would avoid this failure mode.²⁴

Figure 2.

Scanning electron microscopy x-ray image (150 μm × 133 μm) showing spatial distributions of calcium (red), silicon (green), and aluminum (blue) in coal fly-ash material. Such measurement techniques and data will help industry accommodate fluctuations in fly-ash feedstock composition that can lead to unacceptably long setting times and other degradations in binder performance when fly ash is used in high volumes. (Credit: Paul Stutzman, National Institute of Standards and Technology.)

In coming years, the levels of toxics will become increasingly important in measurement and standards research on fly-ash-laden cements. For example, the European Union is developing revisions to standards and policy that would reclassify fly ash as a “waste product” rather than a “byproduct,”Reference Feuerborn²⁵ thereby making fly ash susceptible to the stringent REACH (Registration, Evaluation, Authorisation and Restriction of Chemical substances)²⁶ and RoHS (Restriction of the Use of Certain Hazardous Substances in Electrical and Electronic Equipment)²⁷ regulations. New regulations are being considered in the United States as well.²⁸ Standard protocols that quantify levels of toxics in fly ash will be needed to support industry compliance with these and related laws. Control technologies designed to reduce air pollution from power plants could shift pollutants from the flue gas to fly ash and other air-pollution-control residues. The potential reuse of these materials raises concerns about the release of sequestered mercury during processing and the presence of toxics in the finished products. These issues warrant extensive characterizations of coal combustion residues,Reference Kosson, Sanchez, Kariher, Turner, Delapp and Seignette²⁹ as well as the development of Standard Reference Materials (SRMs) consisting of these byproducts.³⁰

Properties and reliability of lead-free solders and finishes

Driven in part by RoHS and the WEEE (Waste Electrical and Electronic Equipment) Directive³¹ in Europe and similar trends in Japan, electronics manufactures have transitioned to the use of lead-free solders in their products. Several lead-free solder materials are available, mainly Sn–Ag–Cu, Ag–Cu, and Sn–Cu alloys, but their full implementation in manufacturing is hindered by a lack of data supporting their quality control, processing limits, and long-term reliability. Accordingly, SDOs and NMIs have been developing measurements, data, and standards to support use of the most promising replacement materials. For example, to provide a reference for the compositional analysis of lead-free solder alloys, Japan’s Society for Analytical Chemistry has produced a series of certified reference materials (JSAC 0131–JSAC 0134)Reference Noro, Korenaga, Kozaki, Kawada, Kurusu, Mizuhira, Ono, Katsumi, Kakita, Takimoto and Sakata³² for Sn–Ag–Cu solders, and NIST has deployed SRM 1728³³ (Figure 3). In turn, measurement techniques, such as protocols for quantifying trace-element content using x-ray fluorescence spectrometry methods, ensure that lead-free products comply with regulatory and reporting thresholds.Reference Sieber³⁴

Figure 3.

Disks of Standard Reference Material (SRM) 1728 Tin Alloy (Sn–3Cu–0.5Ag), a lead-free solder composition, showing various stages in manufacturing and testing. The alloy was created using a semi-chill casting process to ensure homogeneity of the disks to a depth of at least 10 mm. The SRM provides values for bulk composition of a number of elements, including chromium, cadmium, mercury, and lead, which are restricted in products around the world for environmental and health reasons.³³

Driven by COST (European Cooperation in Science and Technology) Action 531³⁵ on lead-free solder materials, databases of solder thermodynamic and physical properties have been compiled. For example, the National Physical Laboratory (NPL), the UK’s NMI, has established a public database of critically evaluated thermodynamic parameters for over 50 binary alloys and numerous ternary systems of eleven elements that can potentially be used in lead-free solder formulations.³⁶ The Polish Academy of Sciences compiled the downloadable SURDAT database,³⁷ which lists experimentally determined molar volumes, densities, and surface tensions of Ag–Cu and Sn–Ag–Cu systems. In addition, the Japanese Standards Association has established test methods for determining critical physical and engineering properties of lead-free solders (JIS Z 3198-1–JIS Z 3198-7).

Lead-free solders and finishes have been employed in some electronics applications for nearly 70 years, but the tremendous increase in their use over the past decade has brought attention to some ways in which these materials can fail.Reference Galyon³⁸ In particular, over long periods, normally stable solder balls and interconnects can develop structural and morphological changes that result in the formation of cracks, pull-offs, and “whiskers”—microscopic, hair-like protrusions of metal, sometimes centimeters long—that can cause short circuits in devices (Figure 4). Such failures are problematic for long-lifetime components, such as those found in mainframe computers, and can be catastrophic in critical applications such as aircraft and medical devices. For example, according to the U.S. National Aeronautics and Space Administration, since 1992, at least four in-orbit satellites have lost full function as a result of the formation of tin whiskers from lead-free solders and finishes, and another four have partially lost function.⁴⁰

Figure 4.

Scanning electron microscopy image of a tin whisker growing from a lead-free surface finish.³⁹ The composition of the lead-free surface finish is tin with 3% mass fraction copper (Sn–3 wt% Cu). The whisker growing out of the surface finish is tin. Tin whiskers often grow spontaneously from pure tin electrodeposits and short-circuit finely pitched electrical components. Adding a low percentage of lead inhibits whisker growth, but environmental concerns have resulted in a demand for lead-free finishes and whisker-mitigation strategies. (Credit: Maureen Williams, National Institute of Standards and Technology.)

Roadmaps by the International Electronics Manufacturing Initiative (iNEMI) have highlighted the reliability and failure mechanisms of lead-free solders as priority issues to address, leading to the establishment of a working group to produce accelerated test methods for measuring tin whisker growth.^{41, 42} This work has enabled industry users and producers of lead-free finishes to assess the rate at which tin whiskers can form and grow from these materials under service conditions. NIST has also assessed the conditions of tin-whisker growth,Reference Stafford, Williams, Johnson, Moon, Bertocci, Kongstein and Boettinger⁴³ demonstrating that whiskers grow only when column-shaped grains form perpendicular to the finish surfacesReference Boettinger, Johnson, Bendersky, Moon, Williams and Stafford⁴⁴ and that whisker growth releases residual stress in the material.

Tuning the color of solid-state lighting

Solid-state lighting (SSL), historically limited to monochromatic light-emitting diodes (LEDs), became viable for broad consumer and commercial applications with the advent in 1997 of LED-driven devices that produce white light by incorporating phosphors. However, consumer acceptance of SSL depends on whether it can emit the “warmer” white tones of incandescent bulbs. Blue-tinged “bright-white” sources have a “cold” quality that many people find unpleasant. The color tone of the light from SSL devices can be controlled by tuning the phosphor materials, but developing, choosing, and processing these materials in ways that achieve consistent performance can be challenging. Standards help SSL manufacturers meet these challenges, by enabling them to tune the emission of phosphor mixtures and to gauge the performance of candidate phosphor and LED materials⁴⁵ (Table I).

Table I.

Examples of solid-state lighting standards.

Acronyms: ANSI, American National Standards Institute; ANSLG, American National Standard Lighting Group; CIE, International Commission on Illumination; IESNA, Illuminating Engineering Society of North America; LED, light-emitting diode; NEMA, National Electrical Manufacturers Association; NIST, National Institute of Standards and Technology; SSL, solid-state lighting; U.S. DOE, U.S. Department of Energy.

The development of SSL standards is part of the U.S. government’s effort to help the DOE reach its goal of developing and introducing SSL to reduce energy consumption for lighting by 50% by 2025 and to support the Energy Star program, a joint program of the DOE and the EPA that promotes energy-efficient products and practices. NIST independently tested 150 Energy Star-qualified products, using measurement methods traceable to national electrical standards, and confirmed that these products met EPA product specifications (100% for digital versatile disc products and computer monitors and 95% for printers).⁵²

Photovoltaics

In its 2010 Technology Roadmap for Solar Photovoltaic Energy, the International Energy Association (IEA) indicated that, since 2000, global photovoltaic (PV) capacity has been increasing by more than 40% per year, on average, and has significant potential for long-term growth in coming decades. The IEA envisions that, by 2050, photovoltaics will provide 11% of global electricity production (4500 TWh per year). Achieving such growth, however, necessitates policies in the next decade that enable optimal technology progress, cost reduction, and an increase of industrial manufacturing.⁵³

One approach offering the possibility of greatly reduced manufacturing cost compared to conventional inorganic semiconductor silicon technology is organic photovoltaics (OPV). These are solar cells that use organic molecules, including polymers, dendrimers, small molecules, and dyes. However, OPV devices have much lower efficiencies than those based on traditional PV materials. To provide design principles for optimizing OPV materials and devices, a suite of measurements aimed at determining the molecular and microstructural mechanisms of charge transport in these materials, especially across the complex interfaces within them, is being developed by NIST. Photoelectron spectroscopies, scanning-probe methods, and theoretical models of multiscale processes in thin organic films and polymeric heterojunctions are central to this pursuit.⁵⁴ In addition to accelerating research, these measurement techniques could establish standard test methods for use by industry. Such methods for OPV and other organic electronic devices are being pursued through the Versailles Project on Advanced Materials and Standards (VAMAS), which includes efforts to develop reference methods and data to support the process optimization, quality control, and reliability of OPV devices. This effort is led by the VAMAS Organic Electronics Technical Working Area and is co-chaired by two NMIs: NPL and NIST.⁵⁵