New work improves stainless steel surface.Manufacturers polish, grind, and roll stainless steel stainless steel: see steel. stainless steel Any of a family of alloy steels usually containing 10–30% chromium. The presence of chromium, together with low carbon content, gives remarkable resistance to corrosion and heat. to create countless everyday products. Such manipulations can produce, for example, an especially hard material for sharp edges on surgical tools and razor blades. Yet the resulting metal can be more brittle and prone to corrosion than other forms of stainless steel are. Now, an electrochemical electrochemical /elec·tro·chem·i·cal/ (-kem´i-k'l) pertaining to interaction or interconversion of chemical and electrical energies. e·lec·tro·chem·i·cal adj. technique seems to improve a stainless steel surface without degrading the rest of the material. The new process is so simple, says Tim Burstein of the University of Cambridge in England, that "you could just about carry it out in a schoolroom." Burstein and his colleagues ground and polished 1-centimeter squares made of a steel microstructure mi·cro·struc·ture n. The structure of an organism or object as revealed through microscopic examination. microstructure Noun a structure on a microscopic scale, such as that of a metal or a cell called austenite aus·ten·ite n. A nonmagnetic solid solution of ferric carbide or carbon in iron, used in making corrosion-resistant steel. [After Sir William Chandler Roberts-Austen (1843-1902), British metallurgist. . As expected, X-ray diffraction revealed that their alterations had introduced another crystal microstructure, the brittle martensite mar·ten·site n. A solid solution of iron and up to one percent of carbon, the chief constituent of hardened carbon tool steels. [After Adolf Martens (1850-1914), German metallurgist. , on the squares' surface. Then, Burstein's team placed the steel in a conductive bath of sodium nitrite sodium nitrite n. A white crystalline compound used to lower systemic blood pressure, to relieve local vasomotor spasms, to relax bronchial and intestinal spasms, and as an antidote for cyanide poisoning. and water at 80 [degrees] Celsius. The scientists slowly pulsed electricity back and forth through the solution, alternating between two voltages. After 3 hours, new X-ray observations showed that the martensite had disappeared. Yet the desirable hardness remained, the team reports in the Oct. 19 NATURE. Tests showed a surface even harder than that of the original polished steel square. For comparison, Burstein's group also used the conventional method of removing martensite. Treating stainless steel with very high temperatures can eliminate that crystal form, but there's a tradeoff. The heat can also alter the underlying metal's desirable properties. The team showed that heating polished steel samples to 750 [degrees] C eliminates martensite but simultaneously decreases surface hardness. The Cambridge team produced their hardest surfaces yet by following an electrochemical treatment electrochemical treatment (  ·lek·trō·ke·mi·k with a 550 [degrees] C treatment. Burstein says any eventual use of the new process will likely include both electrochemistry electrochemistry, science dealing with the relationship between electricity and chemical changes. Of principal interest are the reactions that take place between electrodes and the electrolytes in electric and electrolytic cells (see electrolysis), as well as the and heat. Martensite also decreased during electrochemical processing of cold-rolled steel. Rolling had created the hard, brittle form of stainless steel throughout the samples and not just at the surface. Burstein reports that the electrochemical treatment eliminated the brittle structure even below the topmost atomic layers and reached as deep as 8 micrometers into the metal. Burstein notes that the mechanisms underlying the electrochemical technique remain unclear. Once researchers understand more of this chemistry, they may be able to use it to harden the surfaces of other metals, he adds. "It's not a slam dunk yet," comments Robert G. Kelly of the University of Virginia in Charlottesville. Still, if further research reveals enough detail about how this new process works, it could have many applications. Consider razor blades. "You have the martensite at the cutting edge of the blade," Kelly says. "One of the reasons blades go dull after shaving is that they stay wet, and so they corrode cor·rode v. cor·rod·ed, cor·rod·ing, cor·rodes v.tr. 1. To destroy a metal or alloy gradually, especially by oxidation or chemical action: acid corroding metal. . If you can remove the martensite and therefore slow the corrosion down, those of us who shave ... would be much happier." |
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