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Synthesis, Characterization, and Properties of Nanophase Ceramics

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Abstract

Ultrafine-grained ceramics have been synthesized by the production of ultrafine (2–20 nm) particles, using the gas-condensation method, followed by their in-situ, ultra-high vacuum consolidation at room temperature. These new nanophase ceramics have properties that are significantly improved relative to those of their coarser-grained, conventionally-prepared counterparts. For example, nanophase rutile (TiO2) with an initial mean grain diameter of 12 nm sinters at 400 to 600°C lower temperatures than conventional powders, without the need for compacting or sintering aids. The sintered nanophase rutile exhibits both improved microhardness and fracture characteristics. These property improvements result from the reduced scale of the grains and the increased cleanliness of the particle surfaces and the subsequently-formed grain boundaries. Research completed on the synthesis, characterization, and properties of nanophase ceramics is reviewed and the potential for using the nanophase synthesis method for engineering new and/or improved ceramics and composites is considered.

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Authors and Affiliations

  1. Materials Science Division, Argonne National Laboratory, 60439, Argonne, Illinois, USA

    R. W. Siegel & J. A. Eastman

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  1. R. W. Siegel
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  2. J. A. Eastman
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Siegel, R.W., Eastman, J.A. Synthesis, Characterization, and Properties of Nanophase Ceramics. MRS Online Proceedings Library 132, 3–14 (1988). https://doi.org/10.1557/PROC-132-3

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