Abstract
Large negative thermal expansion (NTE) has been discovered during the last decade in materials of various kinds, particularly materials associated with a magnetic, ferroelectric or charge-transfer phase transition. Such NTE materials have attracted considerable attention for use as thermal-expansion compensators. Here, we report the discovery of giant NTE for reduced layered ruthenate. The total volume change related to NTE reaches 6.7% in dilatometry, a value twice as large as the largest volume change reported to date. We observed a giant negative coefficient of linear thermal expansion α=−115 × 10−6 K−1 over 200 K interval below 345 K. This dilatometric NTE is too large to be attributable to the crystallographic unit-cell volume variation with temperature. The highly anisotropic thermal expansion of the crystal grains might underlie giant bulk NTE via microstructural effects consuming open spaces in the sintered body on heating.
Highlights
Large negative thermal expansion (NTE) has been discovered during the last decade in materials of various kinds, materials associated with a magnetic, ferroelectric or charge-transfer phase transition
We discovered giant NTE of large total volume change DV/V 1⁄4 6.7% and a 1⁄4 À 115 Â 10 À 6 K À 1 (DT of B210 K) in reduced Ca2RuO4 (Supplementary Fig. 1)
The dilatometric NTE observed in sintered b-eucryptite reaches 1.7%, which is greater than 10 times of the crystallographic NTE (Table 3)
Summary
Large negative thermal expansion (NTE) has been discovered during the last decade in materials of various kinds, materials associated with a magnetic, ferroelectric or charge-transfer phase transition. We observed a giant negative coefficient of linear thermal expansion a 1⁄4 À 115 Â 10 À 6 K À 1 over 200 K interval below 345 K This dilatometric NTE is too large to be attributable to the crystallographic unit-cell volume variation with temperature. Another avenue towards discovery of giant NTE is the utilization of a phase transition accompanied by large volume contraction on heating. One promising mother compound for NTE materials is layered ruthenate Ca2RuO4 (refs 15–22) It undergoes a metal–insulator (MI) transition, which is apparently accompanied by volume expansion. We discuss microstructural effects that enhance the bulk NTE of sintered samples
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