Ruby fluorescence pressure scale: Revisited

doi:10.1088/1674-1056/22/5/056201

Abstract Effect of non-hydrostatic stress on X-ray diffraction in diamond anvil cell (DAC) is studied. Pressure gradient in sample chamber leads to the broadening of the diffraction peaks, which increase with the hkl index of the crystal. It is found that the difference between the determined d-spacing compressive ratio d/d₀ and the real d-spacing compressive ratio d_r/d₀ is determined by the yield stress of the pressure transmitting media (if used) and the shear modulus of the sample. On the basis of the corrected experiment data of Mao et al. (MXB86), which was used to calibrate the most widely used ruby fluorescence ruby scale, a new relationship of ruby fluorescence pressure scale is corrected, i.e., P=(1904/9.827)[(1+Δλ/λ₀)^9.827-1].

Keywords: non-hydrostatic stress ruby fluorescence pressure scale diamond anvil cell

Received: 11 October 2012
Revised: 05 December 2012
Accepted manuscript online:

PACS:	62.20.D-	(Elasticity)
	64.30.Ef	(Equations of state of pure metals and alloys)
	07.35.+k	(High-pressure apparatus; shock tubes; diamond anvil cells)

Fund: Project supported by the Defense Industrial Technology Development Program of China (Grant No. B1520110001), the National Natural Science Foundation of China (Grant No. 10874158), and the CAEP (Grant Nos. 2010A0101001 and 2008A0101001).

Corresponding Authors: Bi Yan
E-mail: biyan_cn@yahoo.com.cn

Cite this article:

Liu Lei (柳雷), Bi Yan (毕延), Xu Ji-An (徐济安) Ruby fluorescence pressure scale: Revisited 2013 Chin. Phys. B 22 056201

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