X-Ray Diamond Anvil Cell Facility at NSLS: 2008 Progress Report
Thomas Duffy Dept. of Geosciences Princeton University
Beamline Management Team: D. Weidner (Stony Brook), T. Duffy (Princeton), M. Rivers (Chicago), J. Chen (FIU), A. Goncharov (CIW), L. Ehm (Stony Brook), C. Kao (BNL)
Beamline Scientists: Jingzhu Hu, Quanzhong Guo
2008 COMPRES Annual Meeting – Colorado Springs
Current High-Pressure Program at the National Synchrotron Light Source
X17B2, X17B3, X17C, U2A
Single crystals and powder x-ray diffraction, infrared spectroscopy
Diamond Cells and Multi-anvil devices
X17 Superconducting wiggler, U2 bending magnet
200 users from 50 institutions annually
~45 publications per year (6% of NSLS total)
Main support through Consortium for Materials Property Research in Earth Sciences (COMPRES) with additional funding from Carnegie/DOE Alliance Center, NSF-EAR, and DOD.
X17 DAC (X17C, X17B3) Strategic Plan
1. Provide a state-of-the-art community facility for high-pressure mineral physics research
2. Develop and enhance key and unique features of the NSLS DAC facility
-- Energy dispersive Diffraction-- New laser heating capabilities-- Combined X-ray and IR studies-- High quality support lab--High-pressure community at NSLS
3. Lay groundwork to develop a high-pressure program at NSLS-II that will be world-class and take advantage of the unique features of this new machine
X-Ray Diamond Anvil Cell Research at NSLS: X17C
X17C -- One of longest-running high-pressure synchrotron beamlines in the world
Side station on a superconducting wiggler beamline
Main techniques: Energy and angle dispersive diffraction on single crystals and polycrystals to ultrahigh pressures,
Studies of: equation of state, phase transitions, structure refinements, yield strength, amorphization, texturing, compressibility, and other properties
New techniques pioneered on the beamline in recent years: development of rotational diamond anvil cell, applications of synthetic and designer anvils, gem anvil cells, and radial x-ray diffraction techniques
Materials studied: metals. oxides, silicates, nitrides, manganites, clathrates, nanocrystals, microinclusions
Sample preparation facility: diamond cell equipment, stereomicroscope, microdrills, gas loading, ruby fluorescence spectrometer
Supported by NSF Earth Science through COMPRES
Monochromator Sagittally bent Si Laue crystals
Beam energy tunable 20 keV to 40 keV
Focusing mirror K-B mirror
Primary beam size 0.150 mm x 0.160 mm
Focus beam size 0.025 mm x 0.020 mm
Detector MARCCD
Angle-dispersive x-ray diffraction experiments at X17C
Energy-dispersive x-ray diffraction experiments at X17C
White beam energy ramge 20 keV to100 keV
Focusing mirror K-B mirror
Primary beam size 0.060 mm x 0.070 mm
Focus beam size 0.025 mm x 0.020 mm
Detector Ge detector
detectorsampleslits
X-Ray Diamond Anvil Cell Research at NSLS: X17B3
Main techniques: Energy and angle dispersive diffraction on single crystals and polycrystals to ultrahigh pressures; laser heating to 4000 K.
Studies of: equation of state, phase transitions, structure refinements, yield strength, amorphization, melting, texturing, thermal expansivity, compressibility, liquid and glass structure and other properties
New techniques pioneered on the beamline in recent years:
Development of x-ray focusing devices, monochromators
High energy total x-ray scattering of melts and glasses.
Materials studied: metals. oxides, silicates, nitrides, manganites, clathrates, nanocrystals, microinclusions
Angle-dispersive x-ray diffraction experiments at X17B3
Energy-dispersive x-ray diffraction experiments at X17B3
White beam energy 20 keV to100 keVFocusing mirror K-B mirrorPrimary beam size .100 mm x .180 mm at 2mradFocus beam size 8um x 8umDetector Ge detector
Monochromator Sagittally bent Si Laue crystalsBeam energies 30 keV / 80 keVFocusing mirror K-B mirror (for 30 KeV)Primary beam size .100 mm x .150 mm at 2mradFocus beam size 25 um x 25 umDetector Mar345
Operations Summary
•Contributing user agreement with NSLS: 50% general user time and 50% contributing user (COMPRES) time (25% for users, 25% for development).
•X-17C operates 100% of time:~81 days beamtime per cycle (G+C users)
•X-17B3 operates 33% time dedicated, 33% parasitic with X-17B2.~ 54 days beamtime per cycle (G+C users)
•All beamtime allocated by proposals submitted to NSLS General User System
•Beamlines are running with only 1 staff person for each station.
2008 Beamtime Usage Statistics for X17 DAC (X17C+X17B3):
May-August 2008: 20 proposals requesting 114 days of beamtime
Sept-Dec 2008: 24 proposals requesting 152 days of beamtime
Calendar Year
2008 2007 2006 2005 2004
Publications 12 20 26 10 23
Premier Publications
3 3 4 2 5
# of Users --- 56 40 31
Calendar Year
2008 2007 2006 2005 2004
Publications 1 3 7 2 1
Premier Publications
0 0 1 1 0
# of Users --- 14 19 16
X17C
X17B3
X17 Selected Publications -- 2008
High Pressure Phase Transitions and Compressibilities of Er2Zr2O7 and Ho2Zr2O7
F. Zhang et al., Appl. Phys. Lett., 92: 011909 (2008)
Phase Stability and Pressure Dependence of Defect Formation in Gd2Ti2O7 and Gd2Zr2O7 PyrochloreZhang et al., Phys. Rev. Lett., 100: 045503 (2008)
Osmium Metal Studied under High Pressure and Nonhydrostatic StressM Weinberger et al., Phys. Rev. Lett., 100: 045506 (2008) Irraditation-Induced Stabilization of Zircon (ZrSiO4) at High PressureLang et al. Earth Planet Sci. Lett., 269: 291 (2008)
Garnet Yield Strength at High Pressures and Implications for Upper Mantle and Transition Zone Rheology, Kavner, J. Geophys. Res., 112: B12207 (2008)
In Situ High-Pressure X-ray Diffraction Study of H2O Ice VIIM Somayazulu, et al,, J. Chem. Phys., 128: 064510 (2008)
Premier Publication as defined by NSLS
Deformation of the Lower-Mantle Ferropericlase (Mg,Fe)O across the Electronic Spin Transition
Beamline: X17C
Category of Researcher:GU and CU
Technique: EDXD
Researchers & affiliations:J. Lin, LLNLH. R. Wenk, BerkeleyS. Speziale, PotsdamJ. Shu, CIWT. S. Duffy, Princeton
Publication: Deformation of the lower-mantle ferropericlase across the electronic spin transition, submitted to Nature, 2008.
Motivation:
To understand the effect of an Fe spin transition on the texture, stress, and strength of ferropericlase under lower-mantle pressures,
We have deformed [(Mg0.83,Fe0.17)O]
under nonhydrostatic condition in a diamond anvil cell up to 81 GPa using energy-dispersive radial X-ray diffraction techniques.
Results:
We observe unexpectedly lower stress and strength of ferropericlase, together with active slip systems and high elastic anisotropy. These results indicate that ferropericlase would play more dominant roles in the deformation and seismic anisotropy of the lower mantle, including subducting slabs, than what is expected by studying the high-spin ferropericlase.
Figure 1 Figure: Inverse pole figures of the compression direction for (Mg0.83,Fe0.17)O
at high pressures in equal area projection.
Phase Transitions in Alkaline Earth Fluorides CaF2 and SrF
2 to 95 GPa
Beamline:X17B3
Category of Researcher:CU
Technique: ADXD Laser Heating
Researchers & affiliations:
S. Dorfmann, F. Jiang,Z. Mao, and T. Duffyall: Princeton U
Publication: S. Dorfmann et al., EOS Trans. AGU, 2007
Motivation:
Results:
Figure 1 Pressure-volume data on SrF2.
The Ni2In-type and cotunnite-type phases
are fitted to a Birch-Murnaghan equation of state.
1.0
0.9
0.8
0.7
0.6
V/V
0
100806040200
Pressure (GPa)
Ni2In-type
K0=153 GPa and K0'=4
FluoriteK0=65 GPa and K0'=4 (Tang '05)
Cotunnite-typeK0=82 GPa and K0'=4
Co2Si-type
SrF2The alkaline earth fluorides (MgF2, CaF2, SrF2, BaF2) exhibit extensive polymorphism at high pressures. They serve as a model system for understanding highly coordinated structures and phase transition pathways in other AX2 compounds such as SiO2.
CaF2 and SrF2 transform to a hexagonal Ni
2In-type structure at 84 and 36 GPa,
respectively, following laser heating. This work represents the first synthesis and characterization of the Ni
2In-type
phase for these compositions.
On decompression, SrF2 passes through an intermediate orthorhombic
phase at 28 GPa before returning to cotunnite structure at 22 GPa. This transition is analogous to the isosymmetric phase transition to the Co
2Si-
type structure reported in PbF2 by Haines et al. (1998). This is the first
report of Co2Si structure in an alkaline earth fluoride.
Structure of liquid Gallium at high pressure
Beamline:X17B3
Category of Researcher:CU
Technique: X-ray total scattering
Researchers & affiliations:T. Yu1, L. Ehm1,4, J. Chen1,2
S. Luo3, and Q. Guo1
1Stony Brook University2Florida Int. University3Los Alamos National Lab.4NSLS
Publication: This project received the "Best Poster" Award at 2007 NSLS User's Meeting.Yu et al., in preparation, 2008
Motivation:
Results:
Figure 1 Raw data of solid gallium and the liquid phase of gallium.
Gallium shows many polymorphic phase transitions as a function of pressure and temperature. Furthermore, gallium belongs to the ice-type elements the density of the liquid phase exceeds the density of the stable crystalline phase Ga-I by ~3%. Hence, gallium melts at RT upon application of pressure.
Figure 3 Pressure dependence of the Pair Distribution Function of liquid Gallium.
Figure 2 Normalized structure factor S(Q) at 1.32 GPa.
Non-uniform com-pression of the <Ga-Ga> distances. This compression behavior of liquid-Gallium can not easily be explained by a hard sphere model of the liquid.
Compression behavior and the presents of a shoulder on the first diffraction maximum in S(Q) suggest a local ordering in liquid Gallium.
Major Developments at X17 DAC -- 2008
1. Personnel and management
New management team (Duffy, Weidner co-PI)
Lars Ehm (SBU/BNL staff member)
New beamline scientists in 2008
Integration of high-pressure activities at NSLS
2. Beamline Developments
New laser heating system (Goncharov, PI)
New dedicated area detector
3. Planning for transition to NSLS-II in 2015
Staffing
Jingzhu Hu and Quanzhong Guo will retire on 9/30/08.
Jingzhu has been beamline scientist at X17C for 18 years. She is 2008 winner of the NSLS Community Service Award. Quanzhong Guo has been beamline scientist at X17B3 for 10 years.
The high-pressure community is very grateful for their years of dedicated service.
On-going search for new beamline scientists Search committee: Duffy, Ehm, Weidner
“Over the last 15 years, every single time I have been at X17C, Jingzhu has given 100 percent of herself to help ensure that my experiments worked. She seemed to live at the synchrotron. When problems that I couldn’t deal with popped up, whether at 9 a.m. or 9 p.m., Jingzhu was there to help us overcome them.”
-- From an anonymous nomination letter for Jingzhu Hu for the NSLS community service award
X17B3 Upgrade: New Area Detector
Rayonix SX-165 CCD detector
-- 165 mm active area, 2048 x 2048 pixels
--Previous generation (MarCCD) is standard for high-P synchrotron experiments
-- fast readout time (2.5 s) for in situ laser heating
- millisecond partial readout time will allow for studies on a time scale not previously available in high P-T science.
High-Pressure Community Outreach Efforts and Planning
Feb. 25-26, 2006 “NSLS X-Ray High Pressure Research Workshop: Current operation and vision into NSLS II (sponsored by COMPRES and MPI) (46 attendees) Report prepared by J. Chen et al.
July 17-18, 2007 High-pressure discussion session at “NSLS-II Users Workshop” (28 attendees). “High Pressure Needs at NSLS-II Synchrotron” prepared by D. Weidner et al.
January 17-18, 2008 “Materials at High Pressure” breakout session during the Workshop on “The NSLS-II Powder Diffraction Project Beamline” and “Materials Science Engineering Strategic Planning for NSLS and NSLS-II (34 attendees). White paper prepared by Lars Ehm et al.
March 2008 Letter of Interest (LOI) submitted for high-pressure superconducting wiggler beamline at NSLS-II
May 21, 2008 Workshop on “Future Directions in High-Pressure Research” at NSLS Users’ Meeting
Two crystals of 0.76 mm thick,
with surfaces corresponding to the (001) planes, are bent sagittally to 1 m radius.
Used in the Laue (transmission) mode.
Silicon 111 reflection was used with asymmetry angle of 35.3 degrees. The monochromatic beam is higher 20 mm than incident white beam.
The distance of two crystals d depends on the X-ray energy. At 30 keV d = 160mm. At 40 keV d = 200 mm.The bent Laue crystals provides high energy-resolution beam with a flux one order of magnitude greater than that of a flat-crystal monochromator, Sagittal focusing was not used at X17C due to short distance between monochromator and sample
25md
20mm
Monochomatic beam
Z. Zhong, et. al., Acta. Cryst. A 59 (2003)
BeamstopIon chamberVertical beam
focusing mirror
Clean up slit
Goniometor , 2stages
Motorized X, Y, Z stages
Manual adjustingX, Y stages
Rotating stage
X17B beam pipe
X
Y
Z
DA
C
Experiment Setup in X17C Hutch
MARCCD
microscope
2 armX-ray window
Beam slit
Horizontal beam focusing mirror
Si (100)
Monochromator
Beam stop
Photo diode