TY - JOUR
T1 - Synchrotron FTIR imaging of OH in quartz mylonites
AU - Kronenberg, Andreas K.
AU - Hasnan, Hasnor F.B.
AU - Holyoke, Caleb W.
AU - Law, Richard D.
AU - Liu, Zhenxian
AU - Thomas, Jay B.
N1 - Funding Information:
Acknowledgements. This study benefitted from helpful and enjoyable discussions with Kyle Ashley, Renee Heilbronner, Rüdiger Kilian, Stephen Kirby, Sina Marti, Michael Stipp, Holger Stünitz, and Robert Tracy. The manuscript was greatly improved by the thoughtful review of Jed Mosenfelder, comments of a second anonymous reviewer, and the editorial oversight by Re-nee Heilbronner and Fabrizio Storti. We thank Nicholas Davis for his outstanding work preparing beautifully thin, doubly polished IR plates; his skill, care, and patience were invaluable to our work. We are indebted to Randy Smith of Brookhaven National Laboratory for sharing his expertise with OPUS imaging subroutines and teaching us how to compile and analyze integrated absorbances for multiple IR spectra collected over large scanned areas. Many thanks go to the leadership and staff of Brookhaven National Laboratory for operating the National Synchrotron Light Source (NSLS) I and awarding access to the U2A Beamline and Bruker Hyperion-2000 FTIR microscope. We thank the Consortium for Materials Properties Research in Earth Sciences COMPRES for their coordination of Earth science pursuits with other sciences done at NSLS. The National Science Foundation funded this work through a collaborative research grant awarded to the PIs at Virginia Tech (NSF EAR 1220345), Texas A&M University (NSF EAR 1220138), and Renssellaer Polytechnic Institute (transferred to Syracuse University, NSF EAR 1543627); their support is gratefully acknowledged.
PY - 2017/10/4
Y1 - 2017/10/4
N2 - Previous measurements of water in deformed quartzites using conventional Fourier transform infrared spectroscopy (FTIR) instruments have shown that water contents of larger grains vary from one grain to another. However, the non-equilibrium variations in water content between neighboring grains and within quartz grains cannot be interrogated further without greater measurement resolution, nor can water contents be measured in finely recrystallized grains without including absorption bands due to fluid inclusions, films, and secondary minerals at grain boundaries. Synchrotron infrared (IR) radiation coupled to a FTIR spectrometer has allowed us to distinguish and measure OH bands due to fluid inclusions, hydrogen point defects, and secondary hydrous mineral inclusions through an aperture of 10 Êm for specimens > 40μm thick. Doubly polished infrared (IR) plates can be prepared with thicknesses down to 4-8μm, but measurement of small OH bands is currently limited by strong interference fringes for samples25μm thick, precluding measurements of water within individual, finely recrystallized grains. By translating specimens under the 10μm IR beam by steps of 10 to 50μm, using a software-controlled x-y stage, spectra have been collected over specimen areas of nearly 4.5mm2. This technique allowed us to separate and quantify broad OH bands due to fluid inclusions in quartz and OH bands due to micas and map their distributions in quartzites from the Moine Thrust (Scotland) and Main Central Thrust (Himalayas). Mylonitic quartzites deformed under greenschist facies conditions in the footwall to the Moine Thrust (MT) exhibit a large and variable 3400 cm-1 OH absorption band due to molecular water, and maps of water content corresponding to fluid inclusions show that inclusion densities correlate with deformation and recrystallization microstructures. Quartz grains of mylonitic orthogneisses and paragneisses deformed under amphibolite conditions in the hanging wall to the Main Central Thrust (MCT) exhibit smaller broad OH bands, and spectra are dominated by sharp bands at 3595 to 3379 cm..1 due to hydrogen point defects that appear to have uniform, equilibrium concentrations in the driest samples. The broad OH band at 3400 cm..1 in these rocks is much less common. The variable water concentrations of MT quartzites and lack of detectable water in highly sheared MCT mylonites challenge our understanding of quartz rheology. However, where water absorption bands can be detected and compared with deformation microstructures, OH concentration maps provide information on the histories of deformation and recovery, evidence for the introduction and loss of fluid inclusions, and water weakening processes.
AB - Previous measurements of water in deformed quartzites using conventional Fourier transform infrared spectroscopy (FTIR) instruments have shown that water contents of larger grains vary from one grain to another. However, the non-equilibrium variations in water content between neighboring grains and within quartz grains cannot be interrogated further without greater measurement resolution, nor can water contents be measured in finely recrystallized grains without including absorption bands due to fluid inclusions, films, and secondary minerals at grain boundaries. Synchrotron infrared (IR) radiation coupled to a FTIR spectrometer has allowed us to distinguish and measure OH bands due to fluid inclusions, hydrogen point defects, and secondary hydrous mineral inclusions through an aperture of 10 Êm for specimens > 40μm thick. Doubly polished infrared (IR) plates can be prepared with thicknesses down to 4-8μm, but measurement of small OH bands is currently limited by strong interference fringes for samples25μm thick, precluding measurements of water within individual, finely recrystallized grains. By translating specimens under the 10μm IR beam by steps of 10 to 50μm, using a software-controlled x-y stage, spectra have been collected over specimen areas of nearly 4.5mm2. This technique allowed us to separate and quantify broad OH bands due to fluid inclusions in quartz and OH bands due to micas and map their distributions in quartzites from the Moine Thrust (Scotland) and Main Central Thrust (Himalayas). Mylonitic quartzites deformed under greenschist facies conditions in the footwall to the Moine Thrust (MT) exhibit a large and variable 3400 cm-1 OH absorption band due to molecular water, and maps of water content corresponding to fluid inclusions show that inclusion densities correlate with deformation and recrystallization microstructures. Quartz grains of mylonitic orthogneisses and paragneisses deformed under amphibolite conditions in the hanging wall to the Main Central Thrust (MCT) exhibit smaller broad OH bands, and spectra are dominated by sharp bands at 3595 to 3379 cm..1 due to hydrogen point defects that appear to have uniform, equilibrium concentrations in the driest samples. The broad OH band at 3400 cm..1 in these rocks is much less common. The variable water concentrations of MT quartzites and lack of detectable water in highly sheared MCT mylonites challenge our understanding of quartz rheology. However, where water absorption bands can be detected and compared with deformation microstructures, OH concentration maps provide information on the histories of deformation and recovery, evidence for the introduction and loss of fluid inclusions, and water weakening processes.
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U2 - 10.5194/se-8-1025-2017
DO - 10.5194/se-8-1025-2017
M3 - Article
AN - SCOPUS:85030655644
SN - 1869-9510
VL - 8
SP - 1025
EP - 1045
JO - Solid Earth
JF - Solid Earth
IS - 5
ER -