Solid-state calcium NMR references
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Danielle Laurencin, Yang Li, Melinda Duer, Dinu Iuga, Christel Gervais, and Christian Bonhomme
A 43Ca nuclear magnetic resonance perspective on octacalcium phosphate and its hybrid derivatives,
Magn. Reson. Chem. 59, 1048-1061 (2021).
Abstract -
H. Colas, L. Bonhomme-Coury, C. Coelho Diogo, F. Tielens, F. Babonneau, C. Gervais,
D. Bazin, D. Laurencin, M. E. Smith, J. V. Hanna, M. Daudon, and C. Bonhomme
Whewellite, CaC2O4·H2O: structural study by a combined NMR, crystallography and modelling approach,
CrystEngComm 15, 8840-8847 (2013).
Abstract -
Danielle Laurencin and Mark E. Smith
Development of 43Ca solid state NMR spectroscopy as a probe of local structure in inorganic and molecular materials,
Prog. Nucl. Magn. Reson. Spectrosc. 68, 1-40 (2013).
Abstract -
Yu-Chieh Huang, Yun Mou, Tim Wen-Tin Tsai, Yu-Ju Wu, Hsin-Kuan Lee,
Shing-Jong Huang, and Jerry C. C. Chan
Calcium-43 NMR studies of polymorphic transition of Calcite to Aragonite,
J. Phys. Chem. B 116, 14295-14301 (2012).
Abstract -
A. Wong, P. M. Aguiar, T. Charpentier, and D. Sakellariou
A low-cost strategy for 43Ca solid-state NMR spectroscopy,
Chem. Sci. 2, 815-818 (2011).
Abstract -
D. L. Bryce
Calcium binding environments probed by 43Ca NMR spectroscopy,
Dalton Trans. 39, 8593-8602 (2010).
Abstract -
Alan Wong, Danielle Laurencin, Ray Dupree, and Mark E. Smith
Two-dimensional 43Ca–1H correlation solid-state NMR spectroscopy,
Solid State Nucl. Magn. Reson. 35, 32-36 (2009).
Abstract -
G. M. Bowers and R. J. Kirkpatrick
Natural abundance 43Ca NMR spectroscopy of tobermorite and jennite: Models for the C-S-H structure,
J. Am. Ceram. Soc. 92, 545-548 (2009).
Abstract -
D. L. Bryce, E. B. Bultz, and D. Aebi
Calcium-43 chemical shift tensors as probes of calcium binding environments. Insight into the structure of the Vaterite CaCO3 polymorph by 43Ca solid-state NMR spectroscopy.,
J. Am. Chem. Soc. 130, 9282-9292 (2008). -
D. Laurencin, A. Wong, R. Dupree, and M. E. Smith
Natural abundance 43Ca solid-state NMR characterisation of hydroxyapatite: identification of the two calcium sites,
Magn. Reson. Chem. 46, 347-350 (2008). -
D. Laurencin, A. Wong, J. V. Hanna, R. Dupree, and M. E. Smith
A high-resolution 43Ca solid-state NMR study of the calcium sites of hydroxyapatite,
J. Am. Chem. Soc. 130, 2412-24113 (2008). -
Kenneth J. D. MacKenzie, Mark E. Smith, and Alan Wong
A multinuclear MAS NMR study of calcium-containing aluminosilicate inorganic polymers,
J. Mater. Chem. 17, 5090-5096 (2007).
Abstract -
F. Angeli, M. Gaillard, P. Jollivet, and T. Charpentier
Contribution of 43Ca MAS NMR for probing the structural configuration of calcium in glass,
Chem. Phys. Lett. 440, 324-328 (2007). -
K. Shimoda, Y. Tobu, Y. Shimoikeda, T. Nemoto, and K. Saito
Multiple Ca2+ environments in silicate glasses by high-resolution 43Ca MQMAS NMR technique at high and ultra-high (21.8 T) magnetic fields,
J. Magn. Reson. 186, 156-159 (2007). -
K. Shimoda, Y. Tobu, K. Kanehashi, K. Saito, and T. Nemoto
First evidence of multiple Ca sites in amorphous slag structure: Multiple-quantum MAS NMR spectroscopy on calcium-43 at high magnetic field,
Solid State Nucl. Magn. Reson. 30, 198-202 (2006). -
A. Wong, A. P. Howes, R. Dupree, and M. E. Smith
Natural abundance 43Ca NMR study of calcium-containing organic solids: A model study for Ca-binding biomaterials,
Chem. Phys. Lett. 427, 201-205 (2006). -
Z. J. Lin, M. E. Smith, F. E. Sowrey, and R. J. Newport
Probing the local structural environment of calcium by natural-abundance solid-state 43Ca NMR,
Phys. Rev. B 69, 224107/1-224107/7 (2004). -
S. Marchand, A. Trokiner, A. Yakubovskii, P. Monod, A. Knizhnik,
and Y. Eckstein
43Ca NMR study of the doping effects in the high temperature superconductor (La1-xCax)(Ba1.75-xLa0.25+x)Cu3Oy,
C. R. Acad. Sci. Paris, Chimie 4, 819-824 (2001). -
A. Trokiner, P.-V. Bellot, Y. Zhdanov, and A. Yakubovskii
NMR determination of the Sternheimer antishielding factor of Ca2+,
Solid State Nucl. Magn. Reson. 16, 171-175 (2000). -
R. Dupree, A. P. Howes, and S. C. Kohn
Natural abundance solid state 43Ca NMR,
Chem. Phys. Lett. 276, 399-404 (1997). -
A. Trokiner, L. Le Noc, A. Yakubovskii, K. N. Mykhalyov, and S. V. Verkhovskii
43Ca NMR study of bismuth-based high-Tc superconductors,
Z. Naturforsch. 49a, 373-378 (1993).
More solid-state Ca-43 NMR references.
Solid-state NMR bibliography for
- Aluminum-27 (鋁)
- Antimony-121/123 (銻)
- Arsenic-75 (砷)
- Barium-135/137 (鋇)
- Beryllium-9 (鈹)
- Bismuth-209 (鉍)
- Boron-10/11 (硼)
- Bromine-79/81 (溴)
- Calcium-43 (鈣)
- Cesium-133 (銫)
- Chlorine-35/37 (氯)
- Chromium-53 (鉻)
- Cobalt-59 (鈷)
- Copper-63/65 (銅)
- Deuterium-2 (氘)
- Gallium-69/71 (鎵)
- Germanium-73 (鍺)
- Gold-197 (金)
- Hafnium-177/179 (鉿)
- Indium-113-115 (銦)
- Iodine-127 (碘)
- Iridium-191/193 (銥)
- Krypton-83 (氪)
- Lanthanum-139 (鑭)
- Lithium-6/7 (鋰)
- Magnesium-25 (鎂)
- Manganese-55 (錳)
- Mercury-201 (銾)
- Molybdenum-95/97 (鉬)
- Neon-21 (氖)
- Nickel-61 (鎳)
- Niobium-93 (鈮)
- Nitrogen-14 (氮)
- Osmium-189 (鋨)
- Oxygen-17 (氧)
- Palladium-105 (鈀)
- Potassium-39/41 (鉀)
- Rhenium-185/187 (錸)
- Rubidium-85/87 (銣)
- Ruthenium-99/101 (釕)
- Scandium-45 (鈧)
- Sodium-23 (鈉)
- Strontium-87 (鍶)
- Sulfur-33 (硫)
- Tantalum-181 (鉭)
- Titanium-47/49 (鈦)
- Vanadium-51 (釩)
- Xenon-131 (氥)
- Zinc-67 (鋅)
- Zirconium-91 (鋯)