Page 304 - Read Online

P. 304

Zhou et al. Microstructures 2023;3:2023043 https://dx.doi.org/10.20517/microstructures.2023.38 Page 21 of 23

probe. Ultramicroscopy 2023;253:113826. DOI PubMed
24. Shen PS. The 2017 nobel prize in chemistry: cryo-EM comes of age. Anal Bioanal Chem 2018;410:2053-7. DOI
25. Moore EB, Molinero V. Structural transformation in supercooled water controls the crystallization rate of ice. Nature 2011;479:506-8.
DOI PubMed
26. Dubochet J, Adrian M, Chang JJ, et al. Cryo-electron microscopy of vitrified specimens. Q Rev Biophys 1988;21:129-228. DOI
27. Gerstl S, Wepf R. Methods in creating, transferring, & measuring cryogenic samples for APT. Microsc Microanal 2015;21:517-8.
DOI
28. Perea DE, Gerstl SSA, Chin J, Hirschi B, Evans JE. An environmental transfer hub for multimodal atom probe tomography. Adv Struct
Chem Imaging 2017;3:12. DOI PubMed PMC
29. McCarroll IE, Bagot PAJ, Devaraj A, Perea DE, Cairney JM. New frontiers in atom probe tomography: a review of research enabled
by cryo and/or vacuum transfer systems. Mater Today Adv 2020;7:100090. DOI PubMed PMC
30. El-Zoka AA, Stephenson LT, Kim SH, Gault B, Raabe D. The fate of water in hydrogen-based iron oxide reduction. Adv Sci
2023;10:e2300626. DOI PubMed PMC
31. Stender P, Gault B, Schwarz TM, et al. Status and direction of atom probe analysis of frozen liquids. Microsc Microanal
2022;28:1150-67. DOI
32. El-Zoka AA, Kim SH, Deville S, Newman RC, Stephenson LT, Gault B. Enabling near-atomic-scale analysis of frozen water. Sci Adv
2020;6:eabd6324. DOI PubMed PMC
33. Chen Y, Bagot PA, Moody MP, Haley D. Observing hydrogen in steel using cryogenic atom probe tomography: a simplified approach.
Int J Hydrog Energy 2019;44:32280-91. DOI
34. Chen YS, Lu H, Liang J, et al. Observation of hydrogen trapping at dislocations, grain boundaries, and precipitates. Science
2020;367:171-5. DOI
35. Moody MP, Vella A, Gerstl SS, Bagot PA. Advances in atom probe tomography instrumentation: implications for materials research.
MRS Bull 2016;41:40-5. DOI
36. Stephenson LT, Szczepaniak A, Mouton I, et al. The laplace project: an integrated suite for preparing and transferring atom probe
samples under cryogenic and UHV conditions. PLoS One 2018;13:e0209211. DOI PubMed PMC
37. Miller MK. Atom probe microanalysis, principles and applications to materials problems. Mater Res Soc 1989. Available from: https://
inis.iaea.org/collection/NCLCollectionStore/_Public/19/064/19064040.pdf?r=1 [Last accessed on 31 Oct 2023].
38. Melmed AJ. The art and science and other aspects of making sharp tips. J Vac Sci Technol B 1991;9:601-8. DOI
39. Schreiber DK, Perea DE, Ryan JV, Evans JE, Vienna JD. A method for site-specific and cryogenic specimen fabrication of liquid/solid
interfaces for atom probe tomography. Ultramicroscopy 2018;194:89-99. DOI PubMed
40. Chen YS, Haley D, Gerstl SS, et al. Direct observation of individual hydrogen atoms at trapping sites in a ferritic steel. Science
2017;355:1196-9. DOI
41. Zachman MJ, de Jonge N, Fischer R, Jungjohann KL, Perea DE. Cryogenic specimens for nanoscale characterization of solid-liquid
interfaces. MRS Bull 2019;44:949-55. DOI
42. Meng K, Schwarz TM, Weikum EM, Stender P, Schmitz G. Frozen n -tetradecane investigated by cryo-atom probe tomography.
Microsc Microanal 2022;28:1289-99. DOI
43. Ackerman AK, Vorontsov VA, Bantounas I, et al. Interface characteristics in an α + β titanium alloy. Phys Rev Mater 2020;4:013602. DOI
44. Zhang S, Gervinskas G, Qiu S, et al. Methods of preparing nanoscale vitreous ice needles for high-resolution cryogenic
characterization. Nano Lett 2022;22:6501-8. DOI
45. Lilensten L, Gault B. New approach for FIB-preparation of atom probe specimens for aluminum alloys. PLoS One 2020;15:e0231179.
DOI PubMed PMC
46. Chang Y, Lu W, Guénolé J, et al. Ti and its alloys as examples of cryogenic focused ion beam milling of environmentally-sensitive
materials. Nat Commun 2019;10:942. DOI PubMed PMC
47. Halpin JE, Webster RWH, Gardner H, Moody MP, Bagot PAJ, MacLaren DA. An in-situ approach for preparing atom probe
tomography specimens by xenon plasma-focussed ion beam. Ultramicroscopy 2019;202:121-7. DOI PubMed
48. Marko M, Hsieh C, Schalek R, Frank J, Mannella C. Focused-ion-beam thinning of frozen-hydrated biological specimens for cryo-
electron microscopy. Nat Methods 2007;4:215-7. DOI PubMed
49. Rigort A, Bäuerlein FJ, Villa E, et al. Focused ion beam micromachining of eukaryotic cells for cryoelectron tomography. Proc Natl
Acad Sci USA 2012;109:4449-54. DOI PubMed PMC
50. Mahamid J, Schampers R, Persoon H, Hyman AA, Baumeister W, Plitzko JM. A focused ion beam milling and lift-out approach for
site-specific preparation of frozen-hydrated lamellas from multicellular organisms. J Struct Biol 2015;192:262-9. DOI PubMed
51. Parmenter CD, Fay MW, Hartfield C, Eltaher HM. Making the practically impossible “merely difficult”-cryogenic FIB lift-out for
“damage free” soft matter imaging. Microsc Res Tech 2016;79:298-303. DOI PubMed
52. Saxey DW, Cairney JM, McGrouther D, Honma T, Ringer SP. Atom probe specimen fabrication methods using a dual FIB/SEM.
Ultramicroscopy 2007;107:756-60. DOI PubMed
53. Gordon LM, Joester D. Nanoscale chemical tomography of buried organic-inorganic interfaces in the chiton tooth. Nature
2011;469:194-7. DOI PubMed
54. Gordon LM, Tran L, Joester D. Atom probe tomography of apatites and bone-type mineralized tissues. ACS Nano 2012;6:10667-75.
DOI PubMed

299 300 301 302 303 304 305 306 307 308 309