Skip to main content

We use cookies to distinguish you from other users and to provide you with a better experience on our websites. Close this message to accept cookies or find out how to manage your cookie settings.

Close cookie message
Cancel
×
×
Home
  • Home
Chapter
  • Print publication year: 2016
  • Online publication date: December 2016

7 - Electron Beam Effects in Liquid Cell TEM and STEM

from Part I - Technique
Export citation
Recommend this book

Email your librarian or administrator to recommend adding this book to your organisation's collection.

Liquid Cell Electron Microscopy
  • Online ISBN: 9781316337455
  • Book DOI: https://doi.org/10.1017/9781316337455
Please enter your name
Please enter a valid email address
Who would you like to send this to *

CAPTCHA *

Skip to the audio challenge
×
1.Grogan, J. M., Schneider, N. M., Ross, F. M. and Bau, H. H., Bubble and pattern formation in liquid induced by an electron beam. Nano Lett., 14 (2014), 359364.
2.Schneider, N. M., Norton, M. M., Mendel, B. J. et al., Electron–water interactions and implications for liquid cell electron microscopy. J. Phys. Chem. C, 118 (2014), 2237322382.
3.Spinks, J. W. T. and Woods, R. J., An Introduction to Radiation Chemistry (New York: Wiley-Interscience, 1990).
4.Allen, A. O., The Radiation Chemistry of Water and Aqueous Solutions (Princeton, NJ: Van Nostrand, 1961).
5.Draganic, I., The Radiation Chemistry of Water (New York: Elsevier, 2012).
6.Pastina, B. and LaVerne, J. A., Effect of molecular hydrogen on hydrogen peroxide in water radiolysis. J. Phys. Chem. A, 105 (2001), 93169322.
7.Elliot, A. J. and McCracken, D. R., Computer modeling of the radiolysis in an aqueous lithium salt blanket: suppression of radiolysis by addition of hydrogen. Fusion Eng. Des., 13 (1990), 2127.
8.Joseph, J. M., Choi, B. S., Yakabuskie, P. and Wren, J. C., A combined experimental and model analysis on the effect of pH and O2(aq) on γ-radiolytically produced H2 and H2O2. Radiation Phys. Chem., 77 (2008), 10091020.
9.Carron, N. J., An Introduction to the Passage of Energetic Particles through Matter (Boca Raton, FL: CRC Press, 2006).
10.Bethe, H. A. and Ashkin, J., Bethe: Passage of radiations through matter. In Segre, E., ed., Experimental Nuclear Physics Vol. 1, (New York: Wiley, 1953).
11.Berger, M. J., Coursey, J. S., Zucker, M. A. and Chang, J., NIST Stopping-Power and Range Tables: Electrons, Protons, Helium Ions. Available at http://physics.nist.gov/PhysRefData/Star/Text/ESTAR.html [Accessed: 3 November 2014].
12.LaVerne, J. A. and Pimblott, S. M., Electron energy-loss distributions in solid, dry DNA. Rad. Res., 141 (1995), 208215.
13.Tabata, T., A simple calculation for mean projected range of fast electrons. J. Appl. Phys., 39 (1968), 53425343.
14.Rose, M. E., Electron path lengths in multiple scattering. Phys. Rev., 58 (1940), 90.
15.Drouin, D., Couture, A. R., Joly, D. et al., CASINO V2.42: a fast and easy-to-use modeling tool for scanning electron microscopy and microanalysis users. Scanning, 29 (2007), 92101.
16.Zheng, H., Claridge, S. A., Minor, A. M., Alivisatos, A. P. and Dahmen, U., Nanocrystal diffusion in a liquid thin film observed by in situ transmission electron microscopy. Nano Lett., 9 (2009), 24602465.
17.Schwarz, H. A., Applications of the spur diffusion model to the radiation chemistry of aqueous solutions. J. Phys. Chem., 73 (1969), 19281937.
18.Buxton, G. V., Greenstock, C. L., Helman, W. P. and Ross, A. B., Critical-review of rate constants for reactions of hydrated electrons, hydrogen-atoms and hydroxyl radicals in aqueous solution. J. Phys. Chem. Ref. Data, 17 (1988), 513886.
19.Hill, M. A. and Smith, F. A., Calculation of initial and primary yields in the radiolysis of water. Rad. Phys. Chem., 43 (1994), 265280.
20.Pimblott, S. M. and LaVerne, J. A., Molecular product formation in the electron radiolysis of water. Rad. Res., 129 (1992), 265271.
21.Christensen, H., Remodeling of the oxidant species during radiolysis of high-temperature water in a pressurized water reactor. Nucl. Technol., 109 (1995), 373382.
22.Burton, M., Radiation chemistry. J. Phys. Chem., 51 (1947), 611625.
23.Speight, J., Lange’s Handbook of Chemistry (New York: McGraw-Hill Professional, 2004).
24.Schneider, N. M./Radiolysis, github.com. Available at https://github.com/NMSchneider/Radiolysis [Accessed: 30 June 2014].
25.Hart, E. J., The hydrated electron: properties and reactions of this most reactive and elementary of aqueous negative ions are discussed. Science, 146 (1964), 1925.
26.Grogan, J. M., Rotkina, L. and Bau, H. H., In situ liquid-cell electron microscopy of colloid aggregation and growth dynamics. Phys. Rev. E, 83 (2011), 061405.
27.Mirsaidov, U., Ohl, C.-D. and Matsudaira, P., A direct observation of nanometer-size void dynamics in an ultra-thin water film. Soft Matter, 8 (2012), 71087111.
28.Huang, T.-W., Liu, S.-Y., Chuang, Y.-J. et al., Dynamics of hydrogen nanobubbles in KLH protein solution studied with in situ wet-TEM. Soft Matter, 9 (2013), 88568861.
29.Klein, K. L., Anderson, I. M. and de Jonge, N., Transmission electron microscopy with a liquid flow cell. J. Microsc., 242 (2011), 117123.
30.Jones, S., Bubble nucleation from gas cavities: a review. Adv. Coll. Interf. Sci., 80 (1999), 2750.
31.Li, D., Nielsen, M. H., Lee, J. R. I. et al., Direction-specific interactions control crystal growth by oriented attachment. Science, 336 (2012), 10141018.
32.Woehl, T. J., Evans, J. E., Arslan, I., Ristenpart, W. D. and Browning, N. D., Direct in situ determination of the mechanisms controlling nanoparticle nucleation and growth. ACS Nano, 6 (2012), 85998610.
33.Noh, K. W., Liu, Y., Sun, L. and Dillon, S. J., Challenges associated with in-situ TEM in environmental systems: the case of silver in aqueous solutions. Ultramicroscopy, 116 (2012), 3438.
34.Lee, J., Urban, A., Li, X. et al., Unlocking the potential of cation-disordered oxides for rechargeable lithium batteries. Science, 343 (2014), 519522.
35.Bresin, M., Nadimpally, B. R., Nehru, N., Singh, V. P. and Hastings, J. T., Site-specific growth of CdS nanostructures. Nanotechnology, 24 (2013), 505305.
36.Park, J., Kodambaka, S., Ross, F. M., Grogan, J. M. and Bau, H. H., In situ liquid cell transmission electron microscopic observation of electron beam induced Au crystal growth in a solution. Microsc. Microanal., 18 (2012), 10981099.
37.den Heijer, M., Shao, I., Radisic, A., Reuter, M. C. and Ross, F. M., Patterned electrochemical deposition of copper using an electron beam. APL Materials, 2 (2014), 022101.
38.Remita, H., Lampre, I., Mostafavi, M., Balanzat, E. and Bouffard, S., Comparative study of metal clusters induced in aqueous solutions by γ-rays, electron or C6+ ion beam irradiation. Rad. Phys. Chem., 72 (2005), 575586.
39.Abidi, W. and Remita, H., Gold based nanoparticles generated by radiolytic and photolytic methods. Recent Patents in Eng., 4 (2010), 170188.
40.Mullins, W. W. and Sekerka, R. F., Stability of a planar interface during solidification of a dilute binary alloy. J. Appl. Phys., 35 (1964), 444451.
41.Evans, J. E., Jungjohann, K. L., Browning, N. D. and Arslan, I., Controlled growth of nanoparticles from solution with in situ liquid transmission electron microscopy. Nano Lett., 11 (2011), 28092813.
42.Zheng, H., Smith, R. K., Jun, Y. W. et al., Observation of single colloidal platinum nanocrystal growth trajectories. Science, 324 (2009), 13091312.
43.Mallard, W. G., Ross, A. B. and Helman, W. P., NDRL/NIST Solution Kinetics Database on the Web: A complication of kinetics data on solution-phase reactions. Available at http://kinetics.nist.gov/solution/ [Accessed: 6 April 2015].
44.Park, J. H., Schneider, N. M., Grogan, J. M. et al., Control of electron beam-induced Au nanocrystal growth kinetics through solution chemistry. Nano Lett., 15 (2015), 53145320.
45.Mozumder, A., Fundamentals of Radiation Chemistry (London: Elsevier Science, 1999).
46.Mincher, B. J. and Wishart, J. F., The radiation chemistry of ionic liquids: a review. Solvent Extraction and Ion Exchange, 32 (2014), 563583.
47.Huang, J. Y., Zhong, L., Wang, C. M. et al., In situ observation of the electrochemical lithiation of a single SnO2 nanowire electrode. Science, 330 (2010), 15151520.
Cancel
Confirm
×