Michael Stadermann
Michael Stadermann
Verified email at llnl.gov
Cited by
Cited by
Fast mass transport through sub-2-nanometer carbon nanotubes
JK Holt, HG Park, Y Wang, M Stadermann, AB Artyukhin, ...
Science 312 (5776), 1034-1037, 2006
Ion exclusion by sub-2-nm carbon nanotube pores
F Fornasiero, HG Park, JK Holt, M Stadermann, CP Grigoropoulos, A Noy, ...
Proceedings of the National Academy of Sciences 105 (45), 17250-17255, 2008
Advanced carbon aerogels for energy applications
J Biener, M Stadermann, M Suss, MA Worsley, MM Biener, KA Rose, ...
Energy & Environmental Science 4 (3), 656-667, 2011
Review of the national ignition campaign 2009-2012
J Lindl, O Landen, J Edwards, E Moses, NIC team
Physics of Plasmas 21 (2), 020501, 2014
Capacitive desalination with flow-through electrodes
ME Suss, TF Baumann, WL Bourcier, CM Spadaccini, KA Rose, ...
Energy & Environmental Science 5 (11), 9511-9519, 2012
Nanoscale study of conduction through carbon nanotube networks
M Stadermann, SJ Papadakis, MR Falvo, J Novak, E Snow, Q Fu, J Liu, ...
Physical Review B 69 (20), 201402, 2004
Mechanically robust 3D graphene macroassembly with high surface area
MA Worsley, SO Kucheyev, HE Mason, MD Merrill, BP Mayer, J Lewicki, ...
Chemical Communications 48 (67), 8428-8430, 2012
Ultrafast gas chromatography on single-wall carbon nanotube stationary phases in microfabricated channels
M Stadermann, AD McBrady, B Dick, VR Reid, A Noy, RE Synovec, ...
Analytical chemistry 78 (16), 5639-5644, 2006
Fusion energy output greater than the kinetic energy of an imploding shell at the National Ignition Facility
S Le Pape, LFB Hopkins, L Divol, A Pak, EL Dewald, S Bhandarkar, ...
Physical review letters 120 (24), 245003, 2018
Demonstration of ignition radiation temperatures in indirect-drive inertial confinement fusion hohlraums
SH Glenzer, BJ MacGowan, NB Meezan, PA Adams, JB Alfonso, ET Alger, ...
Physical review letters 106 (8), 085004, 2011
Controlled electrostatic gating of carbon nanotube FET devices
AB Artyukhin, M Stadermann, RW Friddle, P Stroeve, O Bakajin, A Noy
Nano letters 6 (9), 2080-2085, 2006
Energy consumption analysis of constant voltage and constant current operations in capacitive deionization
Y Qu, PG Campbell, L Gu, JM Knipe, E Dzenitis, JG Santiago, ...
Desalination 400, 18-24, 2016
Performance metrics for the objective assessment of capacitive deionization systems
SA Hawks, A Ramachandran, S Porada, PG Campbell, ME Suss, ...
Water research 152, 126-137, 2019
Characterization of resistances of a capacitive deionization system
Y Qu, TF Baumann, JG Santiago, M Stadermann
Environmental science & technology 49 (16), 9699-9706, 2015
Energy breakdown in capacitive deionization
A Hemmatifar, JW Palko, M Stadermann, JG Santiago
Water research 104, 303-311, 2016
First high-convergence cryogenic implosion in a near-vacuum hohlraum
LFB Hopkins, NB Meezan, S Le Pape, L Divol, AJ Mackinnon, DD Ho, ...
Physical review letters 114 (17), 175001, 2015
High-speed, temperature programmable gas chromatography utilizing a microfabricated chip with an improved carbon nanotube stationary phase
VR Reid, M Stadermann, O Bakajin, RE Synovec
Talanta 77 (4), 1420-1425, 2009
Two-dimensional porous electrode model for capacitive deionization
A Hemmatifar, M Stadermann, JG Santiago
The Journal of Physical Chemistry C 119 (44), 24681-24694, 2015
Mechanism and kinetics of growth termination in controlled chemical vapor deposition growth of multiwall carbon nanotube arrays
M Stadermann, SP Sherlock, JB In, F Fornasiero, HG Park, AB Artyukhin, ...
Nano letters 9 (2), 738-744, 2009
Super‐compressibility of ultralow‐density nanoporous silica
SO Kucheyev, M Stadermann, SJ Shin, JH Satcher Jr, SA Gammon, ...
Advanced Materials 24 (6), 776-780, 2012
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