The scientist’s investigation covers issues in Molecular dynamics, Composite material, Nanotechnology, Mechanics and Slip. Her studies examine the connections between Molecular dynamics and genetics, as well as such issues in Molecular physics, with regards to Graphite. The study incorporates disciplines such as Thin film and Single crystal in addition to Composite material.
Her work on Graphene is typically connected to Context as part of general Nanotechnology study, connecting several disciplines of science. Ashlie Martini has researched Mechanics in several fields, including Lubrication, Shear and Lubricant. Her research in Nanocomposite intersects with topics in Nanocellulose, Bacterial cellulose, Composite number, Microstructure and Nanomaterials.
Ashlie Martini mostly deals with Molecular dynamics, Composite material, Nanotechnology, Mechanics and Nanoscopic scale. She combines subjects such as Chemical physics, Molecule, Graphene and Thermodynamics with her study of Molecular dynamics. Her work deals with themes such as Metallurgy, Nanocrystal and Transmission electron microscopy, which intersect with Composite material.
Her Mechanics study integrates concerns from other disciplines, such as Slip and Engineering drawing. Her Nanoscopic scale research integrates issues from Monolayer, Substrate and Contact area. Her Lubricant research incorporates themes from Lubrication and Chemical engineering.
Ashlie Martini spends much of her time researching Molecular dynamics, Tribology, Composite material, Chemical engineering and Nanoscopic scale. Her biological study spans a wide range of topics, including Chemical physics, Crystallization, Amorphous solid, Monolayer and Oxygen. Her research integrates issues of Engineering ethics and Scope in her study of Tribology.
Her Composite material research is multidisciplinary, incorporating elements of Work and Continuum mechanics. Her Chemical engineering study combines topics in areas such as Decomposition and Inert. Her studies deal with areas such as In situ and Mechanical engineering, Contact pressure as well as Nanoscopic scale.
Tribology, Molecular dynamics, Dry lubricant, Nanotechnology and Chemical physics are her primary areas of study. Her Tribology study incorporates themes from Titanium alloy, Film coating, Coating and Nitriding. The Molecular dynamics study combines topics in areas such as Monolayer and Asperity.
Her Dry lubricant research incorporates elements of Doping, Polymer science and Molybdenum disulfide. Ashlie Martini combines subjects such as Cellulose and Structural material with her study of Nanotechnology. Her work deals with themes such as Chemical reaction, Chemical bond, Mechanochemistry and Current, which intersect with Chemical physics.
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Cellulose nanomaterials review: structure, properties and nanocomposites
Robert J. Moon;Robert J. Moon;Ashlie Martini;John Nairn;John Simonsen.
Chemical Society Reviews (2011)
Expected Performance of the ATLAS Experiment - Detector, Trigger and Physics
G. Aad;E. Abat;B. Abbott.
arXiv: High Energy Physics - Experiment (2008)
Measurement of inclusive jet and dijet cross sections in proton-proton collisions at 7 TeV centre-of-mass energy with the ATLAS detector
G. Aad;B. Abbott;J. Abdallah;A.A. Abdelalim.
European Physical Journal C (2011)
Processing bulk natural wood into a high-performance structural material
Jianwei Song;Chaoji Chen;Shuze Zhu;Mingwei Zhu.
A radiative cooling structural material.
Tian Li;Yao Zhai;Shuaiming He;Wentao Gan.
Performance of the ATLAS detector using first collision data
G. Aad;G. Aad;E. Abat;B. Abbott;J. Abdallah.
Journal of High Energy Physics (2010)
Speed dependence of atomic stick-slip friction in optimally matched experiments and molecular dynamics simulations.
Qunyang Li;Yalin Dong;Danny Perez;Ashlie Martini.
Physical Review Letters (2011)
Solid Lubrication with MoS2: A Review
Mohammad R. Vazirisereshk;Ashlie Martini;David A. Strubbe;Mehmet Z. Baykara.
The Belle II Physics Book
E. Kou;P. Urquijo;W. Altmannshofer;F. Beaujean.
arXiv: High Energy Physics - Experiment (2018)
Thermal expansion of self-organized and shear-oriented cellulose nanocrystal films.
Jairo A. Diaz;Xiawa Wu;Ashlie Martini;Jeffrey P. Youngblood.
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