His Metallurgy research encompasses a variety of disciplines, including Alloy and Chemical engineering. Chemical engineering and Metallurgy are two areas of study in which he engages in interdisciplinary work. Other disciplines of study, such as Conductivity and Doping, are mixed together with his Electrical resistivity and conductivity studies. Jeff Wolfenstine performs multidisciplinary study in Doping and Electrical resistivity and conductivity in his work. He undertakes interdisciplinary study in the fields of Organic chemistry and Inorganic chemistry through his works. In his works, he conducts interdisciplinary research on Inorganic chemistry and Ion. His Ion study typically links adjacent topics like Organic chemistry. His research on Composite material often connects related areas such as Composite number. The study of Composite number is intertwined with the study of Carbon fibers in a number of ways.
Composite material and Creep are frequently intertwined in his study. In most of his Creep studies, his work intersects topics such as Metallurgy. Jeff Wolfenstine connects Metallurgy with Alloy in his research. His research brings together the fields of Composite material and Alloy. By researching both Physical chemistry and Chemical engineering, he produces research that crosses academic boundaries. Jeff Wolfenstine conducted interdisciplinary study in his works that combined Chemical engineering and Physical chemistry. His Organic chemistry study frequently intersects with other fields, such as Ion. His research on Ion often connects related topics like Organic chemistry. Jeff Wolfenstine performs integrative study on Thermodynamics and Diffusion in his works.
His research brings together the fields of Cracking and Composite material. In most of his Physical chemistry studies, his work intersects topics such as Conductivity. His research combines Physical chemistry and Conductivity. Jeff Wolfenstine combines Mineralogy and Metallurgy in his studies. His Metallurgy study frequently intersects with other fields, such as Crystallite. Many of his studies involve connections with topics such as Characterization (materials science) and Nanotechnology. His study on Characterization (materials science) is mostly dedicated to connecting different topics, such as Nanotechnology. He undertakes multidisciplinary investigations into Nanoindentation and Young's modulus in his work. He integrates Young's modulus and Nanoindentation in his research.
His Physical chemistry study frequently links to adjacent areas such as Conductivity. Many of his studies on Conductivity involve topics that are commonly interrelated, such as Physical chemistry. His Analytical Chemistry (journal) research extends to the thematically linked field of Chromatography. His study on Analytical Chemistry (journal) is mostly dedicated to connecting different topics, such as Chromatography. In his papers, he integrates diverse fields, such as Electrode and Electrolyte. In his papers, he integrates diverse fields, such as Electrolyte and Electrode. His research on Thermodynamics often connects related areas such as Current (fluid). His Current (fluid) study frequently involves adjacent topics like Thermodynamics. His Programming language study frequently draws connections to adjacent fields such as Substitution (logic).
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The Role of Al and Li Concentration on the Formation of Cubic Garnet Solid Electrolyte of Nominal Composition Li7La3Zr2O12
Ezhiyl Rangasamy;Jeff Wolfenstine;Jeffrey Sakamoto.
Solid State Ionics (2012)
Oxygen Transport Properties of Organic Electrolytes and Performance of Lithium/Oxygen Battery
J. Read;K. Mutolo;M. Ervin;W. Behl.
Journal of The Electrochemical Society (2003)
Effect of substitution (Ta, Al, Ga) on the conductivity of Li7La3Zr2O12
J.L. Allen;J. Wolfenstine;E. Rangasamy;J. Sakamoto.
Journal of Power Sources (2012)
Characterizing the Li–Li7La3Zr2O12 interface stability and kinetics as a function of temperature and current density
Asma Sharafi;Harry M. Meyer;Jagjit Nanda;Jeff Wolfenstine.
Journal of Power Sources (2016)
The Limits of Low‐Temperature Performance of Li‐Ion Cells
C. ‐K. Huang;J. S. Sakamoto;J. Wolfenstine;S. Surampudi.
Journal of The Electrochemical Society (2000)
Elastic Properties of the Solid Electrolyte Li7La3Zr2O12 (LLZO)
Seungho Yu;Robert D. Schmidt;Regina Garcia-Mendez;Erik Herbert.
Chemistry of Materials (2016)
Electrical conductivity and charge compensation in Ta doped Li4Ti5O12
J. Wolfenstine;J.L. Allen.
Journal of Power Sources (2008)
Ni3+/Ni2+ redox potential in LiNiPO4
J. Wolfenstine;J. Allen.
Journal of Power Sources (2005)
Tetragonal vs. cubic phase stability in Al – free Ta doped Li7La3Zr2O12 (LLZO)
Travis Thompson;Jeff Wolfenstine;Jan L. Allen;Michelle Johannes.
Journal of Materials Chemistry (2014)
Room temperature elastic moduli and Vickers hardness of hot-pressed LLZO cubic garnet
Jennifer E. Ni;Eldon D. Case;Jeffrey S. Sakamoto;Ezhiyl Rangasamy.
Journal of Materials Science (2012)
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