A major contributor to this article appears to have a
close connection with its subject. (May 2020) |
Khalil Amine | |
---|---|
Born | |
Alma mater | University of Bordeaux |
Organization(s) | Argonne National Laboratory, Stanford University, Imam Abdulrahman Bin Faisal University |
Known for | development of advanced battery materials |
Website | https://www.anl.gov/profile/khalil-amine |
Khalil Amine (born 1962) is a materials scientist at Argonne National Laboratory, an Argonne distinguished fellow, [1] and group leader of the Battery Technology group. His research team is focused [2] on the development of advanced battery systems for transportation applications. In addition to his Argonne appointment, he is an adjunct professor at Stanford University, [3] Imam Abdulrahman Bin Faisal University, [4] Hong Kong University of Science & Technology, King Abdulaziz University, Hanyang University, and Peking University.
For his contributions in the field of electrochemical materials development, [5] Amine was awarded the Global Energy Prize in 2019, and Scientific American's Top Worldwide 50 Research Leader Award in 2003. [6] In 2017, Amine was chosen as a Fellow [7] of the Electrochemical Society. He is the founder and chairman [8] [9] of the Advanced Lithium Battery for Automotive Application (ABAA) global conference.
Amine received his [4] Ph.D. in materials science in 1989 [4] from the University of Bordeaux in France. After completing his doctorate, Amine did postdoctoral studies at Katholieke Universiteit Leuven in Belgium. Moving to Japan in the early 1990s, [4] Amine held various positions at Japan Storage Battery Company, the Osaka National Research Institute, and Kyoto University, before moving to Argonne National Laboratory in 1998.
● Cathode materials based on the AB2O4 spinel structure have been studied extensively since the mid-1980s due to their stability, high lithium-ion diffusion, and large number of materials that crystallize with this stoichiometry. In 1996, Amine and co-workers reported the synthesis and electrochemistry of the ordered spinel LiNi0.5Mn1.5O4 (1996), a cathode often called "5V spinel". It is notable for its stable high voltage with a typical capacity of 125 mAh/g. The compound operates using only the nickel content as the active redox species while the structure inhibits charge compensation by oxygen evolution.
● Amine and co-workers have been active in the studying the lithium-ion cathode materials termed NMC cathodes (patent issued 2005). The materials structure is based on intergrowths of constituent nano-domains of two closely related layered oxides. They are widely used cathode materials in consumer electronics and electric vehicles. [10] NMC technology has been incorporated into multiple batteries types around the world including those that powered GM's Chevy Volt and Bolt. [11] [12] [13] [14] [15] Depending on the lithium content, these materials show an activation step on the first charging cycle that creates a heterogeneous electrochemically active material with capacities greater than 220 mAh/g.
● One of the instabilities of NMC cathodes involves the redox activity of the highly charged cations at the surface against the solvent molecules of the organic electrolyte. In 2012 Amine and Prof Yang Kook Sun from Hanyang University, [16] [17] reported an improvement over the standard NMC cathode by devising a synthetic strategy that slightly orders the constituent cations to create a gradient structure that allows for the surface to be less reactive than the bulk. An advanced version of the NMC cathode technology allows for a wide range of formulations and compositions [18] to be created across each particle to increase both energy and stability at high voltage. [17]
● Lithium-air technology, including a new series of catalysts (2007) developed with Larry Curtiss of Argonne National Laboratory for Lithium-air energy storage systems that increase reversibility, was developed to reduce the overpotential observed in air-based systems associated with the needed electron transfer reactions. [19] [20] In 2013 they improved on the system by developing a closed oxygen system that results in a significant simplification of the purification and storage system. The system stores energy in the couple going from superoxide (O2−) anion to the peroxide (O2−2) anion. The net reaction is (LiO2 +Li –-> Li2O2). [21]
A major contributor to this article appears to have a
close connection with its subject. (May 2020) |
Khalil Amine | |
---|---|
Born | |
Alma mater | University of Bordeaux |
Organization(s) | Argonne National Laboratory, Stanford University, Imam Abdulrahman Bin Faisal University |
Known for | development of advanced battery materials |
Website | https://www.anl.gov/profile/khalil-amine |
Khalil Amine (born 1962) is a materials scientist at Argonne National Laboratory, an Argonne distinguished fellow, [1] and group leader of the Battery Technology group. His research team is focused [2] on the development of advanced battery systems for transportation applications. In addition to his Argonne appointment, he is an adjunct professor at Stanford University, [3] Imam Abdulrahman Bin Faisal University, [4] Hong Kong University of Science & Technology, King Abdulaziz University, Hanyang University, and Peking University.
For his contributions in the field of electrochemical materials development, [5] Amine was awarded the Global Energy Prize in 2019, and Scientific American's Top Worldwide 50 Research Leader Award in 2003. [6] In 2017, Amine was chosen as a Fellow [7] of the Electrochemical Society. He is the founder and chairman [8] [9] of the Advanced Lithium Battery for Automotive Application (ABAA) global conference.
Amine received his [4] Ph.D. in materials science in 1989 [4] from the University of Bordeaux in France. After completing his doctorate, Amine did postdoctoral studies at Katholieke Universiteit Leuven in Belgium. Moving to Japan in the early 1990s, [4] Amine held various positions at Japan Storage Battery Company, the Osaka National Research Institute, and Kyoto University, before moving to Argonne National Laboratory in 1998.
● Cathode materials based on the AB2O4 spinel structure have been studied extensively since the mid-1980s due to their stability, high lithium-ion diffusion, and large number of materials that crystallize with this stoichiometry. In 1996, Amine and co-workers reported the synthesis and electrochemistry of the ordered spinel LiNi0.5Mn1.5O4 (1996), a cathode often called "5V spinel". It is notable for its stable high voltage with a typical capacity of 125 mAh/g. The compound operates using only the nickel content as the active redox species while the structure inhibits charge compensation by oxygen evolution.
● Amine and co-workers have been active in the studying the lithium-ion cathode materials termed NMC cathodes (patent issued 2005). The materials structure is based on intergrowths of constituent nano-domains of two closely related layered oxides. They are widely used cathode materials in consumer electronics and electric vehicles. [10] NMC technology has been incorporated into multiple batteries types around the world including those that powered GM's Chevy Volt and Bolt. [11] [12] [13] [14] [15] Depending on the lithium content, these materials show an activation step on the first charging cycle that creates a heterogeneous electrochemically active material with capacities greater than 220 mAh/g.
● One of the instabilities of NMC cathodes involves the redox activity of the highly charged cations at the surface against the solvent molecules of the organic electrolyte. In 2012 Amine and Prof Yang Kook Sun from Hanyang University, [16] [17] reported an improvement over the standard NMC cathode by devising a synthetic strategy that slightly orders the constituent cations to create a gradient structure that allows for the surface to be less reactive than the bulk. An advanced version of the NMC cathode technology allows for a wide range of formulations and compositions [18] to be created across each particle to increase both energy and stability at high voltage. [17]
● Lithium-air technology, including a new series of catalysts (2007) developed with Larry Curtiss of Argonne National Laboratory for Lithium-air energy storage systems that increase reversibility, was developed to reduce the overpotential observed in air-based systems associated with the needed electron transfer reactions. [19] [20] In 2013 they improved on the system by developing a closed oxygen system that results in a significant simplification of the purification and storage system. The system stores energy in the couple going from superoxide (O2−) anion to the peroxide (O2−2) anion. The net reaction is (LiO2 +Li –-> Li2O2). [21]