Patents by Inventor Ian J Youngs
Ian J Youngs has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Publication number: 20240147867Abstract: Magnetoelectric magnetic tunnel junction (MEMTJ) logic devices comprise a magnetoelectric switching capacitor coupled to a pair of magnetic tunnel junctions (MTJs) by a conductive layer. The logic state of the MEMTJ is represented by the magnetization orientation of the ferromagnetic layer of the magnetoelectric capacitor, which can be switched through the application of an appropriate input voltage to the MEMTJ. The magnetization orientation of the magnetoelectric capacitor ferromagnetic layer is read out by the MTJs. The conductive layer is positioned between the capacitor and the MTJs. The MTJ ferromagnetic free layers are exchange coupled to the ferromagnetic layer of the magnetoelectric capacitor. The potential of an MTJ free layer is based on a supply voltage applied to the reference layer of the MTJ. The MTJ reference layers have a magnetization orientation that is parallel or antiparallel to the magnetization orientations of the ferromagnetic layer of the magnetoelectric capacitor.Type: ApplicationFiled: October 31, 2022Publication date: May 2, 2024Applicant: Intel CorporationInventors: Punyashloka Debashis, Dominique A. Adams, Hai Li, Chia-Ching Lin, Dmitri Evgenievich Nikonov, Kaan Oguz, John J. Plombon, Ian Alexander Young
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Publication number: 20240120415Abstract: Technologies for a field effect transistor (FET) with a ferroelectric gate dielectric are disclosed. In an illustrative embodiment, a perovskite stack is grown on a buffer layer as part of manufacturing a transistor. The perovskite stack includes one or more doped semiconductor layers alternating with other lattice-matched layers. Growing the doped semiconductor layers on lattice-matched layers can improve the quality of the doped semiconductor layers. The lattice-matched layers can be etched away, leaving the doped semiconductor layers as fins for a ribbon FET. A ferroelectric layer can be conformally grown on the fins, creating a high-quality ferroelectric layer above and below the fins. A gate can then be grown on the ferroelectric layer.Type: ApplicationFiled: October 1, 2022Publication date: April 11, 2024Applicant: Intel CorporationInventors: Scott B. Clendenning, Sudarat Lee, Kevin P. O'Brien, Rachel A. Steinhardt, John J. Plombon, Arnab Sen Gupta, Charles C. Mokhtarzadeh, Gauri Auluck, Tristan A. Tronic, Brandon Holybee, Matthew V. Metz, Dmitri Evgenievich Nikonov, Ian Alexander Young
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Publication number: 20240113212Abstract: Technologies for a field effect transistor (FET) with a ferroelectric gate dielectric are disclosed. In an illustrative embodiment, a perovskite stack is grown on a buffer layer as part of manufacturing a transistor. The perovskite stack includes one or more doped semiconductor layers alternating with other lattice-matched layers, such as undoped semiconductor layers. Growing the doped semiconductor layers on lattice-matched layers can improve the quality of the doped semiconductor layers. The lattice-matched layers can be preferentially etched away, leaving the doped semiconductor layers as fins for a ribbon FET. In another embodiment, an interlayer can be deposited on top of a semiconductor layer, and a ferroelectric layer can be deposited on the interlayer. The interlayer can bridge a gap in lattice parameters between the semiconductor layer and the ferroelectric layer.Type: ApplicationFiled: September 29, 2022Publication date: April 4, 2024Applicant: Intel CorporationInventors: Ian Alexander Young, Dmitri Evgenievich Nikonov, Marko Radosavljevic, Matthew V. Metz, John J. Plombon, Raseong Kim, Kevin P. O'Brien, Scott B. Clendenning, Tristan A. Tronic, Dominique A. Adams, Carly Rogan, Hai Li, Arnab Sen Gupta, Gauri Auluck, I-Cheng Tung, Brandon Holybee, Rachel A. Steinhardt, Punyashloka Debashis
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Publication number: 20240113220Abstract: Technologies for a transistor with a thin-film ferroelectric gate dielectric are disclosed. In the illustrative embodiment, a transistor has a thin layer of scandium aluminum nitride (ScxAl1-xN) ferroelectric gate dielectric. The channel of the transistor may be, e.g., gallium nitride or molybdenum disulfide. In one embodiment, the ferroelectric polarization changes when voltage is applied and removed from a gate electrode, facilitating switching of the transistor at a lower applied voltage. In another embodiment, the ferroelectric polarization of a gate dielectric of a transistor changes when the voltage is past a positive threshold value or a negative threshold value. Such a transistor can be used as a one-transistor memory cell.Type: ApplicationFiled: September 30, 2022Publication date: April 4, 2024Applicant: Intel CorporationInventors: Arnab Sen Gupta, Ian Alexander Young, Dmitri Evgenievich Nikonov, Marko Radosavljevic, Matthew V. Metz, John J. Plombon, Raseong Kim, Uygar E. Avci, Kevin P. O'Brien, Scott B. Clendenning, Jason C. Retasket, Shriram Shivaraman, Dominique A. Adams, Carly Rogan, Punyashloka Debashis, Brandon Holybee, Rachel A. Steinhardt, Sudarat Lee
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Publication number: 20240105810Abstract: In one embodiment, transistor device includes a first source or drain material on a substrate, a semiconductor material on the first source or drain material, a second source or drain material on the semiconductor material, a dielectric layer on the substrate and adjacent the first source or drain material, a ferroelectric (FE) material on the dielectric layer and adjacent the semiconductor material, and a gate material on or adjacent to the FE material. The FE material may be a perovskite material and may have a lattice parameter that is less than a lattice parameter of the semiconductor material.Type: ApplicationFiled: September 23, 2022Publication date: March 28, 2024Applicant: Intel CorporationInventors: Rachel A. Steinhardt, Ian Alexander Young, Dmitri Evgenievich Nikonov, Marko Radosavljevic, Matthew V. Metz, John J. Plombon, Raseong Kim, Kevin P. O'Brien, Scott B. Clendenning, Tristan A. Tronic, Dominique A. Adams, Carly Rogan, Arnab Sen Gupta, Brandon Holybee, Punyashloka Debashis, I-Cheng Tung, Gauri Auluck
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Publication number: 20240105822Abstract: A transistor device may include a first perovskite gate material, a first perovskite ferroelectric material on the first gate material, a first perovskite semiconductor material on the first ferroelectric material, a second perovskite ferroelectric material on the first semiconductor material, a second perovskite gate material on the second ferroelectric material, a third perovskite ferroelectric material on the second gate material, a second perovskite semiconductor material on the third ferroelectric material, a fourth perovskite ferroelectric material on the second semiconductor material, a third perovskite gate material on the fourth ferroelectric material, a first source/drain metal adjacent a first side of each of the first semiconductor material and the second semiconductor material, a second source/drain metal adjacent a second side opposite the first side of each of the first semiconductor material and the second semiconductor material, and dielectric materials between the source/drain metals and theType: ApplicationFiled: September 27, 2022Publication date: March 28, 2024Applicant: Intel CorporationInventors: Kevin P. O'Brien, Brandon Holybee, Carly Rogan, Dmitri Evgenievich Nikonov, Punyashloka Debashis, Rachel A. Steinhardt, Tristan A. Tronic, Ian Alexander Young, Marko Radosavljevic, John J. Plombon
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Publication number: 20240097031Abstract: In one embodiment, a transistor device includes a gate material layer on a substrate, a ferroelectric (FE) material layer on the gate material, a semiconductor channel material layer on the FE material layer, a first source/drain material on the FE material layer and adjacent the semiconductor channel material layer, and a second source/drain material on the FE material layer and adjacent the semiconductor channel material layer and on an opposite side of the semiconductor channel material layer from the first source/drain material. A first portion of the FE material layer is directly between the gate material and the first source/drain material, and a second portion of the FE material layer is directly between the gate material and the second source/drain material.Type: ApplicationFiled: September 16, 2022Publication date: March 21, 2024Applicant: Intel CorporationInventors: Punyashloka Debashis, Rachel A. Steinhardt, Brandon Holybee, Kevin P. O'Brien, Dmitri Evgenievich Nikonov, John J. Plombon, Ian Alexander Young, Raseong Kim, Carly Rogan, Dominique A. Adams, Arnab Sen Gupta, Marko Radosavljevic, Scott B. Clendenning, Gauri Auluck, Hai Li, Matthew V. Metz, Tristan A. Tronic, I-Cheng Tung
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Patent number: 11919863Abstract: The disclosure is directed to improved methods for preparing substituted quinolinylcyclohexylpropanamide compounds.Type: GrantFiled: December 16, 2021Date of Patent: March 5, 2024Assignee: Bristol-Myers Squibb CompanyInventors: Albert J. Delmonte, Benjamin M. Cohen, Kenneth Joseph Fraunhoffer, Sergei Kolotuchin, Francisco Gonzalez-Bobes, Gregory Louis Beutner, Adam Joseph Freitag, Michael Scott Bultman, Yu Fan, Prantik Maity, Ian Scott Young, Hilary Plake Beck, Maksim Osipov, Jay Patrick Powers, Maureen Kay Reilly, Hunter Paul Shunatona, James Ross Walker, Mikhail Zibinsky
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Patent number: 6074471Abstract: This invention relates to metal oxides based films and a method for their production via a sol-gel route using metal bis(.beta.-diketonate) salts as precursors. They can be conveniently doped by Group (III), (IV) or (V) impurities and may be used to provide coductive coating on optically transparent substrates such as glass, ceramics or polymers.Type: GrantFiled: June 29, 1998Date of Patent: June 13, 2000Assignee: The Secretary of State for Defence in Her Britannic Majesty's Government of the United Kingdom of Great Britain and Northern IrelandInventors: Peter J S Foot, Richard Singer, Maria Sugrue, Ian J Youngs