公开(公告)号：US20250008852A1

公开(公告)日：2025-01-02

申请号：US18346212

申请日：2023-07-01

Applicant: Intel Corporation

Inventor： Punyashloka Debashis ,  Dominique A. Adams ,  Gauri Auluck ,  Scott B. Clendenning ,  Arnab Sen Gupta ,  Brandon Holybee ,  Raseong Kim ,  Matthew V. Metz ,  Kevin P. O'Brien ,  John J. Plombon ,  Marko Radosavljevic ,  Carly Rogan ,  Hojoon Ryu ,  Rachel A. Steinhardt ,  Tristan A. Tronic ,  I-Cheng Tung ,  Ian Alexander Young ,  Dmitri Evgenievich Nikonov

IPC: H10N70/00 ,  H10B63/00 ,  H10B99/00

Abstract: A two-terminal ferroelectric perovskite diode comprises a region of ferroelectric perovskite material positioned adjacent to a region of n-type doped perovskite semiconductor material. Asserting a positive voltage across the diode can cause the polarization of the ferroelectric perovskite material to be set in a first direction that causes the diode to be placed in a low resistance state due to the formation of an accumulation region in the perovskite semiconductor material at the ferroelectric perovskite-perovskite semiconductor boundary. Asserting a negative voltage across the diode can cause the polarization of the ferroelectric perovskite material to be set in a second direction that causes the diode to be placed in a high resistance state due to the formation of a depletion region in the perovskite semiconductor material at the ferroelectric perovskite-perovskite semiconductor material. These non-volatile low and high resistance states enable the diode to be used as a non-volatile memory element.

公开(公告)号：US11980037B2

公开(公告)日：2024-05-07

申请号：US16906217

申请日：2020-06-19

Applicant: Intel Corporation

Inventor： Nazila Haratipour ,  Shriram Shivaraman ,  Sou-Chi Chang ,  Jack T. Kavalieros ,  Uygar E. Avci ,  Chia-Ching Lin ,  Seung Hoon Sung ,  Ashish Verma Penumatcha ,  Ian A. Young ,  Devin R. Merrill ,  Matthew V. Metz ,  I-Cheng Tung

IPC: H10B53/30 ,  H01L21/768 ,  H01L23/522

CPC classification number: H10B53/30 ,  H01L21/7687 ,  H01L23/5226 ,  H01L21/76843

Abstract: Described herein are ferroelectric (FE) memory cells that include transistors having gate stacks separate from FE capacitors of these cells. An example memory cell may be implemented as an IC device that includes a support structure (e.g., a substrate) and a transistor provided over the support structure and including a gate stack. The IC device also includes a FE capacitor having a first capacitor electrode, a second capacitor electrode, and a capacitor insulator of a FE material between the first capacitor electrode and the second capacitor electrode, where the FE capacitor is separate from the gate stack (i.e., is not integrated within the gate stack and does not have any layers that are part of the gate stack). The IC device further includes an interconnect structure, configured to electrically couple the gate stack and the first capacitor electrode.

公开(公告)号：US20240006506A1

公开(公告)日：2024-01-04

申请号：US17856979

申请日：2022-07-02

Applicant: Intel Corporation

Inventor： Gilbert Dewey ,  Siddharth Chouksey ,  Nazila Haratipour ,  Christopher Jezewski ,  Jitendra Kumar Jha ,  Ilya V. Karpov ,  Jack T. Kavalieros ,  Arnab Sen Gupta ,  I-Cheng Tung ,  Nancy Zelick ,  Chi-Hing Choi ,  Dan S. Lavric

IPC: H01L29/45 ,  H01L29/417 ,  H01L29/423 ,  H01L29/775 ,  H01L29/78 ,  H01L27/088

CPC classification number: H01L29/458 ,  H01L29/41733 ,  H01L29/41791 ,  H01L29/41775 ,  H01L29/42392 ,  H01L29/775 ,  H01L29/7851 ,  H01L27/088 ,  H01L27/0886 ,  H01L29/401

Abstract: Contacts to n-type source/drain regions comprise a phosphide or arsenide metal compound layer. The phosphide or arsenide metal compound layers can aid in forming thermally stable low resistance contacts. A phosphide or arsenide metal compound layer is positioned between the source/drain region and the contact metal layer of the contact. A phosphide or arsenic metal compound layer can be used in contacts contacting n-type source/drain regions comprising phosphorous or arsenic as the primary dopant, respectively. The phosphide or arsenide metal compound layers prevent diffusion of phosphorous or arsenic from the source/drain region into the metal contact layer and dopant deactivation in the source/drain region due to annealing and other high-temperature processing steps that occur after contact formation. Phosphide and arsenide metal contact layers can also reduce the amount of silicide that forms in source/drain regions during processing by limiting the amount of contact metal that diffuses into source/drain regions.

公开(公告)号：US11742407B2

公开(公告)日：2023-08-29

申请号：US16700757

申请日：2019-12-02

Applicant: Intel Corporation

Inventor： Seung Hoon Sung ,  Ashish Verma Penumatcha ,  Sou-Chi Chang ,  Devin Merrill ,  I-Cheng Tung ,  Nazila Haratipour ,  Jack T. Kavalieros ,  Ian A. Young ,  Matthew V. Metz ,  Uygar E. Avci ,  Chia-Ching Lin ,  Owen Loh ,  Shriram Shivaraman ,  Eric Charles Mattson

IPC: H01L29/51 ,  H01L21/8234 ,  H01L27/088 ,  H01L29/423 ,  H01L29/66 ,  H01L29/78

CPC classification number: H01L29/512 ,  H01L21/823431 ,  H01L27/0886 ,  H01L29/42392 ,  H01L29/517 ,  H01L29/66795 ,  H01L29/7851

Abstract: A integrated circuit structure comprises a fin extending from a substrate. The fin comprises source and drain regions and a channel region between the source and drain regions. A multilayer high-k gate dielectric stack comprises at least a first high-k material and a second high-k material, the first high-k material extending conformally over the fin over the channel region, and the second high-k material conformal to the first high-k material, wherein either the first high-k material or the second high-k material has a modified material property different from the other high-k material, wherein the modified material property comprises at least one of ferroelectricity, crystalline phase, texturing, ordering orientation of the crystalline phase or texturing to a specific crystalline direction or plane, strain, surface roughness, and lattice constant and combinations thereof. A gate electrode ix over and on a topmost high-k material in the multilayer high-k gate dielectric stack. A selector element is above the metal layer.

公开(公告)号：US20230197728A1

公开(公告)日：2023-06-22

申请号：US17554791

申请日：2021-12-17

Applicant: Intel Corporation

Inventor： Nicole K. Thomas ,  Eric Mattson ,  Sudarat Lee ,  Sarah Atanasov ,  Christopher J. Jezewski ,  Charles Mokhtarzadeh ,  Thoe Michaelos ,  I-Cheng Tung ,  Charles C. Kuo ,  Scott B. Clendenning ,  Matthew V. Metz

IPC: H01L27/092 ,  H01L29/06 ,  H01L29/417 ,  H01L29/78

CPC classification number: H01L27/0924 ,  H01L29/0669 ,  H01L29/41791 ,  H01L29/785 ,  H01L2029/7858

Abstract: An integrated circuit includes a lower and upper device portions including bodies of semiconductor material extending horizontally between first source and drain regions in a spaced-apart vertical stack. A first gate structure is around a body in the lower device portion and includes a first gate electrode and a first gate dielectric. A second gate structure is around a body in the upper device portion and includes a second gate electrode and a second gate dielectric, where the first gate dielectric is compositionally distinct from the second gate dielectric. In some embodiments, a dipole species has a first concentration in the first gate dielectric and a different second concentration in the second gate dielectric. A method of fabrication is also disclosed.

公开(公告)号：US20220181433A1

公开(公告)日：2022-06-09

申请号：US17116315

申请日：2020-12-09

Applicant: Intel Corporation

Inventor： Sou-Chi Chang ,  Chia-Ching Lin ,  Kaan Oguz ,  I-Cheng Tung ,  Uygar E. Avci ,  Matthew V. Metz ,  Ashish Verma Penumatcha ,  Ian A. Young ,  Arnab Sen Gupta

IPC: H01L49/02

Abstract: Disclosed herein are capacitors including built-in electric fields, as well as related devices and assemblies. In some embodiments, a capacitor may include a top electrode region, a bottom electrode region, and a dielectric region between and in contact with the top electrode region and the bottom electrode region, wherein the dielectric region includes a perovskite material, and the top electrode region has a different material structure than the bottom electrode region.

公开(公告)号：US20240429301A1

公开(公告)日：2024-12-26

申请号：US18341467

申请日：2023-06-26

Applicant: Intel Corporation

Inventor： Rachel A. Steinhardt ,  Dmitri Evgenievich Nikonov ,  Kevin P. O'Brien ,  John J. Plombon ,  Tristan A. Tronic ,  Ian Alexander Young ,  Matthew V. Metz ,  Marko Radosavljevic ,  Carly Rogan ,  Brandon Holybee ,  Raseong Kim ,  Punyashloka Debashis ,  Dominique A. Adams ,  I-Cheng Tung ,  Arnab Sen Gupta ,  Gauri Auluck ,  Scott B. Clendenning ,  Pratyush P. Buragohain

IPC: H01L29/423 ,  H01L29/06 ,  H01L29/66 ,  H01L29/786

Abstract: A transistor device may be formed with a doped perovskite material as a channel region. The doped perovskite material may be formed via an epitaxial growth process from a seed layer, and the channel regions of the transistor device may be formed from lateral overgrowth from the epitaxial growth process.

公开(公告)号：US20240105508A1

公开(公告)日：2024-03-28

申请号：US17935647

申请日：2022-09-27

Applicant: Intel Corporation

Inventor： Jitendra Kumar Jha ,  Justin Mueller ,  Nazila Haratipour ,  Gilbert W. Dewey ,  Chi-Hing Choi ,  Jack T. Kavalieros ,  Siddharth Chouksey ,  Nancy Zelick ,  Jean-Philippe Turmaud ,  I-Cheng Tung ,  Blake Bluestein

IPC: H01L21/768 ,  H01L29/49

CPC classification number: H01L21/76856 ,  H01L21/76837 ,  H01L21/76877 ,  H01L29/4908

Abstract: Disclosed herein are integrated circuit (IC) devices with contacts using nitridized molybdenum. For example, a contact arrangement for an IC device may include a semiconductor material and a contact extending into a portion of the semiconductor material. The contact may include molybdenum. The molybdenum may be in a first layer and a second layer, where the second layer may further include nitrogen. The first layer may have a thickness between about 5 nanometers and 16 nanometers, and the second layer may have a thickness between about 0.5 nanometers to 2.5 nanometers. The contact may further include a fill material (e.g., an electrically conductive material) and the second layer may be in contact with the fill material. The molybdenum may have a low resistance, and thus may improve the electrical performance of the contact. The nitridized molybdenum may prevent oxidation during the fabrication of the contact.

公开(公告)号：US20240006533A1

公开(公告)日：2024-01-04

申请号：US17856982

申请日：2022-07-02

Applicant: Intel Corporation

Inventor： Gilbert Dewey ,  Siddharth Chouksey ,  Nazila Haratipour ,  Christopher Jezewski ,  Jitendra Kumar Jha ,  Ilya V. Karpov ,  Matthew V. Metz ,  Arnab Sen Gupta ,  I-Cheng Tung ,  Nancy Zelick ,  Chi-Hing Choi ,  Dan S. Lavric

IPC: H01L29/78 ,  H01L29/167

CPC classification number: H01L29/785 ,  H01L29/167

Abstract: Contacts to p-type source/drain regions comprise a boride, indium, or gallium metal compound layer. The boride, indium, or gallium metal compound layers can aid in forming thermally stable low resistance contacts. A boride, indium, or gallium metal compound layer is positioned between the source/drain region and the contact metal layer. A boride, indium, or gallium metal compound layer can be used in contacts contacting p-type source/drain regions comprising boron, indium, or gallium as the primary dopant, respectively. The boride, indium, or gallium metal compound layers prevent diffusion of boron, indium, or gallium from the source/drain region into the metal contact layer and dopant deactivation in the source/drain region due to annealing and other high-temperature processing steps that occur after contact formation. Boride, indium, or gallium metal contact layers can also reduce the amount of silicide that forms in source/drain regions during processing by limiting contact metal diffusion into source/drain regions.

公开(公告)号：US11316027B2

公开(公告)日：2022-04-26

申请号：US16833375

申请日：2020-03-27

Applicant: Intel Corporation

Inventor： Sou-Chi Chang ,  Chia-Ching Lin ,  Nazila Haratipour ,  Tanay Gosavi ,  I-Cheng Tung ,  Seung Hoon Sung ,  Ian Young ,  Jack Kavalieros ,  Uygar Avci ,  Ashish Verma Penumatcha

IPC: H01L21/02 ,  H01L29/51 ,  H01L29/24 ,  H01L29/92

Abstract: A capacitor device includes a first electrode having a first metal alloy or a metal oxide, a relaxor ferroelectric layer adjacent to the first electrode, where the ferroelectric layer includes oxygen and two or more of lead, barium, manganese, zirconium, titanium, iron, bismuth, strontium, neodymium, potassium, or niobium and a second electrode coupled with the relaxor ferroelectric layer, where the second electrode includes a second metal alloy or a second metal oxide.