Fabrication and characterization of ferro- and piezoelectric multilayer devices for high frequency applications /

Riekkinen, Tommi.

January 1900

Thesis (doctoral)--Helsinki University of Technology, 2009. / Includes bibliographical references. Also available on the World Wide Web.

Nonlinear constitutive behavior and fracture of ferroelectric materials and structures

Chen, Wei

08 1900

No description available.

Ferroelectric thin films

Ferroelectric devices Materials

Ferroelectric crystals

Electronic ceramics

Ferromagnetic and multiferroic thin films aimed towards optoelectronic and spintronic applications

Zaidi, Tahir

24 May 2010

This work targeted the growth of gadolinium (Gd)-doped gallium nitride (GaN) thin films (Ga₁₋ₓGdₓN) by metal organic chemical vapor deposition (MOCVD). Characterization and evaluation of these Ga₁₋ₓGdₓN thin films for application in spintronics/optoelectronics devices also formed part of this work. This work presents: (1) the first report of stable, reproducible n- and p-type Ga₁₋ₓGdₓN thin films by MOCVD; (2) the first Ga₁₋ₓGdₓN p-n diode structure; and (3) the first report of a room temperature spin-polarized LED using a Ga₁₋ₓGdₓN spin injection layer. The Ga₁₋ₓGdₓN thin films grown in this work were electrically conductive, and co-doping them with Silicon (Si) or Magnesium (Mg) resulted in n-type and p-type materials, respectively. All the materials and structures grown in this work, including the Ga₁₋ₓGdₓN-based p-n diode and spin polarized LED, were characterized for their structural, optical, electrical and magnetic properties. The spin-polarized LED gave spin polarization ratio of 22% and systematic variation of this ratio at room temperature with external magnetic field was observed.

Ferromagnetic

Thin films

Gadolinium

GaN

Spintronic

Spin-LED

LED

Ferroelectric thin films

Ferroelectric devices

Optoelectronic devices

Spintronics

Gadolinium

Gallium nitride

Thermal stability of defects in strontium titante [i.e., titanate] susbtrates for multiferroic materials

Jeddy, Shehnaz.

January 2008

Thesis (M.S.)--University of Alabama at Birmingham, 2008. / Description based on contents viewed May 30, 2008; title from title screen. Includes bibliographical references (p. 50-51).

Prospects for energy-efficient edge computing with integrated HfO₂-based ferroelectric devices

O'Connor, Ian, Cantan, Mayeul, Marchand, Cédric, Vilquin, Bertrand, Slesazeck, Stefan, Breyer, Evelyn T., Mulaosmanovic, Halid, Mikolajick, Thomas, Giraud, Bastien, Noël, Jean-Philippe, Ionescu, Adrian, Igor, Igor

08 December 2021

Edge computing requires highly energy efficient microprocessor units with embedded non-volatile memories to process data at IoT sensor nodes. Ferroelectric non-volatile memory devices are fast, low power and high endurance, and could greatly enhance energy-efficiency and allow flexibility for finer grain logic and memory. This paper will describe the basics of ferroelectric devices for both hysteretic (non-volatile memory) and negative capacitance (steep slope switch) devices, and then project how these can be used in low-power logic cell architectures and fine-grain logic-in-memory (LiM) circuits.

info:eu-repo/classification/ddc/621

ddc:621

Demonstration and Endurance Improvement of p-channel Hafnia-based Ferroelectric Field Effect Transistors

Winkler, Felix, Pešić, Milan, Richter, Claudia, Hoffmann, Michael, Mikolajick, Michael, Bartha, Johann W.

25 January 2022

So far, only CMOS compatible and scalable hafnia-zirconia (HZO) based ferroelectric (FE) n-FeFETs have been reported. To enable the full ferroelectric hierarchy [1] both p- and n-type devices should be available. Here we report a p-FeFET with a large memory window (MW) for the first time. Moreover, we propose different integration schemes comprising structures with and without internal gate resulting in metal-FE-insulator-Si (MFIS) and metal-FE-metal-insulator-Si (MFMIS) devices which could be used to tackle the problem of interface (IF) degradation and possibly decrease the power consumption of the devices.

info:eu-repo/classification/ddc/621.3

ddc:621.3