Ferroelectrics: Historical Introduction
Ferroelectricity
Ferroelectricity
Ferroelectric materials
Early years (1920-1930)
Discrete elements (1940-1960)
Hybrid microelectonics (1970-1990)
Integrated circuits (since 2000)
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Category: physicsphysics
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Ferroelectrics: historical introduction

1. Ferroelectrics: Historical Introduction

by Fedor Tikhonenko

2. Ferroelectricity

= reversible spontaneous polarization
Asymmetric crystal structure is required!

3. Ferroelectricity

= reversible spontaneous polarization

4. Ferroelectric materials

• Typical ferroelectrics are complicated ceramic
compounds of transition metals ( titanates,
niobates, tantalates, etc.)
• NO IRON!
• All FE materials are also pyroelectrics and
piezoelectrics

5. Early years (1920-1930)

• FE effect first discovered in Rochelle salt by
Valasek (1920)
• Materials: Single crystalls (Rochelle salt, ADP,
KDP)
• Methods: Solution growth
• Applications: Photo pickup

6. Discrete elements (1940-1960)

• Materials: ceramics (BT, PZT, LT, SBN, etc.)
• Methods: casting, pressing, evaporation,
sputtering
• Applications: Hi-k Caps, acoustic tranducers,
filters, heat detectors
• 1952: PZT was synthesized in Tokyo Institute
of Technology

7. Hybrid microelectonics (1970-1990)

• Perovskite structure
materials (Perovskii,
1895)
• Materials: thin films (PZT, PZLT, PLT, LN, SBN)
• Methods: sol-gel, LPE, MBE, CVD, MOCVD,
PECVD
• Applications: MEMS, NVM, IR sensors

8. Integrated circuits (since 2000)


Materials: ultra thin films (HfO2, ZrO2)
Methods: CVD, MOCVD, ALD
Applications: NVM, NN, IR starring arrays
Main problems: phase transitions, FE
induced/suppressed by stress and strain and
influenced by surface states and defects.
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