Low Temperature Processing of Dielectric Thin Films Chris Bratten Rose-Hulman Institute of Technology Mechanical / Biomedical Engineering Advising Professors: Hugh Hillhouse and Elliott Slamovich

Introduction

Barium titanate (BaTiO₃) is a piezoelectric material with a perovskite crystal structure. This material is showing much promise as a waveguide and optical switch with electro-optic response figures 10 to 100 times that of currently used materials. My research this summer focused on the hydrothermal synthesis of thin films of barium titanate.

Project Objectives

• Produce thin films of barium titanate using the hydrothermal process
• Use x-ray diffraction to verify formation of BaTiO₃
• Determine the dielectric properties using the microelectronics test bench

Experimental Approach

• Cut standard glass slides in half to use as a substrate
• Cleaned substrates in TCA, acetone, then methanol in a sonic bath
• Deposited a thin film of titanium onto the substrates by evaporation
• Made 1.0M and 0.5M solutions of Ba(OH)₂ and 1.0M solutions of BaCl₂ + NaOH
• Placed samples in solution then backfilled containers with Ar gas
• Heated in ovens for at least 24 hours at temperatures ranging from 65 to 90^oC
• Pulled out of solution in a nitrogen atmosphere glove box and rinsed with methanol to avoid the formation of barium carbonate
• Used X-ray diffraction to determine how well the films formed barium Titanate
• Best samples had titanium electrodes deposited using a TEM grid in the evaporator and were tested for capacitance and dielectric values

Research Findings

• Ba(OH)₂ solution produced consistently better films than the BaCl₂ + NaOH solution
• Higher temperatures produced better films than lower temperatures

X-Ray diffraction pattern of a hydrothermal BaTiO₃ thin film.

Capacitance of the BaTiO₃ film as a function of position.

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Final Research Presentation