Nanoscale characterisation and imaging of partially amorphous materials using local thermomechanical analysis and heated tip AFM

Ljiljana Harding, William P. King, Xuan Dai, Duncan Q. M. Craig, Mike Reading

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    47 Citations (Scopus)

    Abstract

    The purpose is to investigate the use of thermal nanoprobes in thermomechanical and heated tip pulsed force modes as novel means of discriminating between amorphous and crystalline material on a sub-micron scale. Indometacin powder was compressed and partially converted into amorphous material. Thermal nanoprobes were used to perform localised thermomechanical analysis (L-TMA) and heated tip pulsed force mode imaging as a function of temperature. L-TMA with submicron lateral spatial resolution and sub-100 nm depth penetration was achieved, allowing us to thermomechanically discriminate between amorphous and crystalline material at a nanoscale for the first time. The amorphous and crystalline regions were imaged as a function of temperature using heated tip pulsed force AFM and a resolution of circa 50 nm was achieved. We are also able to observe tip-induced recrystallisation of the amorphous material. The study demonstrates that we are able to discriminate and characterise amorphous and crystalline regions at a submicron scale of scrutiny. We have demonstrated the utility of two methods, L-TMA and heated tip pulsed force mode AFM, that allow us to respectively characterise and image adjacent amorphous and crystalline regions at a nanoscale. The study has demonstrated that thermal nanoprobes represent a novel method of characterising and imaging partially amorphous materials.
    Original languageEnglish
    Pages (from-to)2048-2054
    Number of pages7
    JournalPharmaceutical Research
    Volume24
    Issue number11
    DOIs
    Publication statusPublished - 2007

    Keywords

    • ATOMIC-FORCE MICROSCOPY
    • STATE
    • VISUALIZATION
    • POLYMERS
    • glass transition
    • atomic force microscopy
    • microthermal analysis
    • indometacin
    • LACTOSE
    • CRYSTALLIZATION
    • STABILITY
    • THERMAL-ANALYSIS
    • amorphous

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