Polymer Characterization

Below is an outline of how AFM is useful in the study of polymers. Customers worldwide use AFM to study polymer materials; to read some highlighted work from AFMWorkshop customers, click here.

Atomic Force Microscopy for Polymer Characterization

PolyLinkSm Click for highlighted references

AFM is a powerful method for imaging polymers, polymer blends, and polymer composites with nanometer lateral resolution. For polymer applications, the AFM now resides alongside optical microscopy and electron microscopy (SEM – scanning electron microscopy and TEM – transmission electron microscopy) as essential tools for characterization. However, atomic force microscopy provides specific advantages over other microscopies because it provides mechanical interaction between the tip and sample. This mechanical source contrast often provides contrast in situations where electron or photon based microscopies struggle or even fail.

The predominant mode for imaging polymers is phase imaging, which is associated with vibrating mode. In phase imaging, the AFM provides excellent contrast, sensitivity, and discrimination based on various material properties of the polymers.

Key Benefits of AFM

  • Suitable for polymers, polymer blends, polymer composites
  • Used to establish structure-property relationships
  • Lateral resolution is ~10nm
  • Information obtained includes morphology, dispersion, domain size, internal structure
  • Sample preparation – cryo-microtoming - often needed to remove skin effects from molding, other processing methods
  • Phase imaging is excellent method for contrast where contrast is based on material/mechanical properties such as stiffness and adhesion
  • No post processing needed

Phase Imaging

The predominant mode for imaging polymers is phase imaging, which is associated with vibrating mode. In phase imaging, the AFM provides excellent contrast, sensitivity, and discrimination based on various material properties of the polymers including stiffness and adhesion.

Phase imaging is a channel collected in vibrating mode and requires no post processing. Phase imaging collects the information on the phase shift (Φ) induced in the cantilever vibration motion. The cantilever is driven at a resonant frequency and interacts with the sample at a given oscillation amplitude set by the user. The phase shift (Φ) is then induced by interacting with the sample and is mapped as a channel simultaneously with the topography channel while the tip raster scans over the surface. A variety of material properties can affect the tip-sample interaction and induce a phase shift including stiffness, adhesion, viscoelasticity, and capillary forces.

Sample Preparation

AFM imaging requires flat surfaces for imaging. However, polymer samples may require additional sample preparation beyond this. If there is a sample with a "skin", or a sample that has been processed and only the inner bulk material needs to be imaged, it will need to be cryo-microtomed for AFM imaging. Cryo-microtoming is a process by which a very smooth surface is cut and prepared at cold temperatures on a cryomicrotome. Many samples such as thin films or spin-coated films can be imaged as is without this preparation.

Aside from cryo-microtoming, no further sample preparation is required – i.e. no staining is required as is the case for electron microscopy based methods such as scanning electron microscopy (SEM) and transmission electron microscopy (TEM).

Oriented Fibers

AFM topographic image of oriented polypropylene 10 µm x 10 µm

10µm x 10µm topographic image of an oriented polypropylene showing a network of fibers.

 

Polymer Blend

AFM phase image 5 µm x 5 µm thermoplastics & rubbers A phase image over a 5µm x 5µm area of a blend of thermoplastics and rubbers is shown.

The phase imaging differentiates components. The thermoplastic matrix is in the background with brown/orange contrast. The bright white rubber domains are clearly differentiated from the matrix. The rubbers appear in a variety of diameters from a few hundred nm to several microns. Note the diverse shapes of the rubber domains with some inclusions being more round while others are more oval and even irregularly shaped. Additionally, inside the rubbers are small orange type inclusions, further showing the material structure in this sample.

 

Block Copolymer

The extraordinary contrast provided by phase imaging is demonstrated nicely in block copolymer samples as well.

1 µm x 1 µm phase image of SEBS 1 µm x 1 µm topography image of SEBS

Below is a 1µm x 1µm phase image of SEBS (styrene/ethylene/butylene polymer). Compare the phase image on the left with the corresponding topography image on the right. Although the existence of the two domains is observed in the topography, the different blocks are more clearly differentiated in the phase image on the left, enabling a clearer understanding of the morphology, dispersion, and size of the various block domains.

High resolution 500 nm x 500 nm phase image of SEBS

High resolution 500nm x 500 nm phase image below, the smallest domains of ~10 nm in diameter are easily visible.

 

Our AFM Users Recent Polymer Reference Publications

AFMWorkshop's TT-AFM provides all the major Atomic Force Microscopy (AFM) modes needed to characterize polymers, including vibrating mode for topography/morphology and force distance curves for mechanical properties such as adhesion and stiffness. A number of researchers have published their work on polymers using the TT-AFM, characterizing important properties such as size, shape, and dispersion. Click here  to read our highlights of a few recent articles where researchers are utilizing the TT-AFM for work on polymers in biomedical and electronic device applications.

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