Nanomechanical testing of freestanding polymer films: in situ tensile testing and Tg measurement

Velez, Nathan R.; Allen, Frances; Jones, Mary Ann; Donohue, Jenn; Li, Wei; Pister, Kristofer S. J.; Govindjee, Sanjay; Meyers, Gregory F.; Minor, Andrew M.

doi:10.1557/s43578-021-00163-z

Cited by 8 publications

(8 citation statements)

References 19 publications

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“…Particularly, Wang et al [ 32 ], using diglycidyl ether of bisphenol A (DGEBA) and piperidine (cyclic amine), equivalent to the one studied here, proposed the core-shell model, stating that the epoxy specimens could be regarded as a ‘composite’ material, consisting of an epoxy core surrounded by an FIB peening-induced stiff layer. Similar stiffening effects of the surface was reported by Nathan for a PMMA film in tension [ 31 ] and by Schamel for epoxy resin pillars in compression [ 39 ]; the three studies used Ga + FIB milling with an acceleration voltage of 30 kV.…”

Section: Resultssupporting

confidence: 54%

“…Only few studies have used FIB to fabricate small-scale polymeric specimens for mechanical testing, to study the effects of size on mechanical behavior [ 25 , 31 , 32 , 33 ]. Moon demonstrated patterns of wrinkled stiff skin on a polymeric substrate upon exposure to FIB [ 33 ].…”

Section: Introductionmentioning

confidence: 99%

“…Wang performed micro compression experiment on FIB-milled epoxy micropillars and concluded that a non-negligible stiff surface skin is created, and estimated a Young’s Modulus of 30 GPa and a thickness of 30 nm [ 32 ]. Nathan demonstrated a tensile test of polymethylmethacrylate (PMMA) under an optical microscope and in situ TEM [ 31 ]. They highlighted the sensitivity of polymeric materials to the TEM electron beam and to the radiation effects by the FIB.…”

Section: Introductionmentioning

confidence: 99%

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Mechanical and Compositional Implications of Gallium Ion Milling on Epoxy Resin

et al. 2021

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Focused Ion Beam (FIB) is one of the most common methods for nanodevice fabrication. However, its implications on mechanical properties of polymers have only been speculated. In the current study, we demonstrated flexural bending of FIB-milled epoxy nanobeam, examined in situ under a transmission electron microscope (TEM). Controllable displacement was applied, while real-time TEM videos were gathered to produce morphological data. EDS and EELS were used to characterize the compositions of the resultant structure, and a computational model was used, together with the quantitative results of the in situ bending, to mechanically characterize the effect of Ga+ ions irradiation. The damaged layer was measured at 30 nm, with high content of gallium (40%). Examination of the fracture revealed crack propagation within the elastic region and rapid crack growth up to fracture, attesting to enhanced brittleness. Importantly, the nanoscale epoxy exhibited a robust increase in flexural strength, associated with chemical tempering and ion-induced peening effects, stiffening the outer surface. Young’s modulus of the stiffened layer was calculated via the finite element analysis (FEA) simulation, according to the measurement of 30 nm thickness in the STEM and resulted in a modulus range of 30–100 GPa. The current findings, now established in direct measurements, pave the way to improved applications of polymers in nanoscale devices to include soft materials, such as polymer-based composites and biological samples.

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Section: Resultssupporting

confidence: 54%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mechanical and Compositional Implications of Gallium Ion Milling on Epoxy Resin

et al. 2021

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“…As evidenced by the high number of related contributions, the use of the FIB has become essential in the field of nanomechanical testing [17,18,[20][21][22]. This has inevitably raised concerns about possible measurement artifacts due to ion damage incurred during the specimen preparation [20,[23][24][25]. While detrimental effects can be ruled out for some applications [20], in other cases, workarounds are actively being developed to minimize [24] or to completely avoid [23] exposure of the samples to highly energetic ion beams.…”

Section: Focused Ion Beam (Fib)-based Nanomechanical Testingmentioning

confidence: 99%

“…Their development has been a dominant trend in nanomechanical research throughout the past decade, with their application seemingly only being limited by the high costs associated with the techniques. This trend is continued in the focus issue, which features applications both inside scanning electron microscopes (SEM) [17,18,21,22] and transmission electron microscopes (TEM) [23,24].…”

Section: In-situ Investigationsmentioning

confidence: 99%

Current trends in nanomechanical testing research

Merle

Maier–Kiener

Rupert

et al. 2021

Journal of Materials Research

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In Situ Fabrication, Manipulation, and Mechanical Characterization of Free‐Standing Silica Thin Films Using Focused Ion Beam Scanning Electron Microscopy

Soleimani

Maddala

Wismans

et al. 2022

Adv Materials Inter

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are different from their bulk counterparts. [10][11][12][13] However, experimental determination of the mechanical properties of micro and nanoscale thin films, including silica, remains an extremely challenging task. [10,14] Amongst available approaches, nanoindentation is most commonly used for measuring small scale silica thin films. [15][16][17] It requires simple specimen preparation and is comparatively easy to perform while the Young's modulus and hardness of the thin film materials are measurable. [18,19] Nevertheless, several limitations still exist related to the effect of the substrate, particularly relevant for films thinner than a micrometer, such as an indentation maximum of only about 10% of the depth, as well as, the lack of in situ observation during deformation, which all restrict general applicability of conventional nanoindentation. [20][21][22] Taken together, above limitations point to the need for a more versatile approach that eliminates substrate effects, that is, by realizing free-standing silica films/beams in the appropriate respective length scales. Subsequently, performing mechanical testing via indentation in real-time with high resolution force and displacement information becoming available would enable the monitoring of the specimen deformation behavior and concurrent phenomena in great detail.Currently available top down procedures for fabricating micro and nano-objects with well-defined patterns and structure, [23,24] may be employed to obtain free standing silica films Determination of mechanical properties of (silica) thin films is important for the development of new applications. However, a versatile approach for smallscale sample fabrication and in situ mechanical testing of these materials is currently lacking which can overcome the existing difficulties in conventional testing approaches. Here, it is shown that by combining focused ion beam scanning electron microscopy (FIB-SEM) with micromanipulators freestanding silica beams of the desired dimensions can be fabricated. Using in situ bending tests on such beams inside the SEM and finite element method simulations, the Young's modulus of thin-film silica and the effects of gallium ion beam radiation on Young's modulus are determined. Furthermore, the effects of controlled relative humidity on the mechanical behavior of silica beams are investigated. The demonstrated FIB-SEM approach can be extended to other materials and preparation conditions to measure, model, and optimize mechanical properties of thin films for a wide range of (coating) applications.

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Nanomechanical testing of freestanding polymer films: in situ tensile testing and Tg measurement

Cited by 8 publications

References 19 publications

Mechanical and Compositional Implications of Gallium Ion Milling on Epoxy Resin

Mechanical and Compositional Implications of Gallium Ion Milling on Epoxy Resin

Current trends in nanomechanical testing research

In Situ Fabrication, Manipulation, and Mechanical Characterization of Free‐Standing Silica Thin Films Using Focused Ion Beam Scanning Electron Microscopy

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