Understanding the Electrical Behavior of Pyrolyzed Three‐Dimensional‐Printed Microdevices

Tyler, Joshua B.; Smith, Gabriel L.; Leff, Asher C.; Wilson, Peter M.; Cumings, John; Lazarus, Nathan

doi:10.1002/adem.202001027

Cited by 5 publications

(2 citation statements)

References 31 publications

(38 reference statements)

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“…The EELS results are consistent with the literature, that pyrolytic carbon from IP‐Dip below 700 °C is predominantly amorphous. [ 43 ]…”

Section: Resultsmentioning

confidence: 99%

“…The EELS results are consistent with the literature, that pyrolytic carbon from IP-Dip below 700 °C is predominantly amorphous. [43] Figure 7b shows spectral images of carbon and oxygen (the main elemental constituents of IP-Dip) from different pyrolysis conditions. To obtain the elemental mappings, inelastically scattered electrons are collected with a spatial resolution of 2-6 nm over the range of ionization energies for the K shells of the desired elements.…”

Section: Cross-sectional Tem Study Of the Pyrolyzed Microstrutsmentioning

confidence: 99%

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In Situ Pyrolysis of 3D Printed Building Blocks for Functional Nanoscale Metamaterials

Sun

Dölle

Kurpiers

et al. 2023

Adv Funct Materials

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This study presents a novel approach for investigating the shrinkage dynamics of 3D‐printed nanoarchitectures during isothermal pyrolysis, utilizing in situ electron microscopy. For the first time, the temporal evolution of 3D structures is tracked continuously until a quasi‐stationary state is reached. By subjecting the 3D objects to different temperatures and atmospheric conditions, significant changes in the resulting kinetic parameters and morphological textures of the 3D objects are observed, particularly those possessing varying surface‐to‐volume ratios. Its results reveal that the effective activation energy required for pyrolysis‐induced morphological shrinkage is approximately four times larger under vacuum conditions than in a nitrogen atmosphere (2.6 eV vs. 0.5–0.9 eV, respectively). Additionally, a subtle enrichment of oxygen on the surfaces of the structures for pyrolysis in nitrogen is found through a postmortem electron energy loss spectroscopy study, differentiating the vacuum pyrolysis. These findings are examined in the context of the underlying process parameters, and a mechanistic model is proposed. As a result, understanding and controlling pyrolysis in 3D structures of different geometrical dimensions not only enables precise modification of shrinkage and the creation of tensegrity structures, but also promotes pyrolytic carbon development with custom architectures and properties, especially in the field of carbon micro‐ and nano‐electromechanical systems.

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“…The EELS results are consistent with the literature, that pyrolytic carbon from IP‐Dip below 700 °C is predominantly amorphous. [ 43 ]…”

Section: Resultsmentioning

confidence: 99%

Section: Cross-sectional Tem Study Of the Pyrolyzed Microstrutsmentioning

confidence: 99%