posted on 2019-01-22, 00:00authored byChristian Balzer, Anna M. Waag, Florian Putz, Nicola Huesing, Oskar Paris, Gennady Y. Gor, Alexander V. Neimark, Gudrun Reichenauer
Mechanical
properties of hierarchically structured nanoporous materials
are determined by the solid phase stiffness and the pore network morphology.
We analyze the mechanical stiffness of hierarchically structured silica
monoliths synthesized via a sol–gel process, which possess
a macroporous scaffold built of interconnected struts with hexagonally
ordered
cylindrical mesopores. We consider samples with and without microporosity
within the mesopore walls and analyze them on the macroscopic level
as well as on the microscopic level of the mesopores. Untreated as-prepared
samples still containing some organic components and the respective
calcined and sintered counterparts of varying microporosity are investigated.
To determine Young’s moduli on the level of the macroscopic
monoliths, we apply ultrasonic run time measurements, while Young’s
moduli of the mesopore walls are obtained by analysis of the in situ
strain isotherms during N2 adsorption at 77 K. For the
latter, we extended our previously reported theoretical approach for
this type of materials by incorporating the micropore effects, which
are clearly not negligible in the calcined and most of the sintered
samples. The comparison of the macro- and microscopic Young’s
moduli reveals that both properties follow essentially the same trends,
that is, calcination and sintering increase the mechanical stiffness
on both levels. Consequently, stiffening of the monolithic samples
can be primarily attributed to stiffening of the backbone material
which is consistent with the fact that the morphology on the mesopore
level is mainly preserved with the post-treatments applied.