Tannins are eco-friendly, bio-sourced, natural, and highly reactive polyphenols. In the past decades, the understanding of their versatile properties has grown substantially alongside a continuously broadening of the tannins’ application scope. In particular, recently, tannins have been increasingly investigated for their interaction with other species in order to obtain tannin-based hybrid systems that feature advanced and/or novel properties. Furthermore, in virtue of the tannins’ chemistry and their high reactivity, they either physicochemically or physically interact with a wide variety of different compounds, including metals and ceramics, as well as a number of organic species. Such hybrid or hybrid-like systems allow the preparation of various advanced nanomaterials, featuring improved performances compared to the current ones. Consequently, these diverse-shaped materials have potential use in wastewater treatment or catalysis, as well as in some novel fields such as UV-shielding, functional food packaging, and biomedicine. Since these kinds of tannin-based hybrids represent an emerging field, thus far no comprehensive overview concerning their potential as functional chemical building blocks is available. Hence, this review aims to provide a structured summary of the current state of research regarding tannin-based hybrids, detailed findings on the chemical mechanisms as well as their fields of application.
Studies
on the spin-state switching characteristics of surface-bound
thin films of spin-crossover (SCO) complexes are of interest to harness
the device utility of the SCO complexes. Molecule–substrate
interactions govern the SCO of surface-bound films in direct contact
with the underlying substrates. In this study, we elucidate the role
of molecule–substrate interactions on the thermal- and light-induced
spin-state switching characteristics of a functional SCO-complex[Fe(H2B(pz)2)2COOC12H25-bipy] (pz = pyrazole, C12-bpy = dodecyl[2,2′-bipyridine]-5-carboxylate)
deposited at a submonolayer coverage on a highly oriented pyrolytic
graphite (HOPG) substrate. A spin-state coexistence of 42% low-spin
(LS) and 58% high-spin (HS) is observed for the 0.4 ML deposit of
the complex at 40 K, in contrast to the complete spin-state switching
observed in the bulk and in SiO
x
-bound
10 nm thick films. Cooling the sample to 10 K results in a decrease
of the LS fraction to 36%, attributed to soft-X-ray-induced excited
spin-state trapping (SOXIESST). Illumination of the sample with a
green light (λ = 520 nm) at 10 K caused the LS-to-HS switching
of the remaining (36%) LS complexes, by a process termed light-induced
excited spin-state trapping (LIESST). The mixed spin-state in the
submonolayer coverage of [Fe(H2B(pz)2)2COOC12H25-bipy] highlights the role of molecule–HOPG
substrate interactions in tuning the thermal SCO characteristics of
the complex. The 100% HS state obtained after light irradiation indicates
the occurrence of efficient on-surface light-induced spin switching,
encouraging the development of light-addressable molecular devices
based on SCO complexes.
In this study, we present a detailed comparison between a conventional supercritical drying process and an evaporative drying technique for hierarchically organized porous silica gel monoliths. These gels are based on a model system synthesized by the aqueous sol–gel processing of an ethylene-glycol-modified silane, resulting in a cellular, macroporous, strut-based network comprising anisotropic, periodically arranged mesopores formed by microporous amorphous silica. The effect of the two drying procedures on the pore properties (specific surface area, pore volume, and pore widths) and on the shrinkage of the monolith is evaluated through a comprehensive characterization by using nitrogen physisorption, electron microscopy, and small-angle X-ray scattering. It can clearly be demonstrated that for the hierarchically organized porous solids, the evaporative drying procedure can compete without the need for surface modification with the commonly applied supercritical drying in terms of the material and textural properties, such as specific surface area and pore volume. The thus obtained materials deliver a high specific surface area and exhibit overall comparable or even improved pore characteristics to monoliths prepared by supercritical drying. Additionally, the pore properties can be tailored to some extent by adjusting the drying conditions, such as temperature.
The physicochemical properties of rare-earth zirconates can be tuned by the rational modification of their structures and phase compositions. In the present work, La 3+ -, Nd 3+ -, Gd 3+ -, and Dy 3+ -zirconate nanostructured materials were prepared by different synthetic protocols, leading to powders, xerogels, and, for the first time, monolithic aerogels. Powders were synthesized by the co-precipitation method, while xerogels and aerogels were synthesized by the sol−gel technique, followed by ambient and supercritical drying, respectively. Their microstructures, thermogravimetric profiles, textural properties, and crystallographic structures are reported. The co-precipitation method led to dense powders (S BET < 1 m 2 g −1 ), while the sol−gel technique resulted in large surface area xerogels (S BET = 144 m 2 g −1 ) and aerogels (S BET = 168 m 2 g −1 ). In addition, the incorporation of lanthanide ions into the zirconia lattice altered the crystal structures of the powders, xerogels, and aerogels. Single-phase pyrochlores were obtained for La 2 Zr 2 O 7 and Nd 2 Zr 2 O 7 powders and xerogels, while defect fluorite structures formed in the case of Gd 2 Zr 2 O 7 and Dy 2 Zr 2 O 7 . All aerogels contain a mixture of cubic and tetragonal ZrO 2 phases. Thus, a direct effect is shown between the drying conditions and the resulting crystalline phases of the nanostructured rare-earth zirconates.
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