| Literature DB >> 26314784 |
Thomas D Bennett1, Jin-Chong Tan2, Yuanzheng Yue3,4, Emma Baxter1, Caterina Ducati1, Nick J Terrill5, Hamish H-M Yeung6, Zhongfu Zhou7, Wenlin Chen7, Sebastian Henke1,8, Anthony K Cheetham1, G Neville Greaves1,4,7.
Abstract
Hybrid glasses connect the emerging field ofEntities:
Year: 2015 PMID: 26314784 PMCID: PMC4560802 DOI: 10.1038/ncomms9079
Source DB: PubMed Journal: Nat Commun ISSN: 2041-1723 Impact factor: 14.919
Figure 1Phase transitions of ZIF-4 on heating.
(a) Highlighting the rings and imidazolate linkages in zeolitic topologies, in the ordered structure of crystalline ZIF-4 (left) and ZIF-8 (center), and the disordered HDA phase (right) obtained by Molecular Dynamics modelling (Supplementary Methods). Zn, orange; N, blue; C, green; and H, grey. (b) Thermogravimetric analysis and Cp plots for ZIF-4 and ZIF-8, showing, for the former (inset), exothermic collapse to the LDA phase (1) which is closely followed by (2) endothermic formation of the HDA phase, and (3) recrystallization (exothermic). Endothermic melting (4) then follows before thermal degradation. (c) X-ray PDF data D(r) measured for the MQG (green), ZIF-4 (broken black) and the HDA phase (broken pink). The X-ray total scattering data S(q) is presented in Supplementary Fig. 1. Inset: optical images of (left) ZIF-4 (right) MQG, showing the typical fracture pattern of a non-metallic bulk glass. Scale bars, 100 μm.
Figure 2SAXS/WAXS data on ZIF-4 (top) and ZIF-8 (bottom).
(a) I(q)SAXS profiles of ZIF-4, with Lorentzian fits (Supplementary Methods) and three-dimensional plot (inset), highlighting the emergence of a peak between 618 and 663 K (Supplementary Fig. 2f). (b) WAXS data shows the major loss of Bragg diffraction on collapse at ca. 642 K. (c) I(q)SAXS profiles with Lorentzian fits and three-dimensional plot of the SAXS results for ZIF-8. (d) WAXS data show the retention of crystallinity across the entire temperature range studied.
Figure 3Dynamics of ZIF-4 amorphization, polyamorphic glass transitions and coexistence
(a) Sequence of DSC up-scans on ZIF-4 at 10 K min−1 starting with ZIF-4 (black), showing: solvent release (A), collapse to LDL phase (D–F), followed by the LLT to HDL (F–H). The jump in the isobaric heat capacity (Cp) through the LLT (E–G) is 0.33 J g−1 K−1. ΔCp is the difference in Cp from glass to liquid at Tg, being 0.11 and 0.16 J g−1 K−1 for LDA and HDA phases, respectively. The endotherms in successive scans (2–red, 3–green) relate to HDA phase. (b) DSC second up-scans on the same samples at different rates right after cooling, yielding Tg and m for HDA. (c) The change in integrated SAXS , showing the increase of the peak temperature (Tpeak) for different heating rates, giving Tg and m for the LDA phase. Inset: dependences of the Maxwell viscosity12 η=Gτ, where G and τ are the adiabatic shear modulus (2 GPa)40 and structural relaxation time ∼1/heating rate, respectively. (d) DSC up-scans preheated to temperatures A(529 K), B (563 K), C(578 K), D(588 K), E(601 K), F(608 K), G(613 K), H(673 K), cooled back to room temperature, and then reheated to 673 K—all at 10 K min−1. Arrows indicate Tg HDA increasing and Tg LDA decreasing with increases in initial scan temperature. Temperature at 588 K reveals coexistence of LDA and HDA. With double scans (d), amorphization stages occur 20 K lower than for single scans (a).
Figure 4Fragilities and critical point of ZIF-4 polyamorphs, projecting Tm from Tg, and PEL schematic of ZIF-4 amorphization, melting and quenching routes.
(a) Angell plot showing the fragility of LDL and HDL ZIF-4 (Fig. 3b,c), alongside other glass-forming liquids41 including the silica with <20 p.p.m. hydroxyl and <60 metallic impurities. Solid lines are fits to the measured viscosity-temperature relation of the model derived in previous literature1642. (b) T–P phase diagrams obtained from the limiting thermobaric amorphization parameters for ZIF-4 P1, P2, T1 and T2, which extrapolate to a critical point C at negative pressure Tc (659 K) and Pc (–0.063 GPa). PA and TA refer to 50% amorphization points under pressure (RP)5 and temperature (RT)18, respectively. (c) 2/3's Law (Tg versus Tm) for different glass-forming systems293031, including ZIF-4 and ZIF-8 compared with DAF-2 and sodalite, respectively. The thermal degradation temperature separating the locations of the two amorphized ZIFs is shown. (d) Schematic of the PEL43 for ZIF-4, informed from DSC experiments from Figs 1b and 3a. The adjacent LDA and HDA minima bear resemblance to the two states for water, different in density and topology, recently identified in modelling ST2 water36.
pan class="Species">Compton scattering and absorption were applied. The normalized reciprocal space data (Supplementary Fig S1) were then converted to the PDFs using Fourier transform.