The candidate thermoelectric compounds Mg3Sb2 and Mg3Bi2 show excellent performance near ambient temperature, enabled by an anomalously low lattice thermal conductivity (κl) comparable to those of much heavier PbTe or Bi2Te3. Contrary to common mass-trend expectations, replacing Mg with heavier Ca or Yb yields a threefold increase in κl in CaMg2Sb2 and YbMg2Bi2. Here, we report a comprehensive analysis of phonons in the series AMg2X2 (A = Mg, Ca, and Yb; X = Bi and Sb) based on inelastic neutron/x-ray scattering and first-principles simulations and show that the anomalously low κl of Mg3X2 has inherent phononic origins. We uncover a large phonon softening and flattening of low-energy transverse acoustic phonons in Mg3X2 compared to the ternary analogs and traced to a specific Mg-X bond, which markedly enlarges the scattering phase-space, enabling the threefold tuning in κl. These results provide key insights for manipulating phonon scattering without the traditional reliance on heavy elements.
One of the main factors responsible for the mechanical and physical properties of nanocomposites is the effectiveness of the interfacial region to transfer loads and mechanical vibrations between the nano-reinforcements and the matrix. Surface functionalization has been the preferred approach to engineer the interfaces in polymer nanocomposites in order to maximize their potential in structural and functional applications. In this study, amine-functionalized cellulose nanofibrils (mCNF-G1) were synthesized via silylation of the hydroxyl groups on the CNF surface using 3-aminopropyltrimethoxysilane (APTMS). To further increase the amine density (mCNF-G2), dendritic polyamidoamine (PAMAM) was grafted onto mCNF-G1 by the Michael addition of methacrylate onto mCNF-G1, followed by the transamidation of the ester groups of methacrylate using ethylenediamine. Compared to native CNF-reinforced, poly(l-lactide) (PLLA) nanocomposites, amine-functionalized CNF exhibited significantly improved dispersion and interfacial properties within the PLLA matrix due to the grafting of PLLA chains via aminolysis. It is also a more effective nucleating agent, with 15% mCNF-G1 leading to a crystallinity of 32.5%, compared to 0.1 and 8.7% for neat PLLA and native CNF-reinforced composites. We have demonstrated that APTMS-functionalized CNF (mCNF-G1) significantly improved the tensile strength compared to native CNF, with 10% mCNF-G1 being the most effective (i.e., >100% increase in tensile strength). However, we also found that excessive amines on the CNF surface (i.e., mCNF-G2) resulted in decreased tensile strength and modulus due to PLLA degradation via aminolysis. These results demonstrate the potential of optimized amine-functionalized CNF for future renewable material applications.
Alloys
between Mg3Sb2 and Mg3Bi2 have recently been shown to be exceptional thermoelectric
materials due in part to their anomalously low thermal conductivity.
In the present study, in situ high-pressure synchrotron
X-ray diffraction was used to investigate the structure and bonding
in Mg3Sb2 and Mg3Bi2 at
pressures up to 50 GPa. Our results confirm prior predictions of isotropic
in-plane and out-of-plane compressibility but reveal large disparities
between the bond strength of the two distinct Mg sites. Using single-crystal
diffraction, we show that the octahedral Mg–Sb bonds are significantly
more compressible than the tetrahedral Mg–Sb bonds in Mg3Sb2, which lends support to prior arguments that
the weaker octahedral Mg bonds are responsible for the anomalous thermal
properties of Mg3Sb2 and Mg3Bi2. Further, we report the discovery of a displacive and reversible
phase transition in both Mg3Sb2 and Mg3Bi2 above 7.8 and 4.0 GPa, respectively. The transition
to the high-pressure structure involves a highly anisotropic volume
collapse, in which the out-of-plane axis compresses significantly
more than the in-plane axes. Single-crystal diffraction at high pressure
was used to solve the monoclinic high-pressure structure (C2/m), which is a distorted variant of
the ambient-pressure structure containing four unique Mg coordination
environments.
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