Piezoelectric/ferroelectric zinc tin oxide (ZnSnO3) nanocubes (NCs) are synthesized via a hydrothermal synthesis process. Piezoelectric materials exhibit a superior dielectric property, strong electric dipole moment, and higher piezoelectric coefficient, which results in an improved electrical output of the nanogenerator. The synthesized ZnSnO3 NCs are embedded in triboelectric polydimethylsiloxane (PDMS) polymer to employ the synergistic effect of ZnSnO3/PDMS composite polymer matrix (CPM), which creates a hybrid nanogenerator (HNG). The proposed HNG reveals a high electrical performance due to the improved dielectric constant as well as the synergistic effect of piezoelectricity and triboelectricity. Besides, a conductive filler material such as reduced graphene oxide (rGO) is synthesized using a modified Hummer's method and is further utilized to prepare an rGO-ZnSnO3/PDMS CPM for improving the electrical output performance of the HNG. Furthermore, the ZnSnO3 NCs and rGO-ZnSnO3 with different amounts are embedded into PDMS polymeric film to optimize the electrical performance of the HNG. The durability test of the proposed HNG device along with the robustness is investigated. Finally, the proposed HNG device is employed to harvest mechanical movements from daily life human activities to power various portable electronics.

The controlled development of mixed phases of transition metal dichalcogenide (TMDC) electrodes with hierarchical nanostructures overcomes the limited contribution of pure TMDC compositions, which is desirable to achieve superior electrochemical performance. Herein, the flower-like NiMo3S4/NiS2 (NMS/NS) nanostructures with mixed-phase nature were grown on conductive carbon cloth (ie, NMS/NS@CC-210) at 210°C (24 h) by a hydrothermal method. Importantly, the uniform flower-like nanostructured NMS/NS@CC-210 electrode revealed battery-like performance with a superior specific capacitance of 1448 F g−1 (480 C g−1 at 1 A g−1) than the other NMS/NS@CC (180°C, 190°C, and 200°C) electrodes at different reaction temperatures as well as single counterparts of MoS2 (MS)@CC-210 and NiS2(NS)@CC-210 electrodes. The presence of plenty of lattice defects in NMS/NS@CC-210 electrode structure is favored to the exposure of several electrochemical active sites for rapid transportation of electron and electrolyte diffusion, resulting in better cycling retention (83%) behavior than the pure MoS2@CC (50%) and NiS2@CC (68%) electrodes after successive 5000 cycles. Using the optimized NMS/NS@CC-210 electrode, an asymmetric electrochemical capacitor was fabricated, and its electrochemical behavior was evaluated in a two-electrode system. The NMS/NS@CC-210//activated carbon (AC)@CC device delivered its superior energy and power densities of 43.8 W h kg−1 and 12 853 W kg−1, respectively. Finally, two flexible NMS/NS@CC-210//AC@CC devices with similar features were made and successfully powered the 3-V-based light-emitting diodes and display portable electronics for practical applications.

Rational architecture design of the artificial protective layer on the zinc (Zn) anode surface is a promising strategy to achieve uniform Zn deposition and inhibit the uncontrolled growth of Zn dendrites. Herein, a red phosphorous-derived artificial protective layer combined with a conductive N-doped carbon framework is designed to achieve dendrite-free Zn deposition. The Zn–phosphorus (ZnP) solid solution alloy artificial protective layer is formed during Zn plating. Meanwhile, the dynamic evolution mechanism of the ZnP on the Zn anode is successfully revealed. The concentration gradient of the electrolyte on the electrode surface can be redistributed by this protective layer, thereby achieving a uniform Zn-ion flux. The fabricated Zn symmetrical battery delivers a dendrite-free plating/stripping for 1100 h at the current density of 2.0 mA cm–2. Furthermore, aqueous Zn//MnO2 full cell exhibits a reversible capacity of 200 mAh g–1 after 350 cycles at 1.0 A g–1. This study suggests an effective solution for the suppression of Zn dendrites in Zn metal batteries, which is expected to provide a deep insight into the design of high-performance rechargeable aqueous Zn-ion batteries.

Triboelectric nanogenerators (TENGs) are one of the most trending energy harvesting devices because of their efficient and simple mechanism in harvesting mechanical energy from the environment into electricity. Herein, ferroelectric and dielectric bismuth tungstate (Bi2WO6 (BWO)) with a marigold flower-like structure is prepared via a hydrothermal method, which is embedded in poly(vinylidene fluoride-co-hexafluoropropylene) (PVDF-HFP), forming a PVDF-HFP/BWO composite polymer film (CPF) to fabricate TENGs. Generally, the ferroelectric materials exhibit a large piezoelectric coefficient, high electrostatic dipole moment, and high dielectric constant. The prepared PVDF-HFP/BWO CPF reveals a high polar crystalline β-phase which leads to enhanced piezoelectric and ferroelectric properties of the CPF, thus resulting in the increased electrical performance of the fabricated TENG. The electrical output performance of the proposed TENG is systematically investigated by varying the amount of BWO material embedded in the PVDF-HFP polymer. The fabricated PVDF-HFP/2.5 wt% BWO CPF-based TENG device exhibits the highest electrical output performance. Additionally, the robust test of the TENG device is conducted to investigate the electrical performance for long-term durability and mechanical stability. Finally, the proposed TENG is operated as a self-powered sensor, harvesting mechanical energy from daily life human activities, and powering various low-power portable electronics.