Highly robust and sensitive dual-network freeze-resistant organic hydrogel thermocells.

Thermocells (TECs) are eco-friendly and ideal power-generation devices that sustainably convert waste heat into electricity to power wearable electronics. However, their poor mechanical properties, limited operating temperature, and low sensitivity limit their practical application. Hence, K3/4Fe(CN)6 and NaCl thermoelectric materials were introduced into a bacterial cellulose-reinforced polyacrylic acid double-network structure and permeated into a glycerol (Gly)/water binary solvent to prepare an organic thermoelectric hydrogel. The resulting hydrogel had a tensile strength of approximately 0.9 MPa and a stretched length of approximately 410 %; moreover, it worked stably even in the stretched/twisted state. Owing to the introduction of Gly and NaCl, the as-prepared hydrogel exhibited excellent freezing tolerance (- 22 °C). In addition, the TEC also demonstrated excellent sensitivity (~13 s). Good environmental stability and high sensitivity make this hydrogel TEC a promising candidate for thermoelectric power-generation/temperature-monitoring systems.

Bacterial cellulose-based dual chemical reaction coupled hydrogel thermocells for efficient heat harvesting.

Reasonable and efficient utilization of low-grade thermal energy in nature is the choice for sustainable energy development. We demonstrate a bacterial cellulose (BC) hydrogel thermocell (TEC) based on BC electrolyte combined with carbon fiber paper and copper composite electrode sheets. The large specific surface area of carbon fiber paper provides a large number of active sites for thermoelectric ions, which drives the redox reaction inside the electrolyte and stimulates the chemical reaction between the electrolyte and the electrode. The combination of the two chemical reactions significantly improves the thermoelectric performance of the thermocell. The thermopower of the BC-TEC reaches 5.9 mV·K-1 at a temperature difference of 50 K. The TEC consisting of 6-units in series produces an open-circuit voltage of about 2 V and a peak power of 535 µW. The TEC shows new potential and prospects in ambient thermoelectric energy conversion by rationally designing the power generation principle.

Wood-inspired high strength and lightweight aerogel based on carbon nanotube and nanocellulose fiber for heat collection.

Wood is one of the most abundant materials in nature, with excellent mechanical properties and anisotropy. Its main component, cellulose has excellent dispersion properties and biocompatibility after nano-treatment, which has aroused the interest of researchers. Therefore, this study prepared a thermoelectric aerogel based on carboxylated nanocellulose fiber and carbon nanotube, and made it have a wood-like anisotropic structure through directional freezing technology. The aerogel exhibited excellent mechanical properties and had the stress of up to 152 kPa when compressed at 90%. It also exhibited low thermal conductivity (0.03-0.08 W/mK) and density (7.5 mg/cm3). When the device was at a temperature difference of 30 K, the single output power was 0.23 nW. This work confirmed the dispersion effect of carboxylated nanocellulose fiber on carbon nanotube, and the enhancement of the wood-like structure on thermoelectric generators. It provided new ideas and solutions for the construction of thermoelectric devices.