Ulrike G. K. Wegst3,2,Kaiyan Qiu1,2
Washington State University1,Dartmouth College2,Northeastern University3
Ulrike G. K. Wegst3,2,Kaiyan Qiu1,2
Washington State University1,Dartmouth College2,Northeastern University3
Native and carbonized freeze-cast bacterial cellulose-alginate (BC-ALG) foams possess an ice-templated honeycomb-like architecture with remarkable properties. Their unique pore morphology consists of two levels of porosity: 20–50 μm diameter pores between, and 0.01–10 μm diameter pores within the cell-walls. The mechanical properties of the BC-ALG foams, a Young’s modulus of up to 646.2 ± 90.4 kPa and a compressive yield strength of up to 37.1 ± 7.9 kPa, are high for their density and scale as predicted by the Gibson–Ashby model for cellular materials. Carbonizing the BC-ALG foams in an inert atmosphere at 1000–1200 °C in a second processing step, both pore mor-phology and mechanical properties of the BC-ALG remain well preserved with specific mechanical properties that are higher than those reported in the liter-ature for similar foams. Also the electrical conductivity of the BC-ALG foams is high at 1.68 ± 0.04 S cm−1 at a density of only 0.055 g cm−3, and is found to increase with density as predicted, and as a function of the degree of carbonization determined by both carbonization temperature and atmosphere. The property profile makes freeze-cast BC-ALG foams and their carbonized foams attractive for energy applications and as a sorbent.