Valorizing Sewage Sludge: Using Nature-Inspired Architecture to Overcome Intrinsic Weaknesses of Waste-Based Materials

TL;DR

This paper explores converting sewage sludge into hydrochar via hydrothermal processing and enhancing its use in additive manufacturing by applying nature-inspired hierarchical microstructures to improve mechanical properties.

Contribution

It introduces a novel approach of using nature-inspired architecture to overcome weaknesses of waste-derived hydrochar in additive manufacturing.

Findings

Hydrothermal processing alters chemical and structural properties of sewage sludge.

Hierarchical microstructures can recover toughness and strain in hydrochar composites.

Atypical metallic and metalloid dopants influence organic material processing.

Abstract

Sewage sludge, a biosolid product of wastewater processing, is an often-overlooked source of rich organic waste. Hydrothermal processing (HTP), which uses heat and pressure to convert biomass into various solid, liquid, and gaseous products, has shown promise in converting sewage sludge into new materials with potential application in biofuels, asphalt binders, and bioplastics. In this study we focus on hydrochar, the carbonaceous HTP solid phase, and investigate its use as a bio-based filler in additive manufacturing technologies. We explore the impact of HTP and subsequent thermal activation on chemical and structural properties of sewage sludge and discuss the role of atypical metallic and metalloid dopants in organic material processing. In additive manufacturing composites, although the addition of hydrochar generally decreases mechanical performance, we show that toughness and strain can be recovered with hierarchical microstructures, much like biological materials that achieve outstanding properties by architecting relatively weak building blocks.