Grantee Research Project Results

Sustainable PFAS Removal from Biosolids A Multifaceted, Biochar-Based Approach

EPA Contract Number: 68HERC25C0012
Title: Sustainable PFAS Removal from Biosolids A Multifaceted, Biochar-Based Approach
Investigators: Shubert, Jason R
Small Business: Talon LPE, Ltd.
EPA Contact: Richards, April
Phase: I
Project Period: December 16, 2024 through June 15, 2025
Project Amount: $100,000
RFA: Small Business Innovation Research (SBIR) - Phase I (2025) RFA Text |  Recipients Lists
Research Category: Small Business Innovation Research (SBIR)

Description:

The urgent need for effective PFAS remediation, especially in biosolids, drives this Phase I project. We're proposing an innovative, multifaceted solution that leverages the remarkable properties of biochar to create a sustainable and scalable process that can be rapidly commercialized in wastewater treatment plants (WWTPs) across the U.S.

Our research will explore three key strategies.

Direct Biochar Application: We'll mix engineered, manure-based biochar directly into biosolids to trap and lock away PFAS, preventing them from escaping into the environment.

Leaching and Biochar Filtration: A two-step process where we'll first extract PFAS from biosolids into a liquid, then capture them using a specialized biochar filter.

Biosolids Pyrolysis: We'll use high temperatures to break down PFAS in biosolids, while also creating valuable biochar that can be reused.

This innovative technology offers several key advantages.

Sustainability: It uses renewable resources (manure-based biochar) and turns waste into valuable products, promoting a circular economy.

Scalability: It can be adapted to handle different amounts and types of biosolids, making it suitable for both large and small wastewater treatment plants.

Cost-Effectiveness: It uses readily available materials and could even generate revenue through biochar reuse, helping to offset treatment costs.

Environmental Impact: It significantly reduces PFAS contamination in biosolids, protecting both the environment and public health.

If successful, this project could revolutionize how we manage biosolids, giving wastewater treatment plants a practical and sustainable way to deal with PFAS. Plus, creating high-quality biochar for reuse aligns perfectly with the goals of a circular economy, offering additional economic and environmental benefits.

Our team's deep expertise in biochar, pyrolysis, and environmental chemistry, combined with encouraging preliminary results, makes us confident in our ability to conduct thorough feasibility studies during Phase I. We'll carefully evaluate each approach, looking at PFAS removal rates, the leftover waste, environmental impact, and how well it can be scaled up. By pinpointing the most promising method, we'll set the stage for a game-changing solution that tackles a major environmental problem and opens up new business opportunities in the growing PFAS remediation market.