Our Research Fouling-resistant nanoporous membranes

Stack of petri dishes and other tools on lab bench

Photo Credit: Grossman research team

Photo Credit: Grossman research team

Cartoon depiction of graphene oxide filter

Photo Credit: Grossman research team

Principal Investigator

Jeffrey C. Grossman

Morton and Claire Goulder and Family in Environmental Systems
Professor of Materials Science and Engineering
Head of the Department of Materials Science and Engineering
Department of Materials Science and Engineering

Jeffrey Grossman is the Morton and Claire Goulder and Family Professor in Environmental Systems at MIT. Professor Grossman's research specializes in utilizing learned insights to development new materials for energy conversion and storage with improved properties. Professor Grossman is the recipient of a 2015 J-WAFS Solutions Grant for his project, "Fouling-Resistant Nanoporous Membranes."

Challenge:

Existing thermal separation processes are costly and energy-intensive. Can precise water filtration occur without high energy inputs?

Research Strategy

Use graphene oxide to engineer a low-cost energy-efficient filter that resists fouling and filters contaminants at the molecular-level
Ensure that membrane tolerates extreme conditions: high temperatures, solvents, & oxidizers
Design membrane to maximize stability, flux, and salt rejection

Project description

The high cost and energy requirements of desalination limits its economic viability in many parts of the world and yet the cost of no water is even higher. Together with conservation and wastewater treatment, desalination is crucial in augmenting water supply for agriculture, food processing, and manufacturing. Many regions of the world already rely on this technology, including Israel, Saudi Arabia, and California. Existing technology relies on specially engineered membranes to remove salt from water, however the useful lifetime of these membranes is inherently limited due to the accumulation of organic foulants. These foulants can substantially reduce water flow and hence plant efficiency, but, due to the chemistry of the membrane itself, cannot be removed with conventional chlorine-based methods. The research team for this project developed scalable nanoporous membranes with optimized surface chemistry in order to increase resilience to both cleaning chemicals and biofoulants. By leveraging the improved permeability of graphene-based membranes, this technology resulted in a product that addresses a serious challenge for plant operators and manufacturing facilities, namely the delicate nature of existing membranes.

Outcomes

Designed and produced membrane samples
Demonstrated long term performance and chlorine resistance of membranes
Optimized design of membranes for stability and resistance to fouling
Resulted in the creation of the spinout company Via Separations

Publications

Chemistry and structure of graphene oxide via direct imaging

Shreya H. Dave, Chuncheng Gong, Alex W.robertson, Jamie H.Warner, and Jeffrey C. Grossman, ACS Nano, 2016

News

J-WAFS Solutions grant spinout pilots a cutting edge energy efficiency project

Via Separations, a company that spun out of a 2015 J-WAFS Solutions grant, partners with the U.S. Department of Energy and …

J-WAFS Solutions grant spinout SiTration is pioneering new separation processes for materials extraction

The company is reducing costs in industrial wastewater treatment, advanced manufacturing, and resource extraction of materials from…

J-WAFS Solutions grant spinout company receives Unreasonable Impact Fellowship

J-WAFS spinout company, Via Separations, was among the 16 ventures selected for the 2021 Unreasonable Impact Fellowship.

Shreya Dave, CEO of J-WAFS spinout ViaSeparations, has been featured on the MIT Energy Initiatve Podcast

Episode #27 of the MIT Energy Initiative Podcast discusses the topic of Climate Tech Startups and interviews Shreya Dave '09, SM'12, Ph.D.'…

MIT.nano launches START.nano accelerator

Pilot program at MIT.nano will support hard-tech startups with access to tools and facilities, including J-WAFS Solutions spinout company…

J-WAFS PI co-founds company helping manufacturers separate chemical compounds

Via Separations aims to eliminate 500 megatons of carbon dioxide by 2050 through an energy-efficient manufacturing process using…

MIT Alumni Feature: Shreya Dave on Tackling Food and Water Challenges After Graduation

J-WAFS spinout company named an "MIT clean tech company to watch"

J-WAFS PI Jeffrey Grossman and his team created Via Separations which was recognized for its innovations in the clean tech space.

Spinout Companies

Via Separations

Redefining the limits of membrane filtration

Fifteen percent of US energy consumption is dedicated to purifying streams in industrial processes. From polymers for plastic products, to active pharmaceutical ingredients for drugs, to nutrients for food products, traditional methods to separate and purify rely on heat. Via Separations is tackling this energy use in process separations by developing a novel, more resilient filtration membrane. It was co-founded by MIT alumna Shreya Dave '16 who was also involved in the J-WAFS Solutions-funded research on graphene membranes.

SiTration

Square image with colored dots and a line moving through

SiTration is building an ultra-durable filtration membrane technology to reduce cost and resource consumption in industrial wastewater treatment, advanced manufacturing, and resource extraction. It was co-founded by MIT alum Brendan Smith '20 who was also involved in the J-WAFS Solutions-funded research on graphene membranes.

Additional Details

Impact Areas

Water
Food

Research Themes

Water Purification & Desalination
Technology & Commercialization
Transforming Food Systems

Year Funded

2015

Grant Type

Solutions Grant

Status

Completed