Our Research Distributed water harvesting from air in water-stressed and remote areas using metal-organic frameworks

Water harvesting prototype on rooftop during outdoor experiment

The water harvesting prototype and experimental setup on the roof of MIT. The device was tested in outdoor experiments in which the adsorbent was regenerated by unconcentrated sunlight. Photo credit: Wang research team

Graphic showing principle of passive, solar-driven adsorption

The operating principle of passive, solar-driven adsorption-based AWH device operating on a daily cycle. Image credit: Wang Research team

Principal Investigators

Mircea Dincă

W. M. Keck Professor of Energy
Department of Chemistry

Evelyn Wang

Gail E. Kendall Professor
Department Head
Department of Mechanical Engineering

Challenge:

How can residents of remote, water-scarce, or polluted environments gain access to fresh drinking water in a localized, carbon-neutral way?

Research Strategy

Engineer metal-organic frameworks (MOFs) to harvest water powered by passive solar
Design a compact device that can fulfill point-of-use needs for rural households and villages in arid regions

Project description

Access to clean water is one of the largest challenges that we face in the world today. While a substantial amount of water is available in the form of vapor in the atmosphere, current techniques such as dewing and fog capture are limited in relative humidity/temperature ranges and/or require large electrical energy inputs. The research team for this project is developing a water harvesting technology that will be well-suited for the production of water at the point of use in water-stressed and remote areas. Their approach harvests water from ambient air via adsorption with porous materials such as metal-organic frameworks (MOF) or zeolites. During operation, the adsorbent is exposed to ambient air, during which the water vapor is adsorbed inside the pores of the material. To harvest the adsorbed water , low-grade heat from sunlight releases the water for condensation and collection. In particular, they are leveraging their development and ability to tailor novel, ultra-high water capacity MOFs. The high uptake capacity and sharp step in the adsorption isotherm can lead to a higher capacity and more efficient device. They aim to further develop these materials, as well as design and optimize a proof-of-concept water harvesting device which demonstrates the scalability of solar-thermal driven devices. This work is an important step towards the realization of adsorption-based water harvesters to address the water scarcity problem worldwide.

Outcomes

Developed a suite of metal-organic frameworks based on M₂X₂BTDD system that reversibly adsorb water with record setting capacities
Synthesized Ni₂Br₂BTDD metal-organic framework (MOF) that can extract water from the air at just 24% humidity and is stable after 400 rounds of water cycling while maintaining rapid rate of water adsorption
Developed a new water harvesting device configuration which can be regenerated passively, by unconcentrated sunlight, and can harvest more water per device area. Developed a detailed computation model to predict device performance and to optimize the design
Tested the new device in outdoor water harvesting experiments where 80x more water was collected than our previous devices under similar, unconcentrated sunlight conditions, demonstrating progress towards scaling of solar-thermal AWH

Publications

Dual-stage atmospheric water harvesting device for scalable solar-driven water production

Alina LaPotin, Yang Zhong, Lenan Zhang, Lin Zhao, Arny Leroy, Hyunho Kim, Sameer R. Rao, and Evelyn N. Wang, Joule, 2021

Record-setting sorbents for reversible water uptake by systematic anion exchanges in metal-organic frameworks

Adam J. Rieth, Ashley M. Wright, Grigorii Skorupskii, Jenna L. Mancuso, Christopher H. Hendon, and Mircea Dincă, Journal of the American Chemical Society, 2019

Adsorption-based atmospheric water harvesting: impact of material and component properties on system-level performance

Alina LaPotin, Hyunho Kim, Sameer R. Rao, and Evelyn N. Wang, Accounts of Chemical Research, 2019

Tunable metal-organic frameworks enable high efficiency cascaded adsorption heat pumps

Adam J. Rieth, Ashley M. Wright, Sameer R. Rao, Hyunho Kim, Alina D. LaPotin, Evelyn N. Wang, Mircea Dincă, Journal of American Chemical Society, 2018

Record atmospheric fresh water capture and heat transfer with a material operating at the water uptake reversibility limit

Adam J. Rieth, Sungwoo Yang, Evelyn N. Wang, and Mircea Dincă, ACS Central Science, 2017

News

J-WAFS projects make inroads on global food and water challenges

Nearly two dozen research teams supported by J-WAFS presented updates on their work at a day-long event on Sept. 15th, 2017. This MIT News…

Collaboration runs through J-WAFS-funded projects

Researchers from across MIT showcase J-WAFS-funded projects tackling critical water and food systems challenges from solutions-oriented…

Water sourced from desert air – and it’s no mirage

An article published in The National covers a collaborative project of Profs. Evelyn Wang and Mircea Dinca funded by J-WAFS working to…

Professor Evelyn Wang is receiving attention for her J-WAFS funded work that aims to improve water supply

MIT News has highlighted J-WAFS sponsored work being done by Evelyn Wang, head of MIT’s Department of Mechanical Engineering. The…

Scientists from MIT and Berkeley discover a way to harvest fresh water from air

A novel, passive solar device that can obtain fresh water was developed by a scientists at MIT and University of California at Berkeley…

Additional Details

Impact Areas

Water

Research Themes

Water Purification & Desalination
Water Resources & Infrastructure
Technology & Commercialization
Sustainability & Adaptation
Equity & Access

Year Funded

2017

Grant Type

Seed Grant

Status

Completed