https://news.mit.edu/2024/solar-powered-desalination-system-requires-no-extra-batteries-1008

Skip to content |
Massachusetts Institute of Technology
MIT Top Menu|

  * Education
  * Research
  * Innovation
  * Admissions + Aid
  * Campus Life
  * News
  * Alumni
  * About MIT
  * More |

Search MIT
Search websites, locations, and people
[                    ]
See More Results

Suggestions or feedback?

MIT News | Massachusetts Institute of Technology

Subscribe to MIT News newsletter
Browse
Enter keywords to search for news articles: [                    ] 
Submit
Browse By

Topics

View All -
Explore:

  * Machine learning
  * Sustainability
  * Startups
  * Black holes
  * Classes and programs

Departments

View All -
Explore:

  * Aeronautics and Astronautics
  * Brain and Cognitive Sciences
  * Architecture
  * Political Science
  * Mechanical Engineering

Centers, Labs, & Programs

View All -
Explore:

  * Abdul Latif Jameel Poverty Action Lab (J-PAL)
  * Picower Institute for Learning and Memory
  * Media Lab
  * Lincoln Laboratory

Schools

  * School of Architecture + Planning
  * School of Engineering
  * School of Humanities, Arts, and Social Sciences
  * Sloan School of Management
  * School of Science
  * MIT Schwarzman College of Computing

View all news coverage of MIT in the media -
Listen to audio content from MIT News -
Subscribe to MIT newsletter -
Close

Breadcrumb

 1. MIT News
 2. Solar-powered desalination system requires no extra batteries

Solar-powered desalination system requires no extra batteries

Because it doesn't need expensive energy storage for times without
sunshine, the technology could provide communities with drinking
water at low costs.
Jennifer Chu | MIT News
Publication Date:
October 8, 2024
Press Inquiries

Press Contact:

Abby Abazorius
Email: abbya@mit.edu
Phone: 617-253-2709
MIT News Office

Media Download

In rural New Mexico, a solar panel truck is next to a trailer with
lots of hoses connected to it going many directions.
| Download Image
Caption: Jon Bessette sits atop a trailer housing the electrodialysis
desalination system at the Brackish Groundwater National Desalination
Research Facility (BGNDRF) in Alamogordo, New Mexico. The system is
connected to real groundwater, water tanks, and solar panels.
Credits: Photo: Shane Pratt
Three people stand inside a trailer with tanks and hoses.
| Download Image
Caption: (Left to right): Jon Bessette, Shane Pratt, and Muriel
McWhinnie (UROP) stand in front of the electrodialysis desalination
system during an installation in July.
Credits: Photo: Shane Pratt

*Terms of Use:

Images for download on the MIT News office website are made available
to non-commercial entities, press and the general public under a
Creative Commons Attribution Non-Commercial No Derivatives license.
You may not alter the images provided, other than to crop them to
size. A credit line must be used when reproducing images; if one is
not provided below, credit the images to "MIT."

Close
In rural New Mexico, a solar panel truck is next to a trailer with
lots of hoses connected to it going many directions.
Caption:
Jon Bessette sits atop a trailer housing the electrodialysis
desalination system at the Brackish Groundwater National Desalination
Research Facility (BGNDRF) in Alamogordo, New Mexico. The system is
connected to real groundwater, water tanks, and solar panels.
Credits:
Photo: Shane Pratt
Three people stand inside a trailer with tanks and hoses.
Caption:
(Left to right): Jon Bessette, Shane Pratt, and Muriel McWhinnie
(UROP) stand in front of the electrodialysis desalination system
during an installation in July.
Credits:
Photo: Shane Pratt
Schematic of the system shows solar panels, containers, and spouts,
and water with positive and negative charge.
Caption:
In a direct-drive electrodialysis desalination system, using
flow-commanded current control, solar panels take in energy from the
sun and then optimally allocate energy (shown in yellow) to the pump
and electrodialysis stack, without the need for energy storage, such
as batteries. Saline feed water flows through the pump into the
electrodialysis stack, where it is desalinated and split into a
drinking water stream (light blue) and a concentrated brine stream
(dark blue).
Credits:
Credit: Jonathan Bessette

Previous image Next image

MIT engineers have built a new desalination system that runs with the
rhythms of the sun.

The solar-powered system removes salt from water at a pace that
closely follows changes in solar energy. As sunlight increases
through the day, the system ramps up its desalting process and
automatically adjusts to any sudden variation in sunlight, for
example by dialing down in response to a passing cloud or revving up
as the skies clear.

Because the system can quickly react to subtle changes in sunlight,
it maximizes the utility of solar energy, producing large quantities
of clean water despite variations in sunlight throughout the day. In
contrast to other solar-driven desalination designs, the MIT system
requires no extra batteries for energy storage, nor a supplemental
power supply, such as from the grid.

The engineers tested a community-scale prototype on groundwater wells
in New Mexico over six months, working in variable weather conditions
and water types. The system harnessed on average over 94 percent of
the electrical energy generated from the system's solar panels to
produce up to 5,000 liters of water per day despite large swings in
weather and available sunlight.

"Conventional desalination technologies require steady power and need
battery storage to smooth out a variable power source like solar. By
continually varying power consumption in sync with the sun, our
technology directly and efficiently uses solar power to make water,"
says Amos Winter, the Germeshausen Professor of Mechanical
Engineering and director of the K. Lisa Yang Global Engineering and
Research (GEAR) Center at MIT. "Being able to make drinking water
with renewables, without requiring battery storage, is a massive
grand challenge. And we've done it."

The system is geared toward desalinating brackish groundwater -- a
salty source of water that is found in underground reservoirs and is
more prevalent than fresh groundwater resources. The researchers see
brackish groundwater as a huge untapped source of potential drinking
water, particularly as reserves of fresh water are stressed in parts
of the world. They envision that the new renewable, battery-free
system could provide much-needed drinking water at low costs,
especially for inland communities where access to seawater and grid
power are limited.

"The majority of the population actually lives far enough from the
coast, that seawater desalination could never reach them. They
consequently rely heavily on groundwater, especially in remote,
low-income regions. And unfortunately, this groundwater is becoming
more and more saline due to climate change," says Jonathan Bessette,
MIT PhD student in mechanical engineering. "This technology could
bring sustainable, affordable clean water to underreached places
around the world."

The researchers report details the new system in a paper appearing
today in Nature Water. The study's co-authors are Bessette, Winter,
and staff engineer Shane Pratt.

Pump and flow

The new system builds on a previous design, which Winter and his
colleagues, including former MIT postdoc Wei He, reported earlier
this year. That system aimed to desalinate water through "flexible
batch electrodialysis."

Electrodialysis and reverse osmosis are two of the main methods used
to desalinate brackish groundwater. With reverse osmosis, pressure is
used to pump salty water through a membrane and filter out salts.
Electrodialysis uses an electric field to draw out salt ions as water
is pumped through a stack of ion-exchange membranes.

Scientists have looked to power both methods with renewable sources.
But this has been especially challenging for reverse osmosis systems,
which traditionally run at a steady power level that's incompatible
with naturally variable energy sources such as the sun.

Winter, He, and their colleagues focused on electrodialysis, seeking
ways to make a more flexible, "time-variant" system that would be
responsive to variations in renewable, solar power.

In their previous design, the team built an electrodialysis system
consisting of water pumps, an ion-exchange membrane stack, and a
solar panel array. The innovation in this system was a model-based
control system that used sensor readings from every part of the
system to predict the optimal rate at which to pump water through the
stack and the voltage that should be applied to the stack to maximize
the amount of salt drawn out of the water.

When the team tested this system in the field, it was able to vary
its water production with the sun's natural variations. On average,
the system directly used 77 percent of the available electrical
energy produced by the solar panels, which the team estimated was 91
percent more than traditionally designed solar-powered
electrodialysis systems.

Still, the researchers felt they could do better.

"We could only calculate every three minutes, and in that time, a
cloud could literally come by and block the sun," Winter says. "The
system could be saying, 'I need to run at this high power.' But some
of that power has suddenly dropped because there's now less sunlight.
So, we had to make up that power with extra batteries."

Solar commands

In their latest work, the researchers looked to eliminate the need
for batteries, by shaving the system's response time to a fraction of
a second. The new system is able to update its desalination rate,
three to five times per second. The faster response time enables the
system to adjust to changes in sunlight throughout the day, without
having to make up any lag in power with additional power supplies.

The key to the nimbler desalting is a simpler control strategy,
devised by Bessette and Pratt. The new strategy is one of
"flow-commanded current control," in which the system first senses
the amount of solar power that is being produced by the system's
solar panels. If the panels are generating more power than the system
is using, the controller automatically "commands" the system to dial
up its pumping, pushing more water through the electrodialysis
stacks. Simultaneously, the system diverts some of the additional
solar power by increasing the electrical current delivered to the
stack, to drive more salt out of the faster-flowing water.

"Let's say the sun is rising every few seconds," Winter explains.
"So, three times a second, we're looking at the solar panels and
saying, 'Oh, we have more power -- let's bump up our flow rate and
current a little bit.' When we look again and see there's still more
excess power, we'll up it again. As we do that, we're able to closely
match our consumed power with available solar power really
accurately, throughout the day. And the quicker we loop this, the
less battery buffering we need."

The engineers incorporated the new control strategy into a fully
automated system that they sized to desalinate brackish groundwater
at a daily volume that would be enough to supply a small community of
about 3,000 people. They operated the system for six months on
several wells at the Brackish Groundwater National Desalination
Research Facility in Alamogordo, New Mexico. Throughout the trial,
the prototype operated under a wide range of solar conditions,
harnessing over 94 percent of the solar panel's electrical energy, on
average, to directly power desalination.

"Compared to how you would traditionally design a solar desal system,
we cut our required battery capacity by almost 100 percent," Winter
says.

The engineers plan to further test and scale up the system in hopes
of supplying larger communities, and even whole municipalities, with
low-cost, fully sun-driven drinking water.

"While this is a major step forward, we're still working diligently
to continue developing lower cost, more sustainable desalination
methods," Bessette says.

"Our focus now is on testing, maximizing reliability, and building
out a product line that can provide desalinated water using
renewables to multiple markets around the world," Pratt adds.

The team will be launching a company based on their technology in the
coming months.

This research was supported in part by the National Science
Foundation, the Julia Burke Foundation, and the MIT Morningside
Academy of Design. This work was additionally supported in-kind by
Veolia Water Technologies and Solutions and Xylem Goulds. 

Share this news article on:

  * X
  * Facebook
  * LinkedIn
  * Reddit
  * Print

Paper

Paper: "Renewable desalination without energy storage: direct-drive
photovoltaic electrodialysis via flow-commanded current control"
Paper: "Flexible batch electrodialysis for low-cost solar-powered
brackish water desalination"

Related Links

  * Amos Winter
  * Jonathan Bessette
  * GEAR Center
  * Department of Mechanical Engineering
  * School of Engineering

Related Topics

  * Desalination
  * Developing countries
  * Energy efficiency
  * Environment
  * Mechanical engineering
  * Renewable energy
  * Research
  * Solar
  * Sustainability
  * Water
  * School of Engineering
  * National Science Foundation (NSF)

Related Articles

Lisa Yang and Amos Winter pose for a photo. They sit together at a
black table in a white room with an intricately carved wooden dresser
and a Buddah head statue in the background.

K. Lisa Yang Global Engineering and Research Center will prioritize
innovations for resource-constrained communities

Three women, researchers from the GEAR Lab, stand on a dirt road in a
field in Jordan holding laptops.

Smart irrigation technology covers "more crop per drop"

A woman carrying a Khethworks solar panel. The efficiency of
Khethworks' groundwater pump enables it to be powered by smaller
panels, making the system portable.

A new way to irrigate crops year-round

A desalinization prototype, a clear rectangular box with water, tubes
and a square spring, setup in the lab

Desalination system could produce freshwater that is cheaper than tap
water

WInning 100K teams with check

Solar-powered desalination device wins MIT $100K competition

Previous item Next item

More MIT News

Grayscale image of nematode worms under a microscope

A cell protector collaborates with a killer

New research reveals what it takes for a protein that is best known
for protecting cells against death to take on the opposite role.

Read full story -

Illustration shows rainbow-hued particles uniformly distributed on a
deep blue background. A pair of cirlces labeled "E4" are shown
orbiting in a circle at the center.

MIT physicists predict exotic form of matter with potential for
quantum computing

New work suggests the ability to create fractionalized electrons
known as non-Abelian anyons without a magnetic field, opening new
possibilities for basic research and future applications.

Read full story -

Multiple layers of graphene

How can electrons can split into fractions of themselves?

Physicists surprised to discover electrons in pentalayer graphene can
exhibit fractional charge. New study suggests how this could work.

Read full story -

Yiming Chen '24, Wilhem Hector, Anushka Nair, and David Oluigbo

Four from MIT named 2025 Rhodes Scholars

Yiming Chen '24, Wilhem Hector, Anushka Nair, and David Oluigbo will
start postgraduate studies at Oxford next fall.

Read full story -

Two people pose holding up a large prop check for $10,000

A launchpad for entrepreneurship in aerospace

The Certificate in Aerospace Innovation gives students the tools and
confidence to be aerospace entrepreneurs during an inflection point
in the industry.

Read full story -

Five people sit on stage during a panel discussion

Ensuring a durable transition

Progress on the energy transition depends on collective action
benefiting all stakeholders, agreed participants in MITEI's annual
research conference.

Read full story -

  * More news on MIT News homepage -

More about MIT News at Massachusetts Institute of Technology

This website is managed by the MIT News Office, part of the Institute
Office of Communications.

News by Schools/College:

  * School of Architecture and Planning
  * School of Engineering
  * School of Humanities, Arts, and Social Sciences
  * MIT Sloan School of Management
  * School of Science
  * MIT Schwarzman College of Computing

Resources:

  * About the MIT News Office
  * MIT News Press Center
  * Terms of Use
  * Press Inquiries
  * Filming Guidelines
  * RSS Feeds

Tools:

  * Subscribe to MIT Daily/Weekly
  * Subscribe to press releases
  * Submit campus news
  * Guidelines for campus news contributors
  * Guidelines on generative AI

Massachusetts Institute of Technology
MIT Top Level Links:

  * Education
  * Research
  * Innovation
  * Admissions + Aid
  * Campus Life
  * News
  * Alumni
  * About MIT
  * Join us in building a better world.

Massachusetts Institute of Technology
77 Massachusetts Avenue, Cambridge, MA, USA

Recommended Links:

  * Visit
  * Map (opens in new window)
  * Events (opens in new window)
  * People (opens in new window)
  * Careers (opens in new window)
  * Contact
  * Privacy
  * Accessibility
  * 
      + Social Media Hub
      + MIT on X
      + MIT on Facebook
      + MIT on YouTube
      + MIT on Instagram