Nanofilters for Clean Water
STEM ED/CHM Nanotechnology 2009
Today’s Agenda
• The problem: adequate clean water• Kinds of filters• Desalination of salt water • Cleaning polluted water• Hands on nanofiltration experiment
The Problem: Adequate Clean Water
Despite the apparent abundance of clean water in most of the US and the developed world, more than 20% of the Earth’s population lacks clean, safe drinking water.
Sources: http://www.battelle.org/environment/images/water-drop.jpg http://www.tribuneindia.com/2004/20040718/pb3.jpg
How is the World’s Water Distributed?
• Less than 3% of Earth’s water is fresh water
• Most of it (97%) is undrinkable salt water in the oceans
• Of the fresh water, most is in ice caps and glaciers, and some is in ground water
• Less than 1% is in more easily accessible surface water (lakes, swamps, rivers, etc.)
Source: http://ga.water.usgs.gov/edu/watercyclesummary.html#global
No Single Cause for the Water Crisis
• Climate and geography• Lack of water systems and infrastructure• Depleting aquifers• Inadequate sanitation and pollution
• 2.6 billion people (40% of the world’s population) lack access to sanitation systems that separate sewage from drinking water
• Inadequate sanitation and no access to clean water have been highly correlated with disease
• Will worsen with increasing population, affluence
How Can We Address the Water Crisis?
• Use less water– More efficient irrigation, like drip irrigation; cover irrigation
ditches– Low-flow shower and toilets; recycle gray water– Use native plants for crops and landscaping; no lawns in AZ– Eat less meat (especially beef)– Fix leaky distribution systems (Quabbin reservoir)
• Find new sources of clean water– Icebergs? Pump aquifers more and more? Use tankers?
• Treat the undrinkable water that we have– Use reverse osmosis to desalinize salt (ocean) water– Clean polluted water using filters, chemicals, and UV light
Repairs to the leaky distribution system from the Quabbin Reservoir located in Western Massachusetts have reduced the demand for new supplies for the Boston area.
Pollution in Fresh Water• Sewage is the most common • Pesticides and fertilizers • Industrial waste dumping• High levels of minerals from
natural sources– Wells in Bangladesh have
dangerous arsenic levels
Sources: http://www.marenrecycling.com/polluted_water.JPG http://mainegov-images.informe.org/agriculture/pesticides/drift/mstblow1.gif
Water Filtration
• Systems for cleaning polluted water typically use a series of filters to remove smaller and smaller particles
• Seawater desalination facilities also use filters
Filters Are Everywhere
Window and door screens are filters – they let air in and keep out insects
Filters in the Home
Dryer filters remove lint
Air conditioning and furnace filters remove dust
Faucet screens trap small pebbles and other debris
Coffee filters block the grinds
http://www.princeton.edu/~pccm/outreach/scsp/mixturesandsolutions/diatoms/coffee_filter.html
Coffee Filter Scanning Electron Microscope Image
Air, oil, fuel, and other filters remove harmful materials
Filters in the Car
Filter Principles
• Some filters block particles too big to pass through holes, like window screens or cell membranes
http://en.wikipedia.org/wiki/File:Schematic_size.jpg
Filter Principles
• Some filters use electrical forces to trap or block particles.– Electrostatic air
cleaners place a charge on airborne particles, then collect the charged particles.
http://en.wikipedia.org/wiki/Activated_carbon
Filter Principles• Chemical filters are
based on molecular forces– Activated carbon is
very porous so it has a large surface area and can adsorb or react with large amount of material in water filtration systems
Filter Geometries
• Some use a single layer such as a screen or a membrane with pores to block particles – Window screen
• Others have an extended medium that gradually traps particles – Sand or gravel beds for
water filtration
http://www.worldhungeryear.org/why_speaks/19_files/image014.gif
Membrane Water Filters
• A membrane is a thin material that has pores (holes) of a specific size
• Membranes trap larger particles that won’t fit through the pores of the membrane, letting water and other smaller substances through to the other side
http://www.alting.fr/index.aspx
Water Filtration Categories
• Microfiltration • Ultrafiltration• Nanofiltration• Reverse Osmosis
Water Filtration Systems
• Pebbles, sand, & charcoal filter out large particles• Membranes filter out smaller particles• It is cost efficient to use a series of membranes to filter
increasingly smaller particles and microorganisms
http://www.alting.fr/images/cross_flow_details.gif
Membrane Filter Technology
http://www.netl.doe.gov/technologies/pwmis/techdesc/membrane/
Sources: http://www.waterworksmw.com/rack%201%20&%202b.jpg http://www.imc.cas.cz/sympo/41micros/Image126.gif
Microfiltration
• Typical pore size: 0.1 microns (100 nm)
• Very low pressure• Removes clay,
suspended materials, bacteria, large viruses
• Does not filter – small viruses, protein
molecules, sugar, and salts
A microfilter membrane
Microfiltration water plant, Petrolia, PA
Source: http://www.inge.ag/bilder/presse/bildmaterial/referenzen/jachenhausen.jpg
An ultrafiltration plant in Jachenhausen, Germany
Ultrafiltration• Typical pore size: 0.01
microns (10 nm)• Moderately low pressure• Removes viruses, protein,
and other organic molecules
• Does not filter ionic particles like – lead, iron, chloride ions;
nitrates, nitrites; other charged particles
Source: http://www.wateronline.com/crlive/files/Images/10899070-E891-11D3-8C1F-009027DE0829/newwater1.gif
Nanofiltration• Typical pore size: 0.001 micron
(1 nm) • Low to moderate pressure• Removes toxic or unwanted
bivalent ions (ions with 2 or more charges), such as– Lead– Iron– Nickel– Mercury (II) Nanofiltration water cleaning
serving Mery-sur-Oise, a suburb of Paris, France
The Problem With Salt Water
• People and most land plants and animals cannot use salt water
• Seawater is much saltier than your body fluids or cells. When it enters the stomach, water from cells in that area comes rushing out to try to equalize the concentrations. Many cells may die due to sudden dehydration.
The Problem With Salt Water
• Also, when your stomach fills rapidly with water from the cells, it causes you to throw up, so you lose almost twice as much water as the amount you originally drank.
• Finally, human kidneys can only make urine about 1/4 as salty as sea water. Therefore, to get rid of all the excess salt taken in by drinking salt water, you have to urinate more water than you drank, so you die of dehydration!
Desalination – 2 Methods
1. Distillation: use heat to evaporate salt water and condense water vapor– Expensive: requires a lot of thermal energy– Sometimes uses the waste heat from a nuclear or
other electric power plant to reduce costs (cogeneration)
– Some pesticides and fertilizers have lower boiling points than water and are not removed
– Some salts may migrate into distillate along walls– Water is tasteless and lacks minerals unless further
treated– Used in Saudi Arabia, elsewhere
Desalination by Distillation
http://www.millipore.com/labwater/lw3/purificationtechniques
Seawater Distillation Plants
desalination.com
Saudi Arabia
www.water-technology.net/projects/shuaiba/shuaiba5.htmlAbu Dhabi Emirate
On the International Space Station
Water is recovered from urine by distillation in a system installed in 2008 to reduce the amount of water that needs to be launched.
http://www.water-technology.net/projects/iss_water_recovery/
Desalination – 2 Methods
2. Reverse osmosis: Membrane with 0.1 nm holes, high pressure
– A practical large scale desalination method, less expensive than distillation without cogeneration
– Semipermeable membrane allows water to pass but not ions or other larger molecules
About Osmosis
• Osmosis is a process that requires a semipermeable membrane – It is permeable to water, allowing water
molecules to pass freely through its pores
– It is impermeable to certain other molecules, which cannot pass through it
• Youtube video
http://hyperphysics.phy-astr.gsu.edu/hbase/kinetic/ospcal.html
More water molecules strike the membrane on the pure water side (left), causing a net diffusion of water across the membrane. The water level rises until equal numbers of water molecules travel in each direction.
How Osmosis Works• More molecules strike the membrane on the pure
water side (a), causing a net diffusion of water across the membrane, raising the water level until there is equilibrium (b).– This explains the rise of sap in sugar maples– Could theoretically be a power source (river meets sea)
Solution
Kane and Sternheim
General Physics
Reverse Osmosis• Equilibrium occurs when the pressure due to the
water molecules is equal on both sides of the membrane (not equal concentrations)– The rate at which water molecules hit the membrane
is determined by their partial pressure– Osmotic pressure is the pressure that must be applied
to stop the flow of water across the membrane
• Reverse Osmosis occurs when enough pressure is applied on the solution side to reverse the flow.– Youtube demo (reverse osmosis desalination)
Reverse osmosis plant for Bahrain (under construction)
http://www.water-technology.net/projects/durrat-desalination/
Tuos reverse osmosis plant provides 10% of Singapore’s water
http://www.water-technology.net/projects/tuas/
Racks of elements containing reverse osmosis membranes (Israel). This plant produces 13% of the country’s domestic water supply.
http://www.water-technology.net/projects/israel/
Nanofilters
• Used to purify polluted water• Used as pre-filter for reverse osmosis in
desalination systems– Lower pressure required– Lower operating costs
• And special properties of nanosized particles can be exploited!– We can design new nanofilters that catch particles
smaller than they would catch based on size alone• Scientists are exploring a variety of methods to
build new nanomembranes with unique properties to filter in new and different ways
Source: http://sciencematters.berkeley.edu/archives/volume2/issue10/images/story2-2.jpg
New Nanofilters are Unique!• Nanomembranes can be
uniquely designed in layers with a particular chemistry and specific purpose– Insert particles toxic to
bacteria
• Embed tubes that “pull” water through and keep everything else out– Signal to self-clean
Image of a nanomembrane
New Nanomembranes I• Imagine having layers of
membranes into which specialized substances are placed to do specific jobs– You can put a chemical in the
filter that will kill bacteria upon contact!
Chemicals toxic to bacteria could be implanted in
nanomembranes
Source: Unknown
New Nanomembranes II• Embed “tubes”
composed of a type of chemical that strongly attracts (“loves”) water
• Weave into the membrane a type of molecule that can conduct electricity and repel oppositely charged particles, but let water through
Water-loving tubes
Electricity moving through a membrane
1 nm Sized Nanopores Repel Electronegative Objects
• 1-2 nm sized pores create an electric field over the opening– Repels negatively charged particles dissolved
in water– Most pollutants from agriculture, industry, and
rivers are negatively charged
• But water can get through!
NanoCeram® Filters• The active ingredient of the
filter media is a nano alumina fiber, only 2 nm in diameter. The nano fibers are highly electropositive.
• Separate particles by charge, not size; pores are large (2 microns)
• The filter retains all types of particles by electroadsorption, including silica, natural organic matter, metals, bacteria, DNA and virus.
http://www.argonide.com/publications/product_overview.pdf
Making the Filter
• The nano fibers are first dispersed and adhered to glass fibers. The nano alumina is seen as a fuzz on the two glass fibers.
• Other fibers are added and the mixture is processed at a paper mill to produce a non-woven filter.
• Because the nano alumina is dispersed, particles have easy access to the charged surface
Manufactured Like Paper (Low Cost)
• Much like a standard filter, the NanoCeram® electropositive fibrous filter media mechanically sieves particles larger than its average pore size.
• However, the NanoCeram® also adsorbs smaller particles throughout its entire fibrous structure,
• Used as prefilter in reverse osmosis instead of ultrafilters.
Nanofilter Biotech Applications
• Removal of contaminants from incoming water
• Prefiltering for reverse osmosis filters instead of ultrafilters
• Filtering endotoxins, bacteria and virus endotoxins
• Filtering hazardous pharmaceutical waste before disposal
• Separation of proteins
Nanofiltration Summary
• At the nanoscale, filters can be constructed to have properties designed to serve a particular purpose
• Scientists and engineers are now experimenting to create membranes that are low-cost yet very effective for filtering water to make it drinkable!
• These inventions may help to solve the global water shortage
NanoSense Hands on Experiment I
• Cleaning “river water”– Made from distilled
water, salt, crushed leaves, dirt, sand, copper sulfate pentahydrate, iron
– Filter with gravel, sand, activated charcoal, nanofilter
– Use test strips for ions – iron, copper, chlorine, nitrates, nitrites – after each step
NanoSense Hands on Experiment II
• Comparing ultrafiltration (25 nm pores) with nanofiltration (2000 nm pores, 2 nm fibers)
– Use diluted ink with 2 nm particles
– Compare clarity of filtered water, color of filter afterwards
– Compare pressure required
References
• www.millipore.com/labwater/lw3/purificationtechniques Maker of Millipore filters
• nanosense.org/activities/finefilters/index.html• www.argonide.com/publications/product_overview.pdf
Maker of argonide nanofilters• http://www.drinking-water.org/flash/splash.html National
Academy of Sciences Kirkland Museum• http://www.understandingnano.com/water.html• http://www.brianlaks.com/nanofilters.htm• http://www.water-technology.net/