4 ways we can avoid a catastrophic drought | David Sedlak | TEDxMarin
-
0:13 - 0:16Our grandparents' generation
created an amazing system -
0:16 - 0:19of canals and reservoirs
that made it possible -
0:19 - 0:22for people to live in places
where there wasn't a lot of water. -
0:23 - 0:25For example, during the Great Depression,
-
0:25 - 0:27they created the Hoover Dam,
-
0:27 - 0:29which in turn, created Lake Mead
-
0:29 - 0:33and made it possible for the cities
of Las Vegas and Phoenix -
0:33 - 0:35and Los Angeles to provide water
-
0:35 - 0:37for people who lived
in a really dry place. -
0:38 - 0:42In the 20th century,
we literally spent trillions of dollars -
0:42 - 0:45building infrastructure
to get water to our cities. -
0:45 - 0:49In terms of economic development,
it was a great investment. -
0:49 - 0:52But in the last decade,
we've seen the combined effects -
0:52 - 0:58of climate change, population growth
and competition for water resources -
0:58 - 1:01threaten these vital lifelines
and water resources. -
1:02 - 1:06This figure shows you the change
in the lake level of Lake Mead -
1:06 - 1:08that happened in the last 15 years.
-
1:08 - 1:11You can see starting around the year 2000,
-
1:11 - 1:13the lake level started to drop.
-
1:13 - 1:14And it was dropping at such a rate
-
1:14 - 1:18that it would have left the drinking water
intakes for Las Vegas high and dry. -
1:19 - 1:21The city became so concerned about this
-
1:22 - 1:26that they recently constructed
a new drinking water intake structure -
1:26 - 1:28that they referred to as the "Third Straw"
-
1:28 - 1:31to pull water water
out of the greater depths of the lake. -
1:32 - 1:35The challenges associated
with providing water to a modern city -
1:35 - 1:38are not restricted
to the American Southwest. -
1:38 - 1:43In the year 2007, the third largest
city in Australia, Brisbane, -
1:43 - 1:46came within 6 months
of running out of water. -
1:46 - 1:51A similar drama is playing out today
in Sáo Paulo, Brazil, -
1:51 - 1:52where the main reservoir for the city
-
1:52 - 1:55has gone from being
completely full in 2010, -
1:55 - 1:58to being nearly empty today
-
1:58 - 2:01as the city approaches
the 2016 Summer Olympics. -
2:02 - 2:05For those of us who are fortunate enough
-
2:05 - 2:07to live in one
of the world's great cities, -
2:07 - 2:10we've never truly experienced
the effects of a catastrophic drought. -
2:12 - 2:16We like to complain
about the navy showers we have to take. -
2:16 - 2:20We like our neighbors to see
our dirty cars and our brown lawns. -
2:20 - 2:23But we've never really faced
the prospect of turning on the tap -
2:24 - 2:25and having nothing come out.
-
2:26 - 2:29And that's because when things
have gotten bad in the past, -
2:29 - 2:32it's always been possible
to expand a reservoir -
2:32 - 2:34or dig a few more groundwater wells.
-
2:35 - 2:39Well, in a time when all
of the water resources are spoken for, -
2:39 - 2:42it's not going to be possible
to rely on this tried and true way -
2:42 - 2:45of providing ourselves with water.
-
2:46 - 2:49Some people think that we're going
to solve the urban water problem -
2:49 - 2:51by taking water from our rural neighbors.
-
2:52 - 2:58But that's an approach that's fraught
with political, legal and social dangers. -
2:58 - 3:02And even if we succeed in grabbing
the water from our rural neighbors, -
3:02 - 3:04we're just transferring
the problem to someone else -
3:04 - 3:07and there's a good chance
it will come back and bite us -
3:07 - 3:09in the form of higher food prices
-
3:09 - 3:13and damage to the aquatic ecosystems
that already rely upon that water. -
3:14 - 3:17I think that there's a better way
to solve our urban water crisis -
3:17 - 3:21and I think that's to open up
four new local sources of water -
3:22 - 3:23that I liken to faucets.
-
3:24 - 3:29If we can make smart investments
in these new sources of water -
3:29 - 3:30in the coming years,
-
3:30 - 3:32we can solve our urban water problem
-
3:32 - 3:35and decrease the likelihood
that we'll ever run across -
3:35 - 3:38the effects of a catastrophic drought.
-
3:39 - 3:40Now, if you told me 20 years ago
-
3:40 - 3:45that a modern city could exist
without a supply of imported water, -
3:46 - 3:49I probably would have dismissed you
as an unrealistic and uninformed dreamer. -
3:50 - 3:51But my own experiences
-
3:51 - 3:56working with some of the world's most
water-starved cities in the last decades -
3:56 - 4:00have shown me that we have
the technologies and the management skills -
4:00 - 4:03to actually transition away
from imported water, -
4:03 - 4:05and that's what I want
to tell you about tonight. -
4:05 - 4:10The first source of local water
supply that we need to develop -
4:10 - 4:12to solve our urban water problem
-
4:12 - 4:15will flow with the rainwater
that falls in our cities. -
4:16 - 4:18One of the great tragedies
of urban development -
4:18 - 4:21is that as our cities grew,
-
4:21 - 4:24we started covering all the surfaces
with concrete and asphalt. -
4:24 - 4:27And when we did that,
we had to build storm sewers -
4:27 - 4:29to get the water
that fell on the cities out -
4:29 - 4:30before it could cause flooding,
-
4:30 - 4:33and that's a waste
of a vital water resource. -
4:35 - 4:37Let me give you an example.
-
4:37 - 4:40This figure here shows you
the volume of water -
4:40 - 4:42that could be collected
in the city of San Jose -
4:42 - 4:46if they could harvest the stormwater
that fell within the city limits. -
4:47 - 4:51You can see from the intersection
of the blue line and the black dotted line -
4:52 - 4:56that if San Jose could just capture half
of the water that fell within the city, -
4:56 - 4:59they'd have enough water
to get them through an entire year. -
4:59 - 5:02Now, I know what some of you
are probably thinking. -
5:02 - 5:06"The answer to our problem
is to start building great big tanks -
5:06 - 5:09and attaching them
to the downspouts of our roof gutters, -
5:09 - 5:11rainwater harvesting."
-
5:11 - 5:14Now, that's an idea
that might work in some places. -
5:14 - 5:17But if you live in a place
where it mainly rains in the winter time -
5:17 - 5:19and most of the water demand
is in the summertime, -
5:19 - 5:23it's not a very cost-effective way
to solve a water problem. -
5:23 - 5:26And if you experience the effects
of a multiyear drought, -
5:26 - 5:28like California's currently experiencing,
-
5:28 - 5:32you just can't build a rainwater tank
that's big enough to solve your problem. -
5:32 - 5:35I think there's a lot more practical way
-
5:35 - 5:38to harvest the stormwater and
the rainwater that falls in our cities, -
5:38 - 5:42and that's to capture it
and let it percolate into the ground. -
5:43 - 5:47After all, many of our cities are sitting
on top of a natural water storage system -
5:47 - 5:50that can accommodate
huge volumes of water. -
5:50 - 5:55For example, historically,
Los Angeles has obtained -
5:55 - 5:58about a third of its water supply
from a massive aquifer -
5:58 - 6:00that underlies the San Fernando Valley.
-
6:00 - 6:03Now, when you look at the water
that comes off of your roof -
6:03 - 6:06and runs off of your lawn
and flows down the gutter, -
6:06 - 6:09you might say to yourself,
"Do I really want to drink that stuff?" -
6:09 - 6:12Well, the answer is
you don't want to drink it -
6:12 - 6:13until it's been treated a little bit.
-
6:13 - 6:16And so the challenge that we face
in urban water harvesting -
6:16 - 6:19is to capture the water, clean the water
-
6:19 - 6:21and get it underground.
-
6:21 - 6:24And that's exactly
what the city of Los Angeles is doing -
6:24 - 6:28with a new project that they're building
in Burbank, California. -
6:28 - 6:32This shows the stormwater park
that they're building -
6:32 - 6:37by hooking a series of stormwater
collection systems, or storm sewers, -
6:37 - 6:40and routing that water
into an abandoned gravel quarry. -
6:41 - 6:43The water that's captured in the quarry
-
6:43 - 6:45is slowly passed
through a man-made wetland, -
6:45 - 6:48and then it goes
into that ball field there -
6:48 - 6:50and percolates into the ground,
-
6:50 - 6:53recharging the drinking water
aquifer of the city. -
6:53 - 6:56And in the process
of passing through the wetland -
6:56 - 6:58and percolating through the ground,
-
6:58 - 7:01the water encounters microbes
that live on the surfaces of the plants -
7:01 - 7:03and the surfaces of the soil,
-
7:03 - 7:05and that purifies the water.
-
7:05 - 7:08And if the water's
still not clean enough to drink -
7:08 - 7:10after it's been through
this natural treatment process, -
7:10 - 7:12the city can treat it again
-
7:12 - 7:14when they pump if back out
of the groundwater aquifers -
7:14 - 7:17before they deliver it to people to drink.
-
7:17 - 7:22The second tap that we need to open up
to solve our urban water problem -
7:22 - 7:23will flow with the wastewater
-
7:23 - 7:26that comes out
of our sewage treatment plants. -
7:26 - 7:30Now, many of you are probably familiar
with the concept of recycled water. -
7:30 - 7:32You've probably seen signs like this
-
7:32 - 7:35that tell you that the shrubbery
and the highway median -
7:35 - 7:37and the local golf course
-
7:37 - 7:39is being watered with water
-
7:39 - 7:41that used to be
in a sewage treatment plant. -
7:42 - 7:45We've been doing this
for a couple of decades now. -
7:45 - 7:47But what we're learning
from our experience -
7:47 - 7:51is that this approach is much more
expensive that we expected it to be. -
7:51 - 7:54Because once we build
the first few water recycling systems -
7:54 - 7:56close to the sewage treatment plant,
-
7:56 - 7:59we have to build longer
and longer pipe networks -
7:59 - 8:01to get that water to where it needs to go.
-
8:01 - 8:04And that becomes prohibitive
in terms of cost. -
8:05 - 8:06What we're finding is
-
8:06 - 8:10that a much more cost-effective
and practical way of recycling wastewater -
8:10 - 8:12is to turn treated wastewater
into drinking water -
8:12 - 8:15through a two-step process.
-
8:16 - 8:19In the first step in this process
we pressurize the water -
8:19 - 8:22and pass it through
a reverse osmosis membrane: -
8:22 - 8:24a thin, permeable plastic membrane
-
8:24 - 8:27that allows water molecules
to pass through -
8:27 - 8:31but traps and retains the salts,
the viruses and the organic chemicals -
8:31 - 8:33that might be present in the wastewater.
-
8:34 - 8:36In the second step in the process,
-
8:36 - 8:39we add a small amount of hydrogen peroxide
-
8:39 - 8:41and shine ultraviolet light on the water.
-
8:41 - 8:44The ultraviolet light
cleaves the hydrogen peroxide -
8:44 - 8:47into two parts that are called
hydroxyl radicals, -
8:47 - 8:51and these hydroxyl radicals
are very potent forms of oxygen -
8:51 - 8:54that break down most organic chemicals.
-
8:55 - 8:59After the water's been
through this two-stage process, -
8:59 - 9:00it's safe to drink.
-
9:00 - 9:02(Laughter)
-
9:02 - 9:03I know,
-
9:03 - 9:05I've been studying recycled water
-
9:05 - 9:09using every measurement technique
known to modern science -
9:09 - 9:10for the past 15 years.
-
9:11 - 9:13We've detected some chemicals
-
9:13 - 9:15that can make it through
the first step in the process, -
9:15 - 9:17but by the time we get to the second step,
-
9:17 - 9:19the advanced oxidation process,
-
9:19 - 9:21we rarely see any chemicals present.
-
9:21 - 9:25And that's in stark contrast
to the taken-for-granted water supplies -
9:25 - 9:27that we regularly drink all the time.
-
9:28 - 9:31There's another way we can recycle water.
-
9:31 - 9:34This is an engineered treatment wetland
that we recently built -
9:34 - 9:37on the Santa Ana River
in Southern California. -
9:37 - 9:40The treatment wetland receives water
from a part of the Santa Ana River -
9:40 - 9:44that in the summertime consists
almost entirely of wastewater effluent -
9:44 - 9:47from cities like Riverside
and San Bernardino. -
9:47 - 9:50The water comes
into our treatment wetland, -
9:50 - 9:52it's exposed to sunlight and algae
-
9:52 - 9:54and those break down
the organic chemicals, -
9:54 - 9:58remove the nutrients
and inactivate the waterborne pathogens. -
9:58 - 10:00The water gets put back
in the Santa Ana River, -
10:00 - 10:03it flows down to Anaheim,
-
10:03 - 10:06gets taken out at Anaheim
and percolated into the ground, -
10:06 - 10:08and becomes the drinking water
of the city of Anaheim, -
10:08 - 10:12completing the trip
from the sewers of Riverside County -
10:12 - 10:15to the drinking water supply
of Orange County. -
10:17 - 10:20Now, you might think
that this idea of drinking wastewater -
10:20 - 10:24is some sort of futuristic fantasy
or not commonly done. -
10:24 - 10:28Well, in California, we already recycle
about 40 billion gallons a year -
10:28 - 10:31of wastewater through the two-stage
advanced treatment process -
10:31 - 10:33I was telling you about.
-
10:33 - 10:36That's enough water to be
the supply of about a million people -
10:36 - 10:38if it were their sole water supply.
-
10:39 - 10:43The third tap that we need to open up
will not be a tap at all, -
10:43 - 10:45it will be a kind of virtual tap,
-
10:45 - 10:48it will be the water conservation
that we manage to do. -
10:48 - 10:52And the place where we need to think
about water conservation is outdoors -
10:52 - 10:55because in California
and other modern American cities, -
10:55 - 10:58about half of our water use
happens outdoors. -
10:59 - 11:00In the current drought,
-
11:00 - 11:02we've seen that it's possible
-
11:02 - 11:05to have our lawns survive
and our plants survive -
11:05 - 11:07with about half as much water.
-
11:07 - 11:10So there's no need
to start painting concrete green -
11:10 - 11:13and putting in Astroturf
and buying cactuses. -
11:13 - 11:17We can have California-friendly
landscaping with soil moisture detectors -
11:17 - 11:19and smart irrigation controllers
-
11:19 - 11:22and have beautiful
green landscapes in our cities. -
11:24 - 11:26The fourth and final water tap
that we need to open up -
11:26 - 11:28to solve our urban water problem
-
11:28 - 11:31will flow with desalinated seawater.
-
11:31 - 11:35Now, I know what you probably heard
people say about seawater desalination. -
11:35 - 11:39"It's a great thing to do if you have
lots of oil, not a lot of water -
11:39 - 11:41and you don't care about climate change."
-
11:41 - 11:45Seawater desalination is energy-intensive
no matter how you slice it. -
11:46 - 11:49But that characterization
of seawater desalination -
11:49 - 11:51as being a nonstarter
is hopelessly out of date. -
11:51 - 11:54We've made tremendous progress
in seawater desalination -
11:54 - 11:56in the past two decades.
-
11:57 - 11:58This picture shows you
-
11:58 - 12:02the largest seawater desalination plant
in the Western hemisphere -
12:02 - 12:05that's currently being built
north of San Diego. -
12:06 - 12:08Compared to the seawater
desalination plant -
12:08 - 12:11that was built in
Santa Barbara 25 years ago, -
12:11 - 12:14this treatment plant
will use about half the energy -
12:14 - 12:16to produce a gallon of water.
-
12:16 - 12:20But just because seawater desalination
has become less energy-intensive, -
12:20 - 12:23doesn't mean we should start building
desalination plants everywhere. -
12:23 - 12:25Among the different choices we have,
-
12:25 - 12:27it's probably the most energy-intensive
-
12:27 - 12:29and potentially environmentally damaging
-
12:29 - 12:32of the options to create
a local water supply. -
12:33 - 12:34So there it is.
-
12:34 - 12:36With these four sources of water,
-
12:36 - 12:39we can move away
from our reliance on imported water. -
12:40 - 12:44Through reform in the way we landscape
our surfaces and our properties, -
12:44 - 12:47we can reduce outdoor water use
by about 50 percent, -
12:47 - 12:51thereby increasing
the water supply by 25 percent. -
12:52 - 12:54We can rely on water reuse,
-
12:54 - 12:56recycle the water
that makes it into the sewer, -
12:56 - 12:59thereby increasing
our water supply by 40 percent. -
13:00 - 13:03And we can make up the difference
through a combination -
13:03 - 13:06of stormwater harvesting
and seawater desalination. -
13:06 - 13:09Now, building a new water system
-
13:09 - 13:12that relies upon local sources
won't be easy. -
13:12 - 13:16But this is exactly the kind of challenge
that our grandparent's generation took on -
13:16 - 13:17and succeeded in,
-
13:17 - 13:20that allowed us to develop our cities
in the 20th century. -
13:21 - 13:24So, let's create a water supply
-
13:24 - 13:29that will be able
to withstand any of the challenges -
13:29 - 13:31that climate change throws at us
in the coming years. -
13:31 - 13:35Let's create a water supply
that uses local sources -
13:35 - 13:38and leaves more water
in the environment for fish and for food. -
13:39 - 13:44Let's create a water system that's
consistent with out environmental values. -
13:44 - 13:48And let's do it for our children
and our grandchildren -
13:48 - 13:51and let's tell them this is the system
-
13:51 - 13:54that they have to
take care of in the future -
13:54 - 13:57because it's our last chance
to create a new kind of water system. -
13:58 - 14:00Thank you very much for your attention.
-
14:00 - 14:01(Applause)
- Title:
- 4 ways we can avoid a catastrophic drought | David Sedlak | TEDxMarin
- Description:
-
more » « less
As the world's climate patterns continue to shift unpredictably, places where drinking water was once abundant may soon find reservoirs dry and groundwater aquifers depleted. In this talk, civil and environmental engineer David Sedlak shares four practical solutions to the ongoing urban water crisis. His goal: to shift our water supply towards new, local sources of water and create a system that is capable of withstanding any of the challenges climate change may throw at us in the coming years.
This talk was given at a TEDx event using the TED conference format but independently organized by a local community. Learn more at http://ted.com/tedx
- Video Language:
- English
- Team:
closed TED
- Project:
- TEDxTalks
- Duration:
- 14:12
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