Friday, May 3, 2019

Ask Me Anything

This week on Facebook I asked my friends to ask my anything about climate change. I was pleased to get some really interesting questions! One friend told me I should share the product of this exercise somehow. So here it is.

My post:
I don't know why but it suddenly occurred to me that some of you might have questions about climate change that you are afraid to ask. I don't have all the answers, but I've been working or lurking in this field for 9 yrs* and might be able to dig up answers where I don't have them. So-- please -- ask me anything about climate change! What do you want to know?
(* I later realized it's been 10 years and spare change, but who's counting.)

Photo by cogdogblog © CC BY 2.0


Q1. Have we really reached the “can’t turn back now” stage?
And another related question: How close is earth to the tipping point?

Q2. What is one small item I should stock in my emergency kit that I may have forgotten? (A question from a friend in the SF Bay Area.)

Q3. Is it bad that I’m rooting for a little sea level rise to wash away the ugly condos between our house and the Hudson River?

Q4. What is one concrete activist goal we could get involved to help make happen, right now?

Q5. Is massive reforestation a viable means of stopping global warming? I've seen these projects that plant millions of trees in a day...

Q6. Regarding the dairy (not meat) side of things: what are the differing effects of grass-fed vs. conventional dairy and what effect will the increased farming of cashews and almonds (as dairy alternatives) have on the environment? (Note: I'm parsing this as a pasture versus feedlot versus nut tree question.)

Q7. What are your thoughts on Project Drawdown's effort to comprehensively quantify greenhouse gas mitigation measures?

Q8. How much of a difference does individual water consumption for showers (not stuff like lawn watering) make in California? I've heard lots of people fretting about how we need to take shorter showers due to droughts, but I'm personally not sure how much difference my few gallons of shower water make, compared to people are still growing almonds and rice in climates that cannot support it...

Q9. What's a scientific answer to whether veganism & vegetarianism are better for the planet?

Q10. The San Francisco MTC is planning for a 3 foot sea level rise by 2050: how likely is 3 feet to come sooner? (I'm reading this as "how likely is San Francisco to have higher than three feet sea level rise by 2050?")

Q11. What do you think poses the greatest existential threat, climate change or the singularity?

Q12. How long till thermohaline circulation stops?

Q13. What's the best estimate for how much methane is held as hydrates that are at risk of melting?



Q1. Have we really reached the “can’t turn back now” stage? 

And: How close is earth to the tipping point?

First question:

Yes and no. Yes, in that there is no "stopping" climate change, that train has left the station. We didn't realize how much heat was being absorbed by the oceans, nor how long it looks like it might take the oceans to return to the temperature we are used to. The trajectory in which Earth returns to pre-industrial temperature ranges is measured in many hundreds of years, maybe a thousand years, taking into account the slow way the ocean warms and cools. So, there is no "turning back" in the sense of we have departed from the historical norms for the foreseeable future. However, the Earth might return to balance someday if we do everything we can to SLOW climate change. If we don't do anything, Earth will become Venus. My understanding is that the point at which Earth will inevitably become Venus has not been reached yet.

Awesome short (7 minute) video by expert climate communicator Katharine Hayhoe on this question "It's too late to do anything about climate change.... right?" - https://www.youtube.com/watch?v=bv7zFAdZ6LI

Second question: 

Good question! See my answer to a similar question above. We don't know how close we are to making it inevitable that Earth becomes Venus, but all the tipping points in nature that scientists have pointed to as signals of doom are happening faster than expected.

Also, the tipping point that is rarely talked about that you might want to learn about is ocean acidification. We can't fight it, and when the oceans acidify to a certain threshold -- that's it. As one scientist put it (privately) to me: "game over."

A 12 minute video by the Cal Academy on biodiversity and ocean acidification that might help give you a grasp on the problem: https://www.youtube.com/watch?v=GL7qJYKzcsk




Q2What is one small item I should stock in my emergency kit that I may have forgotten?

For Bay Area people something I did for my emergency kit was get a geological map showing me where the nearest bedrock area is to my home. I think the Bay Area is more at risk of catastrophic earthquake than catastrophic extreme events from climate change. Things will happen, but it will take the shape of Highway 37 being rendered inaccessible for long periods of time, downtown SF being kayak-able during a King Tide, maybe an extra super hot day here and there, but not hurricanes and storm surge or wildfire that takes out all of Oakland or something like that.

Follow-up question from another Bay Area friend: How does one use bedrock location information in an emergency? Is it where to go to avoid aftershocks?

Bingo

Also it's not prone to subduction or liquefaction. So much of the Bay Area is built on fill, you really should know if you are living on fill or bedrock. Check it out.

I can't remember how I dug up the map I put in my emergency kit - it's been a few years - but this looks promising: 
https://earthquake.usgs.gov/hazards/urban/sfbay/soiltype/



Q3Is it bad that I’m rooting for a little sea level rise to wash away the ugly condos between our house and the Hudson River?

You are entitled to your fantasies! I like the idea of people kayaking around downtown San Francisco. Highway 1 between SF and the airport will be a kayak park someday, in one engineering firm's vision in a design competition held by BCDC in 2009. 
http://www.aiacc.org/.../rising-tides-international.../




Q4. What is one concrete activist goal we could get involved to help make happen, right now? 

Something that surprised me that I learned last week in a presentation on voter behavior at the National Adaptation Forum was that voters who care about the environment tend to NOT VOTE. So right now my answer for you is -- make sure you are registered and tell your friends to get registered or update their registration to vote, and educate yourself on how things on the ballot might affect climate change and how people on the ballot talk about climate change. Fight for access to the vote for disenfranchised people, fight to make voting day a holiday, fight attempts to roll back access to the vote. Teach your kids basic civics (I expect you do). Make voting a part of your core values and tell your friends why you care about it. I'm also hearing from climate scientists that VOTE is their #1 recommended action for people to take if they are scared about climate change.

This friend wanted to know what else she could do...

My other suggestions are along the same lines of civic activism -- let your elected officials know that you support climate action, send them thank you notes when they take unpopular stands on climate change, and if you know anybody living in places dominated by politicians who claim to be climate skeptics tell them to do the same. If the people lead the leaders will follow, etc.

Also, in my humble opinion, fighting income inequality and trying to establish a universal basic income will do a f*-load more for vulnerable populations in terms of giving them options to make good choices for themselves than any new-fangled technology (or old-fangled technology). Yes we need to upgrade and decarbonize our infrastructure but people need to be empowered to get out of harm's way.

She added: I wasn't thinking about technology so much as about policies like the carbon fee proposed in this book: Being the Change by Peter Kalmus

I follow Peter Kalmus on Twitter, but I haven't read his book. What does he propose in terms of a carbon fee? I know that many smart people talk about the need for a carbon fee or tax, some say it's inevitable. If we "internalized the externalities," or baked into the price of things their actual cost including the cost to the environment, it would give the right price signals for a less climate-changey future. It's just not at all politically viable in the U.S. right now. So companies need to impose this fee on themselves to give the right signals to the consumer. And if companies did bake the cost to the environment into their prices, the shock to low-income people would be terrible. So even if companies were inclined to do this, it would need to be done with some public entity providing relief to the worst off, or it would effectively be a regressive tax. If we had decent, affordable public transit in the U.S. it wouldn't be so bad, but imagine if all the non-rich people suddenly couldn't put gas in their cars.

She replied: I'll have to go back and read his proposal but I thought it made sense. He proposed a carbon fee which would be redistributed to citizens as a dividend, so that it would not function as a regressive tax.

It's a funny thing what working in government does to your ability to have faith in government to do something that complicated without screwing over poor people & immigrants somehow. But yeah, in theory, it sounds like a good plan.



Q5Is massive reforestation a viable means of stopping global warming? I've seen these projects that plant millions of trees in a day...

Good question. (1) "Stopping" global warming isn't an option anymore, sadly. (2) Planting trees can help, depending on where they are planted, what kind of tree, and what kind of maintenance support there is. It's an expensive fix but it is the only geoengineering measure that removes CO2 without creating new uncertainties and disruption. (3) For most of the Earth the superior option is restoring rangeland/prairie and encouraging kelp farming. Resources on that topic linked here: https://pacificadaptation.blogspot.com/2019/02/grasslands-kelp-trees-my-parking-lot-of.html



Q6. Regarding the dairy (not meat) side of things: what are the differing effects of grass-fed vs. conventional dairy and what effect will the increased farming of cashews and almonds (as dairy alternatives) have on the environment? (Note: I'm parsing this as a pasture versus feedlot versus nut tree question.)

You are listening to the sound of my head silently imploding and exploding with ideas of how to respond to your question. My main question when it comes to ag is how is the farmer using water, not what is the carbon footprint of the product. That is my California bias. So you've got the water question and the carbon footprint question. Your farmer might do great managing water and replenishing the groundwater and keeping the water footprint low, and then manage the cattle waste poorly so the farm is a big methane emitter. "Permanent" crops like nut trees have their water impact and their carbon footprint, more the former than the latter (in my bystander understanding), but if lucrative nut trees replace open rangeland (cattle pastures, for example), that has a carbon footprint. Then you've got the question of what happens if we regulate dairy farmers out of existence in the U.S. and thereby offshore the water and carbon impacts by buying dairy from less-regulated places. And you probably know that most of California's almonds are sold to China for almond milk, so that's how those natural resources come back into California, as cash, not a replacement for dairy (yet). OVERALL my thoughts on both dairy and nut tree farming boil down to the importance of getting farmers good climate info in a timely manner. There's nothing we can do about the hunger for almond milk in China but we can incent good water management practices (remote sensor-driven irrigation and the like) and help decarbonize farm infrastructure (which the CA Air Resources Board is working on in the San Joaquin Valley). I have other thoughts but I'll leave these thoughts here and see if my brain spits out anything more cogent.

Grazing can be done really well, in a way that fosters land restoration and native plant growth, and it can be done very destructively. Feedlot farming can do great on the greenhouse gas mitigation front and do horrible things to the land and water around it. There are good reasons to do both grazing and feedlot approaches, it's not a simple equation. My go-to orgs for these questions are CalCAN (http://calclimateag.org/) and...

...CAFF (https://www.caff.org/programs/sustainability/)

Also the problem is cow burps not farts, as you may know. People are looking at this seaweed Asparagopsis taxiformis as a possible solution. https://www.technologyreview.com/.../how-seaweed-could.../



Q7. What are your thoughts on Project Drawdown's effort to comprehensively quantify greenhouse gas mitigation measures?

Yes, Project Drawdown has a good list. The organization was created by people from the "Green MBA" program in the Presidio. They favor innovation and market solutions, so that's a bias to be aware of. But I really like Jon Foley, who left the Cal Academy to head up Project Drawdown. He might make it a real organization that does more than publish one book.



Q8. How much of a difference does individual water consumption for showers (not stuff like lawn watering) make in California? I've heard lots of people fretting about how we need to take shorter showers due to droughts, but I'm personally not sure how much difference my few gallons of shower water make, compared to people are still growing almonds and rice in climates that cannot support it...

It's a question of return on investment. When irrigating crops, that water comes back to ground water directly, has benefits for birds & other wildlife, and also translates to $$ for the California economy. So it's a relatively good investment of water compared to lawns (if only grass cuttings could be sold) and extra long showers (the water from which has to be treated, which is an additional cost). There is only so much fresh water, as I'm sure you know, so we need to invest every drop as wisely as possible. The WORST is the way we use treated drinking water to flush toilets. Toilets should be flushed with grey water & at low flow/high efficiency. In the future that is going to have to be mandated. 

Confession: I have a 5 min shower timer and I have never used it. I shower every other day so I say I get a few minutes extra. I also can't deal with the smell & etc. from letting urine sit in my toilet, so I flush every time. I'm no poster child. We should all take shorter/fewer showers and "if it's yellow let it mellow." Also whoever can should collect rainwater in barrels to use in their home and if you have land keep as much of it permeable (not paved) as possible.

Another friend responded: My understanding is it's much less wasteful, gallon for gallon, to use water if it eventually goes down the drain, because that will end up at the water treatment plant for more uses before out to sea. So it's good to cut down on car-washing and lawn-watering, but baths/showers, less so.

Car washing and lawn watering THEORETICALLY recharges ground water, so it isn't wasted water. However because we have such impermeable surfaces around our living areas in cities that car/lawn water tends not to spread and sink but go into drainage pipes that take it right to the sea, untreated. So it is more polluting of the sea than water that goes down the drain. But if you had a nice place with bioswales and other features that slowed, spread, and sunk the car/lawn water, then you are doing the local groundwater a favor, returning tap water to the land.

A really interesting project is trying to capture water that goes down storm drains (like car/lawn water), treating it, and returning it to the tap rather than letting it run to the sea. Los Angeles could supply all of its water needs from storm water if it could capture the water in storm drains (from rain in the mountains) -- so I believe LA is trying out some "internet of water" sensors to capture and store storm drain runoff during and after storms. Someday all the storm drain water might need to be captured and at least turned into grey water for use in toilets and other appropriate grey water uses.



Q9. What's a scientific answer to whether veganism & vegetarianism are better for the planet?

Any food can be healthy or not-- for you and the planet-- including meat. I'm just talking about environmental/physical health here (not ethical health, which is between you and your gods and ancestors, not a matter of public policy). Science doesn't say "go vegetarian" or "go vegan" - what it does say is it's good to reduce the meat in your diet, for lots of reasons. I just learned that among marine animals farmed mussels have the lowest carbon footprint/g protein, which surprised me. I would have guessed wild salmon. Poultry is the lowest of land animals (link attached to where I got that). Now, if you are more concerned about pollution from farming, that goes to the farming practice/ size of enterprise more than the type of meat, I think. Another surprising thing I heard from an ag researcher recently is that small family farms that get big are the WORST for bad environmental practices. Big farms that started out big are prepared for and responsive to regulations. Small farms that get big are not. Anyway, the impact of our food choices on the planet is a very important, complex question. Source for GHG per gram of protein by food type - https://ourworldindata.org/.../greenhouse-gas-emissions...

More on that, if you can get institutional access to a behind-a-paywall article - https://esajournals.onlinelibrary.wiley.com/.../fee.1822

And the source for the farmed mussels being lowest in carbon footprint/g protein - http://seafoodco2.dal.ca/

Specifically this graph: 
https://twitter.com/SarahEMyhre/status/1123294443862257664

This relevant article just came out yesterday [April 30, 2019]. It has a lot of the same info I linked to above but put in a very stylish and user-friendly layout (if you have access to the NYT) - https://www.nytimes.com/.../climate-change-food-eating...



Q10. The San Francisco MTC is planning for a 3 foot sea level rise by 2050: how likely is 3 feet to come sooner? (I'm reading this as "how much sea level rise is San Francisco going to see by 2050?")

MTC is using a controversial projection that uses a probabilistic model (if they are using the California state guidance). They are hedging on the side of caution, using a high estimate for the worst case scenario. Personally, I think it's a good idea. The head of climate change for SF PUC is not so sure it's a good idea to overengineer at this point. The high estimate came from a paper on a particular ice shelf melting in Antarctica (DeConto and Pollard 2016). That ice shelf paper used ONE model of climate change projections and ONE model of ice behavior. Since that paper came out the scientists have done more work and gotten peer feedback and moderated their estimates. I'm attaching the guidance that I believe MTC is basing their planning on: http://www.opc.ca.gov/.../rising-seas-in-california-an...

Here's the DeConto and Pollard (2016) paper that put everyone's neck hairs on end: http://www.documentcloud.org/.../2823837-DeConto-Pollard...

Here's an article on how DeConto and Pollard stepped back their alarming prediction: https://www.theatlantic.com/.../sea-level-rise.../579478/

And on the other hand, this article just came out - https://www.independent.co.uk/.../ross-ice-shelf...

The long and the short is that of all the climate change-driven models out there the ones modeling ice behavior are the newest and least tested. We are building blind at this point, hoping we don't under-engineer.

My friend replied: 16 feet!! That would be bad for countries with large coastal populations and major port cities ... and maybe advantageous to those that don't. Is there anything unclassified that deals with the geopolitical scenarios that might result?

Low-lying island nations have been pointing out the existential threat posed to them by sea level rise for over a decade now. I believe the Maldives has purchased land and is beginning the move process. Indonesia is in the news lately because they are starting the process of moving their capital from Java, which is sinking.There is lots of open discussion about climate refugees from future sea level rise. Bangladesh is a particular concern. All the major populated river deltas in Southeast Asia are particular concerns. The U.S. Naval Atlantic Fleet is run out of Norfolk, VA, that has been preparing for sea level rise for a long time now (though it isn't discussed very clearly/openly as a climate change problem). Turns out sea level rise isn't like filling a bathtub, sea levels rise differently in different places, and Virginia is like ground zero for the fastest sea level rise on any U.S. coast. So our military has had it on its radar for a long time. Pick a location and Google it plus "sea level rise" and you'll find lots out there written about geopolitical implications.



Q11. What do you think poses the greatest existential threat, climate change or the singularity?

I'm guessing you are joking but in case you aren't I don't know, since I don't really believe in the singularity, but just cuz I don't believe in it doesn't mean it won't end the world

My friend conceded: I've been reading about the singularity and becoming convinced it will happen in some form or another, though I don't think we really know how it will happen or when. Climate change is a lot more predictable.



Q12. How long till thermohaline circulation stops?

Oh god I hope not soon, jeez. The impact of climate change on ocean dynamics is almost as little understood as the melting of land ice at the poles (compared to impact on temperature and land processes associated with it). For sure people are studying it but I haven't run across anything that projects a timeline on the thermohaline.

This is a nice juicy link-rich article on the topic from last year, which should give you some idea of how much we know about this problem https://insideclimatenews.org/.../atlantic-ocean...



Q13. What's the best estimate for how much methane is held as hydrates that are at risk of melting? (Note: hydrates = ice crystals containing another element or compound. Methane hydrates = ice crystals containing methane molecules. See the U.S. Department of Energy methane hydrate explainer, it has a good graphic.)

First, I'm not an oceanographer or permafrost specialist, so I wouldn't know if there was new hot research on this topic emerging. I follow a lot of ocean and cryosphere/polar scientists on Twitter (it's a special interest of mine, the loss of ice-based animals and cultures), but I don't know if anyone I follow is researching under-ocean/permafrost-trapped methane at risk of release through melting. I'm sure I've seen something about the estimated amount of methane in play here (and it's a lot, like a lot a lot) but the real question is what is the real probability of it being released, which nobody knows. What I *do* know is the ocean science course I took (Intro to the Marine Environment at Laney College, taught by a guy who cared a lot about students understanding climate change impacts on the ocean) thought that the hype about the methane at the bottom of the ocean being released and causing catastrophic sudden climate change was waaaaay overblown. He believed it was NOT the thing we should be worrying about. Now, the methane being released from permafrost is another thing, and I just saw a new report show up on my radar yesterday about this. Let me go dig it out of the internet. -- BY THE WAY FOR THE UNINITIATED -- Methane is a super-charged greenhouse gas. Although it dissipates much faster than CO2, it is far more dangerous in terms of its heat-trapping potential. It's roughly 30 times more dangerous than CO2.

OK here it is, an opinion piece that came out in Nature on Tuesday [April 30, 2019] about what research is needed on the question of greenhouse gases/permafrost. It includes an estimate of how much carbon is held in permafrost as compared to the atmosphere (twice as much in permafrost). https://www.nature.com/articles/d41586-019-01313-4

And here is a Twitter thread recommended by my favorite paleoecologist on permafrost - doesn't say much on the question of methane but it explains the melting process we are seeing in the tundra - https://twitter.com/queenofpeat/status/1123561998820806656
I haven't read this yet but it looks competently written - the source has been cited by people I deem credible - https://www.seeker.com/.../heres-what-scientists-know...

MORE ON METHANE - I didn't remember that it is much more potent initially - 80+ times more potent than CO2 after release - https://www.edf.org/.../methane-other-important...

Thursday, May 2, 2019

Head in the Clouds: The Dream of Harvesting Water from Fog (the re-post)

The following was published June 8, 2017, on the WWF ClimatePrep blog (climateprep.org) -- which now appears to have gone defunct. You can still see the original on Archive.org. See my blog post about the writing of this article here.
-

FogQuest volunteer Chris Fogliatti, San Francisco, California, 2016.
Photo: Hangar 1 Vodka.

The fog comes/ on little cat feet, wrote Carl Sandburg. We here in the San Francisco Bay Area follow it on Twitter under the name Karl the Fog. It seems like a sentient being that winters on the water and summers on the land.It contributes a gentle touch to the atmosphere, keeping coastal plants and animals living within their narrow comfort zone. It is the natural air conditioning for coast-siders. It is the preferred summer water source for Sequoia sempervirens—coast redwood—the world’s tallest
tree (Limm et al. 2009). Throughout history fog has also been tapped to generate drinking water, such as the harvesting of fog-drip from trees using cisterns in the Canary Islands.

There are also many varied modern efforts at tapping fog water for human use. One example with mixed results began in 1985 in Canada. An atmospheric physicist at Environment Canada named Dr. Robert Schemenauer was approached by an international aid agency with this question: can fog be used for water supply in the desert in Chile? His “proof of technology” project resulted in the world's first large operational fog collection project being built at El Tofo, Chile. It served the nearby coastal community of Chungungo from 1992 until 2003. The project delivered 15,000 liters of fog water per day on average, some days delivering over 100,000 liters. The size of the community doubled as a result. After 10 years of successful water production, the community leaders abandoned the fog collectors, eventually building their own desalination plant. The caretaker for their 100 large fog collectors was let go, and the collectors decayed. In an article about this shift away from fog collection, a representative of the aid agency that began this project, the International Development Research Centre, reflected: “people have certain visions of what it means to be developed, and one of them is that water should be brought to you by the state, and you should never have to think about it.”

Although the Chungungo project did not continue, Dr. Schemenauer, one of the founders of modern fog collection, persists in his work helping establish fog-water systems for isolated high-country communities in the developing world through FogQuest, the NGO he co-founded in 2000. He makes community engagement a priority in his projects.

Access to drinkable water is a growing problem for communities across the world. When the right conditions exist, fog collectors in Guatemala allow villagers access to cheap water that is available immediately. Photo: Girl and baby donkey, Tojquia, Guatemala, 2008. FogQuest/Melissa Rosato. Used with permission. (Source.)
FogQuest’s 1 m2 “standard fog catcher” uses a special polyethylene mesh (called Raschel mesh) that is both effective at capturing fog droplets and is wind-resistant. One of the longest-running (since 2006) and successful FogQuest collection arrays is located in Tojquia, Guatemala, where 35 large (40 m2) collectors trap 7,000 liters (1,849 gallons) of water a day during the winter dry season (FogQuest 2017). Dr. Schemenauer points to that project as having a “bright future” in part because of its robust maintenance regime. Other current projects include other sites in the highlands of Chile (the Atacama Desert Center and Falda Verde), Ethiopia, Nepal, Eritrea, and Morocco (read a 2016 update about this project: Fog harvesting brings water to Morocco’s rural communities, which combines FogQuest collectors and a newer German design created for high wind environments).

Fog collection pilot projects have also been undertaken by many other institutions around the world, including through the University of South Africa. The South African collectors were adapted for local weather conditions: “instead of having one flat vertical panel, we now put three panels (30 meach) in the form of a triangle […] provid[ing] stability to the system during storms,” per a 2013 report.

What is fog and how will climate change affect it?

For most purposes, fog is a cloud that touches the ground. There are different types of fog. One way some types form when warm, moist air passes over a cool surface, causing water vapor to condense on tiny particles (called condensation nuclei). But historically the presence of fog has been measured at airports with regards to navigation (officially, “fog” is present when visibility is less than 1 km), so fog scientists trying to understand how climate change and other factors are affecting fog in, for example, coast redwood habitat have to interpolate trends from airport data which aren’t tailored to their purposes. Fog also doesn’t collect as water in uniform ways: wind and the composition of droplets change how it gathers on collectors. The science of determining the optimal places for fog collection and the optimal collector construction is still being developed through modeling and trial and error.

The question of how climate change is affecting fog is highly unresolved, and probably will be for some time. Some researchers speculate it is declining (see the Johnstone and Dawson 2010 study that shows a 33% decline in summertime fog hours off the coast of California), some that it is intensifying. In any case, the atmospheric, oceanic, and terrestrial systems that produce fog are highly variable and undergoing changes: their future interactions can’t be projected with much certainty.

Ideal conditions for a bumper crop of fog

For the best water production, fog collectors should be constructed perpendicular to the prevailing wind. Drops will form on the mesh and then fall into a trough that is angled to fill a tank. On average, a fog collector of the sort built by FogQuest will produce 3-15 liters (about 1-4 gallons) per day per m2. If the fog event is especially productive, the collector may yield 50 liters (about 13 gallons) per m2 in one day. (Source.)

Fog water harvesting schematic.
Adapted from article by Poulpeaction.org
"Captation d’eau de brouillard"/FogQuest.
 

You can’t get these results by hoisting up a fog collector in any back yard. Fog collectors are most productive in high mountains very close to the ocean. One report from South Africa specifies the following requirements for a viable fog collection project in local conditions:
  • It must be in an area where fog events are frequent year-round and last several hours.
  • It must be at least 1,000 m above sea level and receive at least 90 days of fog precipitation per year.
  • The water content of the fog must be high.
  • There must be wind with the fog to ensure a minimum volume of air blown through collectors.
The fog collector mesh has a 10 year life span. For a large collector of 40 m2 the cost of the standard fog collector mesh and the poles and cables that comprise the frame is between $1,000-1,500 USD. The structure on which it is suspended is flexible in wind storms and earthquakes, so it is relatively easy to put back into place after a natural disturbance. There is no permanent infrastructure required (e.g., no concrete slabs necessary, no electrical cables for pumps): maintenance is relatively cheap, consisting of replacing worn out mesh or damaged pipes, cables, troughs, or water containers. Although it is relatively cheap, a commitment must be made to maintenance, as Chungungo exemplified.


To get ahead of that obstacle, Dr. Schemenauer recommends prioritizing connecting the local people to the project:  “The success of projects depends on having people in the community involved right from the beginning, before you put a fog collector up.”

Dr. Schemenauer emphasizes the importance of involving women and children—the whole community, showing them the concept and starting with a test structure (a 1x1m Standard Fog Collector, for example) as a demonstration. If materials are scarce, a simple mosquito net can work for a proof-of-concept demonstration. The initial construction of fog collectors is relatively easy compared to long-term maintenance, so the sustainability of a fog collector project hinges on local buy-in.

Your new California coastal utility: CalFog?

As romantic as it would be, fog is not likely to ever be a viable source of new water for human consumption in cities, especially not in the developed world with its high-demand user habits. Ultimately fog water requires too much effort and expense for the quantity of water needed. The lifestyle of urban water users would have to change and the cost of fresh water from inland sources would have to skyrocket (and/or quality would have to plummet) to make a utility-scale fog collection project make sense for a city.

In isolated coastal areas where the two main alternative water sources are fog collection and desalination (as in Chungungo), the people who run the desalination plants are unlikely to be equipped to operate a hybrid system integrating both sources: it will be one or the other. If commitment to local maintenance is already a problem, the relative unreliability of fog water compared to desalination might be a deciding factor. Also, if a community has never tried fog harvesting, it will face the problem of any new public infrastructure project (e.g., the questions associated with building water storage basins, how to support collection and maintenance, etc.).

The optimal place for fog water collection for human water needs is a high mountain/ coastal community with a small, isolated population with low water demand, as in the examples above.

The next most cost-effective use might be for agriculture such is in Falda Verde near Chañaral, Chile, where fog water supports a commercial aloe vera plantation through drip irrigation (Carter et al. 2007). The project there is aiming at integrating a fog-fed fish farm, the water from which would add fertilizer to the plantation (aquaponics), according to Dr. Daniel Fernandez, who visited the site in March 2017. Majada Blanca, Chile, has an experimental olive farm fed exclusively with fog water (with a goal of selling fog-fed olive oil to advertise the technique). Its first harvest took place in May 2017.

FogQuest volunteer Chris Fogliatti suggested another drip irrigation system might take the form of fog-collecting mesh installed around an individual native tree sapling. He suggests this might be a useful approach to watering landscaping at high altitudes along the coast; fog water could also be used to feed hydroponic operations producing California’s newly legalized cash crop, marijuana.

Is it safe to drink fog water?

Fog water tends to be of high quality, although it should be subjected to regular testing and filtration if it is being consumed by humans.

There is a concern about bioaccumulation of mercury in coastal animals due to fog exposure. According to Peter Weiss-Penzias at UC Santa Cruz, it appears that mercury levels, on average, are ten times higher in coastal mountain lion whiskers than those found inland. The fog these animals live in can be 20 times more polluted with mercury than rain. This is not a concern for humans, since the amounts are too small to affect humans and we don’t consume anything that consumes fog, but it might be a concern for the long-term health of animals in coastal habitats.

“Fodka” and other adventures with fog

In 2016 the San Francisco Bay Area distiller Hangar 1 debuted Fog Point, a new vodka using local fog water—or fodka (see a 30-second 2016 Time video about it). All proceeds are committed to the charitable mission of FogQuest and fog science. Chile has a “Fog Catcher” (Atrapaniebla) beer, made with only fog water, brewed in one of the driest places in the world, the Atacama Desert (read a 2015 BBC story about the brewery and the research project associated with it).

Projects bringing together art and fog collection are proliferating around the world, such as the Fog Garden (“Jardin de Niebla”) project by Pilar Cereceda and Rodrigo Perez de Arce, piloted in 2008 in Alto Patache in Chile’s Atacama Desert. It was unfortunately abandoned due to lack of funding after the Santiago earthquake in 2010.

The future of fog

Johnstone and Dawson’s 2010 study illustrating a decline in California’s coastal fog has been widely discussed and questioned. Meanwhile, over the past ten years Dr. Daniel Fernandez says coastal fog in Chile has been in decline, with a more pronounced drop than what has been observed in California, but the long-term trends aren’t clear. It might be connected to the Pacific Decadal Oscillation, or a regional effect. Presuming the fog stays with us, our understanding of how best to utilize it as a natural resource will continue to expand, thanks to the many thoughtful people who keep their heads in the clouds.

Standard Fog Collector (1 m x 1 m, mounted 2 m above the ground),
Glen Deven Ranch, California.
Used by permission. Photo: Dan Fernandez
Many thanks to those who contributed to this research for this article: Dr. Daniel Fernandez (Cal State Monterey Bay), Bill Fox (Center for Art and Environment, Nevada Museum of Art), Dr. Robert Schemenauer (FogQuest), and Chris Fogliatti (FogQuest).  

Read More

FogQuest – The modern pioneer in fog collection for water supply in isolated communities in the developing world, an all-volunteer NGO where 90% of funds received from donors and foundations is spent directly on fog-water projects.

The CloudFisher by Aqualonis – A newer design of fog collector designed for high winds. It is more expensive at the outset but intended to be cheaper to maintain than the Raschel mesh fog collectors. Its comparative efficiency in producing water is still being tested. A study in 2014-2015 (Mount Boutmezguida, Morocco) showed the CloudFisher mesh to be more productive (see results table on p. 20-21).


Warka with photovoltaic illumination (2017).
Photo: Warka Water.
Warka Water – A project by designer Arturo Vittori (see the most recent updates on Facebook). This fog collector, still in the pilot stage, is cylindrical, designed to resemble a tree (the warka fig tree), and made at least in part using locally sourced natural materials (bamboo, hemp, and bio-plastic). It is being piloted in Italy, with the target destination of villages in the NE Ethiopian high plateau. The current model (3.7) includes photovoltaic illumination.

Device pulls water from dry air, powered only by the sun (April 2017) – Scientists at the Massachusetts Institute of Technology and UC Berkeley have built a device that can “pull liters of water out of the air each day in conditions as low as 20 percent humidity.”

The California fog collection story in a 25-minute video by Al-Jazeera’s “TechKnow” (April 2017), featuring an interview with fog scientist Dr. Daniel Fernandez, California State University Monterey Bay.

Want to make your own fog collector?

Bayside Fog Collectors will be the small-purchaser distributor for the company that produces Raschel mesh– Marienberg– starting in late 2017, along with other products for people who want to make their own or buy a custom-built backyard fog collector.

Fog research resources

The International Fog and Dew Association – founded at the 7th International Conference on Fog, Fog Collection and Dew held in Poland in 2016. The next conference is expected to be in Taiwan in 2019 and in the U.S. in 2022.

Fog Research: Network and Sites – a new fog StoryMap designed to be a repository for photographs and data from an international network of fog researchers, managed by USGS fog scientist Dr. Alicia Torregrosa, currently featuring research projects in the U.S. (California), Namibia, and Chile. Dr. Torregrosa is also the convener of a weekly webinar series for fog researchers, hosted by the Coastal Fog Online Group, part of the Pacific Coastal Fog Project.

The Summen Project – a $1.75 million, three-year study underway on the U.S. West Coast to study the relationships between fog, climate change, redwoods, and human activities. Read about the project’s launch: Researchers Eye Foggy Link Between Redwoods, Climate Change (2016).

Story Maps: A Rising Star of Climate Change Communication (the re-post)

The following was published April 10, 2017, on the WWF ClimatePrep blog (climateprep.org) -- which now appears to have gone defunct. You can still see the original on Archive.org. See my blog post about the writing of this article here.
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Climate change information can usually be summarized in three words: boring bad news. Journalists try to remedy this with sensationalism, such as with the infamous “Obituary: Great Barrier Reef (25 Million BC-2016)” (Oct 11, 2016, by R. Jacobsen).  This headline angered ocean scientists and climate change communication specialists alike because it was non-factual, and might make otherwise action-oriented people give up: if it’s too late, why bother?

On the other hand, those trying to communicate nuanced, balanced climate change information can skew to the dry side of things. A 1,552-page carefully balanced report on climate change like the 2013 IPCC AR5 science volume is not going to engage the public.

So, how do you find the sweet spot between the 60-point-font doomsday headline and the impenetrable thesis with a thousand citations?

Enter: the Story Map.

Image is a screengrab from the 2017 Story Map “Climate Migrants,” by the Esri Story Maps Team,
accessible at
http://storymaps.esri.com/stories/2017/climate-migrants/index.html

Setting stories in a geospatial, multimedia context

Story Maps are a suite of applications created by the mapping software company Esri (founded as Environmental Systems Research Institute, purveyor of the ArcGIS map-creating software) that help people tell stories online using maps combined with multimedia elements. Story Maps differ from other online interactive maps by presenting a narrative, combining geographic information system (GIS) data with images, videos, and web links. For example, any feature on an online map can be linked to a pop-up window that describes the feature in greater detail. It engages users immediately, and then gives them the opportunity to self-navigate to deeper layers of information.

The father of Story Maps at Esri, Allen Carroll, came up with the idea during his 27-year tenure as National Geographic ‘s Chief Cartographer, calling them “geostories.” However, lacking the technical support he needed to develop the idea at NatGeo, he joined Esri in 2010 and began developing Story Maps. They began as a variety of templates designed by his team to support different kinds of narratives. In 2011 these templates became web applications available for free on the Esri website. The applications are fully customizable, and the best examples submitted to Esri are featured in the Story Maps Gallery. To create your own Story Map you only need a web connection, a free public ArcGIS account (though paid accounts have more capabilities), and your own content, or links to content. No special technical knowledge is needed to develop a Story Map. Although Story Maps are mostly visual, they can be made accessible for the visually impaired by including audio content, such as podcasts. Story Mapping is a highly flexible tool.

“The novelty of Story Mapping is the interactivity,” said Alexis Mychajliw, a Graduate Student Instructor at the Hadly Lab, Stanford University, where she and her colleague Melissa Kemp taught an undergraduate course on using Story Maps to communicate about global change in 2014 and 2015. “People can zoom in on the things they care about.” The two Story Maps created by the Stanford students describe climate change impacts using maps that link to local news articles (See: Geographic Impacts of Global Change: Mapping the Stories of Californians, 2014, and Mapping the Impacts of Global Change: Stories of Our Changing Environment as Told By U.S. Citizens, 2015). While some

Story Maps firmly direct the user’s experience to a particular conclusion, the Stanford maps let the climate-related news articles linked to points on maps displaying GIS data about climate change projections speak for themselves. The user is left to connect the dots, perhaps making a stronger impression than either an alarmist headline or dense scientific report.
Story Maps are currently enjoying growing popularity. They are in use at the grade-school level (Mr. Carroll says they are used from 4th grade up), and the tool is being taught widely in U.S. higher education institutions. Story Maps are replacing PowerPoint presentations at conferences. Non-governmental organizations are using them in lieu of traditional annual reports and project summaries for funders. Local governments and federal U.S. agencies like EPA, USGS, and NOAA are bringing Story Maps into play (see the NOAA Climate Program’s Story Map Evolution of the 2010-2015 Texas Drought).

Conservation science organizations are exploring the tool. There are eight Story Maps in the Landscape Conservation Cooperative Network’s collection, all published in 2016, including five about climate change (for example, one on the President's Resilient Lands and Waters Initiative in Hawai'i).


Image is a screengrab from the 2017 Story Map “Climate Migrants,” by the Esri Story Maps Team, accessible at http://storymaps.esri.com/stories/2017/climate-migrants/index.html


A tool that still needs testing and development

Story Maps have yet to be subjected to impact evaluation as a science communication tool. Generally, Story Maps are found to be “sticky”—they hold internet user’s attention longer than other websites—but there is a hunger at Esri for better analytics. Mr. Carroll reports that while there is anecdotal evidence of the tool’s effectiveness, much depends on the quality of the Story Map. He notes that not everyone is natural storyteller, and the impulse to overcomplicate a story is widespread. There is currently a trend of Story Maps being built inside of Story Maps that Mr. Carroll regards with skepticism.

Besides the problem with quality control in Story Mapping, there is the problem that it is hard to tell the publication date of any given Story Map in the current iterations of Esri’s templates. This is a useful tidbit of information, since much of the quality of a Story Map is contingent on its web links being active. Hopefully in the future Story Map application developers can give Story Mappers easy ways to display the date of their creations.

Story Maps have great potential as conduits for crowdsourcing climate change-related information in a geospatially explicit way. A National Park Memories Story Map from 2016 gives users an avenue for submitting personal stories and photos tied to specific parks.  This type of Story Mapping could have any number of applications for climate change researchers, such as crowdsourcing evidence of the distribution of invasive or endangered species.

Another place Story Maps might play an important role is in connecting local and historical place-based knowledge with climate model outputs. It strikes this correspondent that Story Maps could be particularly useful in linking climate data with Traditional Ecological Knowledge(s), such as Native/First Nations communities’ oral histories and cultural objects, to tell the story of climate change on indigenous lands.

Altogether Story Mapping is an exciting new tool in the climate change communication toolbox. Its multilayered interactive approach has great potential for inviting new audiences to take up otherwise boring bad news in better, self-paced ways, hopefully avoiding the pitfalls of doomsday overwhelm and over-nuanced pedantry, and moving people from curiosity to action.

Images above are screengrabs from the 2017 Story Map “Climate Migrants,” by the Esri Story Maps Team, accessible at http://storymaps.esri.com/stories/2017/climate-migrants/index.html

Resources on teaching Story Mapping
  • Two pedagogical articles came out of the global change Story Mapping classes at Stanford:
Story Maps to explore

Climate Migrants (Jan. 2017). Allen Carroll recommends this recent Esri effort as an excellent example of climate change communication using Story Maps.

Atlas for a Changing Planet (2015). This is an Esri Story Maps Team product created for COP21, covering climate change in five thematic areas: understanding natural systems, mapping human systems, mapping ocean impacts, predicting the future, and international cooperation.
An interesting Story Map in progress: GRID-Arendal, a Norwegian environmental knowledge foundation working with the United Nations Environment Programme, is working on an Indigenous Peoples Story Map project:

Endangered Reefs, Threatened People (2016): an award-winning GRID-Arendal Story Map about coral reefs, climate change, and ocean acidification.

Forest Management, Gender and Climate Change: A Story Map from the Mexican Forest States (2016): created by the International Fund for Agricultural Development (IFAD), a UN agency, this Story Map utilizes photos and videos to quickly and effectively introduce IFAD’s forest management projects and the indigenous women involved in those projects.