A recent study by NASA, the first of its kind, found that significant amounts of water are shifting around Earth’s surface.
Scientists used data from the Gravity Recovery and Climate Experiment (GRACE), two satellites, to track gravitational changes made by hydrologic shifts in 34 regions around the world. From 2002 through 2016, they paired this information with satellite precipitation data, NASA/U.S. Geological Survey Landsat imagery, irrigation maps, and public reports of human activities related to agriculture, mining and reservoir operations.
In short, researchers found that wetter areas are getting wetter and drier areas are getting drier. Jay Famiglietti of NASA’s Jet Propulsion Laboratory is one of the study’s authors. He explains, “We see a distinctive pattern of the wet land areas of the world getting wetter – those are the high latitudes and the tropics – and the dry areas in between getting dryer. Embedded within the dry areas we see multiple hotspots resulting from groundwater depletion.”
Scientists point to a couple of things to explain freshwater depletion in areas that are getting drier. In Saudi Arabia and many other parts of the world, for example, ground water has been depleted for agricultural purposes. The study also found that groundwater availability changes with periods of drought. From 2007 through 2015, southwestern California lost enough freshwater to fill 400,000 Olympic size swimming pools because the region saw less precipitation and snowpack during that time and had to rely on groundwater more heavily.
Freshwater loss in many regions was attributed to global warming that caused glaciers and ice sheets to melt away. However, Famiglietti said that much more research is needed to determine whether climate change caused the other hydrologic shifts.
GRACE Follow-On, GRACE’s successor, will continue to monitor the movement on water on Earth and is set to launch on May 22nd from Vandenberg Air Force Base California.
Dr. Craig Just is an assistant professor of Civil and Environmental Engineering at the University of Iowa. Up for tenure this summer, Dr. Just teaches graduate level courses along with an undergraduate principles of environmental engineering course. His research interests range from freshwater mussels’ impacts on the nitrogen cycles in rivers and streams to the fate of explosive chemicals once they are released into the natural environment. Iowa Environmental Focus caught up with Dr. Just to discuss his research on wastewater treatment in smaller communities.
Jenna Ladd: I wanted to focus on your wastewater treatment research in smaller communities. So, why can’t people in smaller communities flush their toilets affordably?
Dr. Craig Just: So, in a town like Iowa City, we just had an over $15 million expansion to our wastewater treatment plant but that cost was spread, you know, among a population base of 75,000 or 80,000 people so the per person cost for such an advance treatment system is under probably a thousand bucks each, give or take, prorate over a certain amount of time. But for smaller towns, who have increasingly rigorous environmental regulations they have to meet, particularly with respect to the discharge of ammonia and bacteria, they’re small so when you have to do a technology upgrade, it’s more expensive per resident and that’s one of the main issues. The other issue is that it also becomes more expensive then to pay an operator for the plant, someone that has the expertise needed to operate an increasingly more sophisticated treatment system. So, then you have to spread that cost amongst a small population base as well and so both of those factors are really scaling issues that, really, small towns have a problem dealing with compared to some other places. Those are some of the main issues going on there.
Jenna Ladd: How were those issues brought to your attention?
Dr. Craig Just: Sometimes it’s with screaming mayors at small town hall meetings. I’ve been going to Des Moines to talk about this issue since at least 2005. Legislators know it’s a problem, their constitutes tell them it’s a problem. In 2010, I was one of the co-leaders of what’s known as the faculty engagement tour. We get faculty who are typically stuffed in their offices and labs and we stuff them in a bus and took them all around Iowa to say, “You know, here are the people that pay your salaries, really, in a way, and let’s be aware.” So, we had a town hall meeting in Goodell, Iowa, town of about 225 people facing a $2.2 million waste water treatment plant upgrade bill and the mayor of that town and the mayor of three or four other towns came to this meeting. Over 100 people showed up to this meeting in all that was left of the school, the old gymnasium. The school’s gone….Everybody came out, it was such a big deal. People were mad, they were shouting. They viewed me as part of the cultural elite who wasn’t doing enough for them in rural Iowa, and that we were putting unrealistic environmental constraints on them that led them to essentially go bankrupt as a town. So I’ve heard it in casual conversation, I’ve heard legislators talk about it, I’ve heard it in town hall meetings. Candidly, at this point it’s hard for me to get away from. I’m from rural Iowa, you know, that’s where I’m from. So I’ve seen it first hand, it’s not hard to see.
JL: Are these newer wastewater treatment regulations or are communities just kind of playing catch up to those regulations that were already in place?
CJ: They’re new, and I would say that they’re based at the federal level. I would say one of the things that’s happening, and it’s a challenge for Iowa in particular, so the population in the U.S. has gone up. I think in just the U.S. alone, we’re up to like 330 million people now, whatever, 50 years ago, I think it was like 200 million or something. I don’t know those numbers, but the point is the overall population density has been going up. Most towns in these watersheds that have a discharge into a stream, most of them have gotten more dense so then you have to have more stringent regulations to not kill the stream. But when you apply those things at the federal level for the National Pollution Discharge Elimination System, it kind of puts a disproportionate burden on the places that haven’t grown. In fact, in rural Iowa, it’s less dense but then you still have to meet these federal standards which are somewhat one-size-fits all and so, I don’t disagree with the fact that the federal standards have become more strict but it’s difficult to apply it in a place that’s population and tax base isn’t growing. It puts rural Iowa at a very special pinch point where those two things converge.
JL: Are there any solutions you’ve come up with for this problem?
CJ: Well, first of all, there are already some alternative technologies, they’re called, that are approved in Iowa that are robust and more affordable, not as affordable as you might like but still more affordable. So, one of the things that we’re doing in partnership with H.R. Green Consulting Engineers, one of our alums there Matt Wildman has really kind of led the use of this technology in Iowa. We’ve partnered with them and the community of Walker, Iowa to extensively test one of these alternative technologies called—it’s a lagoon modification—a submerged attached growth reactor, essentially rocks in a box. A couple lagoons. The lagoons are aerated, they take care of some of the wastewater issues and then it goes to these rocks in a box where the bacteria then are attached to the rocks, they further covert the ammonia with aeration to nitrate, which you can still legally discharge in Iowa—it’s a fertilizer though. It doesn’t solve all of our problems if you look at the broader watershed problems with respect to nutrient discharges, but yet it removes the acute toxicity associated with ammonia discharges. So, that works out well in many regards. It still doesn’t solve all the problems because at least, approximately half the cost of the system is just the pipes that collect the waste from each house and those systems are deteriorating in these towns as well. So, even if we’re improving the system at the end of all those pipes it still kind of tricky to deal with that.
I’m even thinking of almost having your toilet be more like an appliance where you don’t have to convey your waste someplace else. If we could find a way to do that, almost like a compost toilet would work, the composting waste you’d have to collect. The nice thing about that sort of a mentality is you could then use that waste as a resource because there are nutrients in there, there is energy value in that waste. Right now we send it to a lagoon and then one of these box of rocks with bacteria, we treat it but we don’t harvest any of the energy…in fact, we have to put energy in. I think if we could find ways to do that, even in these small towns, then it would make them more sustainable. It would give them extra resources that I think would be valuable. So in the future, I think it would be valuable to maybe not have these lagoons at all. Especially for these towns that are increasingly small, you know, like 600 people or less.
But anyway, so I’m thinking even longer term, but in the short-term, these alternative technologies are better. One of the things that we’ve been able to do then, with all this data collection that’s been going on in Walker since 2013 is now, we can more appropriately size the technology. Since we didn’t have very much data before, we kind of over-sized it in the name of kind of a safety factor. Now with data, we can shrink the size which then makes it cheaper. So that’s where the researcher comes in. As a researcher, I can come in, get this data, say “No, it doesn’t need to be this big” and then work with Iowa Department of Natural Resources to get that approved. That just recently happened. So, now going forward this particular technology can now be about a third smaller, which would have saved Walker, Iowa about $150,000 on a 2.5 million project. That’s real money. 750 people and $150,000 saved, that would be a lot. You multiple that across the nearly 800 or 900 communities these technologies are targeting so that’s a lot of money that Iowans can save. That’s kind of where research and the practical nature of trying to make things affordable come together. Sizing things appropriately so they still work and then making sure the operators still know how to handle any disruptions and understand why things do get disrupted from time to time.
JL: Are you communicating with people working to solve these problems in rural communities in other states?
CJ: In general, Iowa is a little bit behind. Even our peers on our borders: Minnesota would be ahead of us in many regards, some other places too. A lot of these alternative technologies have been utilized in warmer climates. Since they’re biological processes, the bacteria work better when they’re warm, just like you or I do. I don’t move so fast when I’m cold and neither do bacteria. So the challenge for Iowa has been even though some other states have been embracing these alternative technologies more readily, they are easier case studies too. So really, for Iowa, it’s been “How do we manage the cold weather?” that we have and “Will these systems still work when it’s cold?” So, we’ve applied what we can from other states in trying to catch up and now we have to deal with that in our own Iowa circumstance going forward. So yeah, we’ve learned from other places, but we still have to make sure we deal with, you know, Iowa’s situation.
JL: In what ways does this research relate to your teaching?
CJ: Increasingly, developing countries, where again you lack a population base and kind of a resource base and a tax base, some of the challenges are like rural areas in the United States. They’re kind of falling into some of those same categories sometimes so I want our engineers that graduate from our program to understand the rural dilemma. It’s relatively easy to be an engineer when you have all the resources you need, you got money. Yeah, shoot, design away, and it’s fun to kind of do it like that, but when you have to apply your engineering skills and really your community engagement skills at the same time to try to make a difference in a community that’s struggling just to keep their doors open, that’s a cool place. That’s very satisfying and rewarding for an engineer to be operating there. So I’m encouraging our students to do that in some way or another so when they go out into engineering and consulting, they’ll be aware of the issues that small rural communities face in contrast to what growing, urban areas face: fundamentally different engineering problems.
A recent study shows that when freshwater ponds warm, they release more methane and are able to store less carbon dioxide.
Researchers at the University of Exeter and Queen Mary University of London warmed a collection of man-made ponds by four to five degrees Celsius over the course of seven years. The first of its kind, the study found that the amount of methane released by the ponds increased by double while the amount of carbon dioxide the ponds could store decreased by half.
Professor Gabriel Yvon-Durocher was the study’s lead investigator. He said, “Given the substantial contribution small ponds make to the emission of greenhouse gases, it is vital to understand how they might respond to global warming.”
Yvon-Durocher continued, “Our findings show that warming can fundamentally alter the carbon balance of small ponds over a number of years, reducing their capacity to absorb carbon dioxide and increasing emissions of methane. This could ultimately accelerate climate change.”
The scientist noted that these findings are different than those normally observed on land, where the effect of rising temperatures lessen over time. In contrast, when ponds warm and release methane, a gas that is known to be 25 times more potent than carbon dioxide, they actually exacerbate warming.
Ponds of less than one meter, such as those used in the study, are responsible for the release of 40 percent of all inland methane emissions.
The professor noted, “This accelerating effect in ponds, which could have serious impacts on climate change, is not currently accounted for in Intergovernmental Panel on Climate Change models.”