Latest news with #Glandon
Chicago Tribune
3 days ago
- Science
- Chicago Tribune
Can artificial reefs in Lake Michigan slow erosion and boost fish population? Researchers aim to find out.
Floating about 500 feet offshore of Illinois Beach State Park, Hillary Glandon tightened her scuba goggles, grabbed a small masonite plate from a nearby kayak and dove beneath the Lake Michigan surface. The masonite plate, called a Hester-Dendy sampler, helps biologists like Glandon scrape algae off underwater rocks. Just a few feet below the surface, she reached a huge underwater ridge made of limestone and other rocks piled into 750-foot rows parallel to the coast. On this dive in late June, a crew of four scuba divers ferried equipment back and forth between the kayaks and the underwater ridges, collecting sediment samples near the boulders and dropping off underwater cameras on the bottom of the lake. As the divers continued their work, a thick morning fog began to fade, giving way to clear blue waters. From the surface, schools of juvenile fish could be spotted drifting between patches of sunlight at the bottom of the ridges. These structures, called 'rubble ridges,' aren't just typical rocky reefs found on the bottom of the Great Lakes — they're entirely man-made. 'We just want to see, are these reefs impacting aquatic biodiversity as well as sediment retention?' Glandon said. 'We're trying to get the whole picture of the aquatic community, and in order to do that, we need to sample in a lot of different ways. It allows us to not only look at the sediment … but also the critters that are living in there.' Man-made reefs have become a popular way to provide a habitat for fish in coastal communities. The rubble ridges, however, are also designed as a cost-effective tool to prevent erosion. Each ridge sits about 3 to 5 feet beneath the lake's surface, which allows them to block some of the energy and sediments carried by waves during intense winter storms. When these waves reach the coast, they don't hit the shoreline as hard, which slows the process of erosion. And the gaps between each ridge help to retain some sediment without fully stopping the natural flow of sand. 'The designers call it passive sand management, just to slow erosion down when it's the worst,' said Steve Brown, the Illinois state geologist. 'That was part of the idea — a lower-cost offshore breakwater system. And we're trying to see, does it work like the designers thought it would work?' Glandon and her team of biologists and geologists at the Lake Michigan Biological Station, a research station in Zion run by the University of Illinois, are studying the rubble ridges as part of a federally funded pilot project through the Great Lakes Restoration Initiative. The initiative is a collaborative effort that provides funding to over a dozen federal agencies to protect the Great Lakes through infrastructure and lake monitoring projects. Installed at Illinois Beach State Park in 2021 by the U.S. Army Corps of Engineers, the ridges are being monitored along with another artificial reef at Fort Sheridan in Highland Park, as well as two control sites, about 2 miles south of each respective reef. In this part of Lake Michigan, just 3 miles south of the Illinois-Wisconsin state line, the lake bottom consists of a flat layer of sand, which doesn't usually attract invertebrates and smaller fish. But as Glandon descended onto the rocky ridge, she saw hundreds of fish, from species that tend to stay near the reef year-round like the round goby, to schools of younger migratory species like alewife that were using the ridge as a nursery habitat. By analyzing both biodiversity and shoreline changes at the reef, researchers are hoping to see whether this new kind of infrastructure could be scaled up as a tool for cities across the Great Lakes. 'Lake Michigan is a very dynamic place. It is always changing, and it always wants to change, and it always will change,' said Philip Willink, a biologist with the Illinois Natural History Survey and an expert on natural reefs in Chicago. 'People don't like that change and are trying to hold the shoreline in stasis, when, in reality, nature wants to erode some shoreline … But how do we put that into city planning?' As Glandon and a crew of three other scuba divers and two kayakers ventured out to sample algae and sediments at the ridges, a few other researchers remained onshore to help handle equipment. It was the research team's first dive of the year, and biologist Scot Peterson could already spot the traces of erosion from the winter's storms. Where a wooden boardwalk had once extended out over the beach, only a small chunk of wood remained, poking out from under a sand dune on a nearby roadbed. Strong waves had gradually weakened the structure over the past few years, and last year, the state park decided to remove it altogether. Related Articles A dry, mild start to winter led to below-average ice cover on Lake Michigan and a big drop in water levels We don't know what's at the bottom of the Great Lakes. Climate change demands we find out. Just off Chicago in Lake Michigan sits an oasis of diversity — Morgan Shoal 'Every time I come back, it feels like something has changed,' Peterson said. Sights like these are common across the Great Lakes, and Lake Michigan in particular can be especially 'unpredictable,' said Liz Spitzer, a coastal geologist with the Illinois State Geological Survey. The lake's levels tend to fluctuate from low to high in 10- to 30-year cycles, with levels usually reaching their annual peak during the summer. However, climate change is speeding up these fluctuations, experts say. In January 2013, Lake Michigan was at a record low. Just 3 ½ years later, the lake had risen 4 feet and by July 2020, it nearly broke the record high. Lake levels have always fluctuated, but that has been over a period of decades. Now these shifts are happening within a few years. That variability is attributed to multiple factors, but increased precipitation from climate change is the driving force. Today, lake levels are hovering at about 579 feet, close to the lake's average. At Illinois Beach State Park, these fluctuations have taken a toll, causing extreme erosion along the coastline. Kellogg Creek, located just south of the rubble ridges, has flooded several times over the past few years, damaging one of the buildings that researchers at the Lake Michigan Biological Station used to store samples. The lake bed at the northern part of the beach has eroded away, leaving grass roots exposed as windswept dunes pile up behind the shore. In response, the Illinois Department of Natural Resources approved a massive breakwater installation project in 2019 for the state park. The state spent $73 million to install 22 breakwaters along a 2.2-mile stretch of the state park's shoreline, making it the largest capital project in IDNR history. According to a 2023 release about the breakwaters, the state intended the structures to 'guide and direct the movement of the sand instead of simply trying to prevent its movement.' The breakwaters, made of stone, are angled slightly to the northwest to block storms that typically come from that direction. IDNR officials did not respond to requests for comment. The breakwaters, along with 430,000 cubic feet of sand that was added to bolster the beach, have helped rehabilitate the beach since construction finished in August 2024. The first chain of breakwaters ends just a few hundred feet north of the rubble ridges. With extreme erosion and other construction projects unfolding at the state park, Glandon said her team has had to deal with several 'confounding factors' at this reef site. 'The rubble was actually supposed to be built a little bit north of where it currently is, and that's because the large breakwater project was in the process of being designed when the rubble was being implemented,' Glandon said. 'They moved (the rubble) further south to accommodate those breakwaters.' The monitoring project at Illinois Beach State Park began in 2021 and is set to wrap up next year. The other artificial reef site at Fort Sheridan has been monitored since 2023 under a different project funded by the Illinois-Indiana Sea Grant. Researchers are comparing the results between the two sites, hoping to explain how reef systems function along different types of shorelines. The shoreline at Fort Sheridan consists mostly of rocky bluffs, and the lake bottom in that area is dotted with small boulders. Each spring, geologists have used drones to map the elevation of the bottom of the lake, allowing them to compare any changes in the lake's topography that happened during the winter storm season and see if the reefs are helping retain sediment. According to the research team's preliminary results, the Fort Sheridan reef has successfully helped to build up some sand. At Illinois Beach State Park, though, erosion has overall increased. Most of this erosion occurred between 2022 and 2024, with very little change happening at the site during the 2025 winter season. 'The sediment dynamics, that part of it is going to be very hard to make any conclusions without a huge asterisk, since they built these big breakwaters,' Glandon said. 'But what we're hoping to do is kind of zoom out with the geology story, and tell it from the perspective of before they built these big breakwaters and after. We're just trying to be nimble with the way we're sampling.' Illinois Beach State Park, which boasts the state's longest continuous stretch of natural shoreline, is somewhat of an anomaly. The park takes up 6.5 of Illinois' 63 miles of coastline along Lake Michigan, and the majority of this coastline consists of man-made structures, such as breakwaters or seawalls. This infrastructure is meant to help protect the urban coastline from eroding. However, it's not how the shoreline naturally functions, according to Spitzer. 'Along this stretch of the coast, the dominant current is generally coming from the north, going southward,' she said. 'Over the past couple thousand years, with the direction of the dominant current, we've been seeing the sand moving southward over time. And then human activity adds an extra layer of complexity to that, because that compartmentalizes where the sand can go.' The goal of most coastal protection structures, like seawalls, is to retain sand that's flowing through the lake. This helps build up extra sand along lakefront beaches and harbors, and lessens the impacts of erosion. Sand was already a scarce resource in southern Lake Michigan before humans began to build coastal infrastructure, according to a 2020 study conducted by Brown and other geological survey researchers, making sand retention in the area particularly vital. But man-made structures, which often run perpendicular to the shore, can also block the natural southward flow of sand. So while seawalls can build up sand in one location, a beach directly downstream of that seawall might face worse erosion as a result. 'Every time we create a structure, it stops the sand movement, and you get erosion downstream,' said Brown. 'And so the real question is that we haven't sorted out how to live along the lake.' The rubble ridges were designed to be an 'actively moving system,' Glandon said — as waves crash against the ridges over several years, researchers expect that some of the boulders will tumble to the bottom, flattening out over time. Since reef structures like the rubble ridges run parallel to the coast, they serve as somewhat of a middle ground — they retain some sand near the coastline but still allow most of it to pass through. So as the sand moves downstream, it leaves more for lakefront properties to the south to use as they build up their own shorelines, helping distribute sediments more evenly across the lake. That's part of the reasoning behind government investments in this project, Glandon said. Currently, most municipalities along the North Shore run their own coastal management programs and tend to build shoreline infrastructure like seawalls without consulting their neighbors. When one town builds a seawall, it creates a so-called domino effect — that can starve neighbors of sand directly to the south, and usually the only solution is to build their own seawalls. 'When we have private land ownership, it can be tricky to manage sediment movement that occurs outside of those human-created bounds,' Glandon said. Using infrastructure like artificial reefs, or other more natural designs, could help alleviate the need to build seawall after seawall. It also presents a relatively low-cost option — installing the rubble ridges cost just over $1.4 million. 'One of the hopes of our program is to try to provide this quantitative data on the effects of these structures … to give towns and local managers options for ways that they could potentially retain some sand in their areas without impacting their neighbors as much,' Glandon said. From the shores of Fort Sheridan and Illinois Beach State Park, the artificial reefs are invisible, hovering just beneath the surface. For aquatic creatures, though, these rocky reefs are a landmark, rising distinctly above the lake bottom. 'Most of the bottom of Lake Michigan is pretty flat. It's either sand or mud, with no real features,' Willink said. 'But every once in a while, there are natural reefs out there, and these can be in shallow water, in deeper water, they can be from a variety of sources as well.' Willink, the biologist who now works with the Illinois Natural History Survey at the University of Illinois, worked for many years at Chicago's Field Museum and Shedd Aquarium. There, he studied one of Chicago's most iconic underwater landmarks. Morgan Shoal, located just off the coast of Promontory Point by 53rd Street, is one of a handful of naturally occurring rocky reefs in Lake Michigan. This reef is actually a remnant of Chicago's ancient past, Willink said — about 425 million years ago, the modern-day Great Lakes region was located south of the equator, submerged in a tropical sea that was home to several coral reefs. Though the region's latitude has shifted, traces like the rocky reefs remain on the bottom of the lake, providing an ideal habitat for fish. Morgan Shoal features a wide variety of 'nooks and crannies,' Willink said, which provide habitats for a range of animals from large migratory fish to small invertebrates and worms. 'In the smaller spaces, that's where we found a lot of the aquatic insects and worms — things which may not sound super exciting, but that is the bottom of the food chain,' Willink said. 'This is the key, to have a variety of different habitats. When you do that, you create more of a larger variety of living spaces for a larger variety of species. And then ultimately, you end up with a higher biodiversity on the site.' While natural reefs often provide more appealing habitats for fish, artificial reefs are also widely used for the same purpose, and have been shown to boost biodiversity. This has been shown at the rubble ridges, too. Both the Illinois Beach State Park and Fort Sheridan reefs showed a significant increase in fish populations and biodiversity when compared against the control site for each reef, according to preliminary data from the Lake Michigan Biological Station research team. The team tracks fish diversity with a number of different measures. During the June dive at Illinois Beach State Park, kayakers carried large aluminum frames, each with an underwater camera mounted in the middle, out to the reefs. Scuba divers carried these frames down to the reefs, where they'll remain for the rest of the summer season. The cameras are programmed to take a picture every five minutes, which helps scientists track the density and mass of the fish living on the reef. 'We see at the control sites, biomass is high, but abundance is low, versus at the reef sites, we have much smaller fish,' Glandon said. 'We think it's because this is showing that the reefs are nursery habitats for these fish.' They also take samples of algae living on the underwater boulders that make up the reef, and collect sediments to see what types of invertebrates are living at the site. These invertebrates are the core of the food chain, attracting smaller fish in search of food sources. While fish and invertebrates do sometimes seek shelter around man-made breakwaters, Willink said they're most attracted to natural structures that don't totally stop the flow of sand. 'Part of the key is that it isn't a dam to the sand, it doesn't hold the sand there,' Willink said. 'If there's too much sediment, that would smother all these small places.' As the reef monitoring project continues, so does the constant movement of sand. Despite humans' best efforts to counter this, the currents of the lake are ever-changing and ever-powerful, scientists say. As lakefront communities have built containment structures along their waterfronts, this trend has remained the same — even at established places like Illinois Beach State Park, waves surge above boardwalks, benches sink beneath sand, roadways are left to crumble in the face of encroaching shorelines. 'A lot of what we're facing right now in the 21st century is, how do we deal with nature in urban areas? How do we live with nature next to us and allow nature to do its thing, and yet still maintain the infrastructure of a city?' Willink said. 'And I think that's sort of an emerging field, trying to figure out how to deal with this sort of struggle between the two. It's not just restricted to Lake Michigan — it's everywhere.'
Yahoo
07-04-2025
- Science
- Yahoo
Artificial Reefs Can Mitigate Coastal Erosion in the Great Lakes. Will Cities Agree to Adopt Them?
Lake Michigan in Chicago, March 1, 2024 | Susan J. Demas This article originally appeared on Inside Climate News, a nonprofit, non-partisan news organization that covers climate, energy and the environment. Sign up for their newsletter here. Illinois boasts 63 miles of coastline along Lake Michigan's southwestern shore, nearly all of which is fortified by metal breakwaters, concrete seawalls and even swaths of land built out into the lake. These structures are meant to protect the city of Chicago and its suburbs from coastal erosion. But according to Hillary Glandon, a scientist at the Lake Michigan Biological Station in Zion, Illinois, this fortification is 'part of the problem.' 'You have protection structure after protection structure after protection structure, and it has really disrupted the natural flow and processes that occur in these coastal zones,' Glandon said. With water levels that can vary by several feet from year to year—and climate change making these variations even more unpredictable—cities across the Great Lakes are working to fortify their coastlines and prevent erosion. But traditional coastal infrastructure like breakwalls can cost tens of millions of dollars, making them a heavy financial lift for local governments. And while these breakwalls help retain sand and build up the coastline directly inland of where they're constructed, they also block currents from carrying sediment farther down the coast, compounding the effects of erosion downstream. Glandon and her team have a solution: Install artificial reefs in the lake's shallows to temper the intensity of waves and preserve the shoreline directly inland. Through a federally funded pilot project, the team is studying two artificial reefs—one at Illinois Beach State Park in Zion, and another at Fort Sheridan in nearby Highland Park. They're hoping to collect data on how these reefs impact the local shoreline to see if artificial reefs are a scalable solution to coastal erosion in the Great Lakes. 'This project was hoping to come up with some softer designs, not necessarily fully stopping that movement of sand and water, but also a more cost effective design,' Glandon said. The two reefs she's studying are both made entirely of natural materials and built by the U.S. Army Corps of Engineers. The reef at Fort Sheridan was built in 2020, while the one at Illinois Beach State Park was built the following year, designed as part of the University of Pennsylvania's Healthy Port Futures program. Their approach, called 'rubble ridges,' is relatively simple and involves piling dredged sand and limestone beneath the surface to block waves. While artificial reefs have been used around the world to bolster biodiversity, their use for erosion control is new. Lake Michigan is already home to a handful of artificial reefs, most of which are located farther from shore as a habitat for marine life. Some researchers in the U.S., though, say these could serve the dual purpose of boosting fish populations and preventing erosion, disrupting waves so that they're less intense when they crash ashore. 'It's a hydrodynamic optimization to get the wave energy that''s coming into these reef structures,' said Ansel Garcia-Langley, a graduate student at the Massachusetts Institute of Technology who's working on another architected reef design. 'As the waves hit these pillars, it forces the waves into different directions, so that they spin off into these vortices. So a lot of the energy coming in is dissipated in on itself.' Garcia-Langley and his colleagues at MIT wrapped up their initial study of architected reefs last March, and found promising results. His team, headed by ocean science and engineering professor Michael Triantafyllou, created a unique cylindrical reef design that is intended to maximize drag on wave energy, forcing the waves through cracks in the structure to lower that energy before it hits the coast. Reefs like these help preserve the natural flow of sand and sediment along coasts. Structures like seawalls can create what Garcia-Langley called 'dead zones,' where this flow reaches a standstill, redirecting increased wave energy to the surrounding areas. For local governments jockeying for control over the Lake Michigan shoreline, avoiding these dead zones is critical. 'The lake is valuable, right? People want to live near the lake. They want to be able to go to the beach,' Glandon said. 'And so removing that possibility from a landowner due to actions upstream tends to cause some real tension.' In Illinois, there are dozens of municipalities that border Lake Michigan, and hundreds of private landowners. Because the towns and property owners with a slice of that shoreline control their own infrastructure, shoreline protection can get heated. Sediment flows from north to south in Lake Michigan, so when one town installs a seawall, it can prevent sediment from reaching shores directly south, leaving those places more vulnerable. This has led to heated debate between some shoreline towns, said Cody Eskew, a specialist in coastal studies with the Illinois Sustainable Technology Center. Eskew, who works closely with the Illinois Department of Natural Resources, has helped run IDNR's Shoreline Management Working Group since 2015, holding biannual meetings with local governments who share Lake Michigan's coastline to work through their shoreline protection plans. 'At first, I think there was just a lack of understanding of what the shoreline dynamics were in our region, especially the North Shore region,' Eskew said. 'At Illinois Beach State Park, there's a ton of sand there, but when you go a little bit farther south toward those North Shore neighborhoods, we found that there's just not much naturally occurring sand on that piece of the shoreline. So communities are really limited in terms of, you know, what they can expect from their neighbor and getting sand from updrift.' That makes artificial reefs particularly alluring in the Great Lakes—they're a way to block wave energy without making erosion worse for neighbors, and they're far cheaper than traditional infrastructure. For instance, the Illinois Department of Natural Resources recently funded a project building 22 breakwalls off the coast of Illinois Beach State Park, which cost about $73 million. Installing the beach's rubble ridges cost $1.4 million, according to Eskew. 'The typical community is not going to have in their capital budget to be able to install something that large,' he said of the breakwalls. 'So they are really looking into those more hybrid structures.' The costs aren't set and can vary widely, said Juliet Simpson, a coastal ecologist with MIT's Sea Grant program who also works on their architected reefs project with Garcia-Langley. Last year, the team estimated their model to cost about $6 million per mile, while Simpson noted that other reef models can cost upwards of $10 million per mile. The team is hoping to slash that cost even further to make these protections affordable for coastal communities. So what's keeping this new approach to artificial reefs from taking off? According to Sean Burkholder, who heads the UPenn Healthy Port Futures team that helped design the rubble ridges, it's simply a lack of familiarity. 'We've lived on shorelines that have been protected by seawalls for hundreds of years, and we kind of know that they work,' Burkholder said. 'We also kind of know when they fail, and how they're going to fail. Any type of nature-based infrastructure, they're not super well proven.' To prove the concept, Glandon and her team are meticulously collecting data on how the artificial reefs at Illinois Beach and Fort Sheridan impact their respective shorelines over the course of five years. The data is already showing promising results—and according to Eskew, it's been drawing attention from officials working on shoreline management all over Lake Michigan. If all goes well, these rubble ridges could soon appear beneath the surface of many of the Great Lakes. 'Often these types of structures are built, and there's very few requirements for post construction monitoring.' Glandon said. 'I think this is a really quantitative picture of shoreline change and aquatic habitat creation as a result of these nearshore breakwaters.'
