Have you ever seen barnacles on a rocky shore or the side of a boat and felt amazed? Chances are, probably not. These small, bumpy organisms are known to grow on rocks, boats and even whales, but most people probably don’t think twice about them. Barnacles may just seem like lumpy things in the water, but there is so much more to them than meets the eye.
Barnacles are living organisms (yes, they’re alive!) They are crustaceans, related to crabs, shrimp and lobsters. Scientists have discovered more than 1,400 species of barnacles, with the acorn barnacle being the most commonly known. These animals like to live in rocky intertidal areas or even near underwater volcanoes where there is active, moving water. This makes mealtime much easier for them since they are filter feeders. Barnacles use sensory appendages called cirri to comb through the water to grab their next snack.
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Unlike many other crustaceans, barnacles are sessile as adults, which means they stay in one place. Barnacles begin their lives as itsy-bitsy larvae, floating through the water column until they find a suitable place to call home. Once they find their prime choice in real estate (most often rocks, but sometimes vessels or other organisms), they set up shop permanently. To secure themselves to their new home, barnacles secrete a fast-curing and extremely adhesive “cement”. This natural protein-rich adhesive is one of the strongest natural glues known to science to date. Once barnacles glue themselves to an object, they never move again. Now that’s some serious commitment!
After attachment, a barnacle begins to grow its shell. Over time, the animal grows six calcium carbonate plates. Four of these plates become a “door” that the barnacle uses to feed and, if living in intertidal areas, retain moisture when the water recedes. Like other crustaceans, barnacles outgrow their shells. Unlike other crustaceans, they can’t move to find a new home. Instead, they molt their outgrown shell and regrow a new one. Scientists are still unsure how exactly barnacles do this, but they theorize it involves a unique chemical reaction that creates space inside the shell as new calcium carbonate develops.
People in maritime industries are often annoyed by barnacles, and it’s not just because they are hard to remove from boats and buoys. Large barnacle colonies can increase drag, affecting the energy efficiency of a ship, which in turn causes them to use more fuel than usual. The United States Navy estimates that extreme barnacle growth could increase fuel consumption up to 40%. This poses significant environmental and economic impacts, so it’s important to keep barnacle growth on vessels in check.
While barnacles may cause nautical hindrances, they are proving to be helpful in some areas of science, including forensic investigations. About a year after the vanishing of Malaysian Airlines Flight 370 (MH370) in 2014, pieces of wreckage began to wash ashore on the island of Réunion. Gooseneck barnacles (Lepas anatifera) had grown on the debris, which led investigators to recruit scientists trained in a discipline called sclerochronology. This is the study of chemical composition and temperature markers within a shell over time (similar to tree-ring science, but for shells). The barnacle shells could offer critical coded information about where the debris has been in the ocean and when. While this science is still in its infancy, these studies could help tremendously in the journey to retrace the drift path of MH370 and deconstruct the mystery behind the airline’s disappearance.
Barnacles may not be as cute or charismatic as other marine wildlife, but they still depend on a healthy ocean to thrive. Ocean acidification can harm their growth and shell maintenance, making them especially vulnerable to the impacts of climate change. Click here to learn more about Ocean Conservancy’s work to combat ocean acidification and strengthen the wildlife and communities affected by it today.
The post What’s the Deal with Barnacles? appeared first on Ocean Conservancy.
Ocean Acidification
The Strata that Matta
From Desert to Seafloor

Fig. 1) team Strata That Matta: Victoria C., Maeghan D., Maddie B., Vale B. (from left to right)

The months leading up to OCEAN CORE Academy were filled with another type of adventure for me, surveying the badlands of New Mexico in search of dinosaur bones. Yet, my work in the Gulf Coast Repository consisted of examining ocean cores using a microscope. Although these experiences couldn’t be any more different, the two were similar in that each attempted to answer the same question: what did Earth look like in the past?
I focus much of my research on vertebrate paleontological and geological fieldwork, such as prospecting for fossils, measuring strata, or describing ancient paleoenvironments and faunal assemblages. While I knew about microfossils, I had not fully grasped how much geological history is present in them.
Fig. 2) fieldwork, NM (May 2026)
History Through a Microscope

This leads me to one of the most memorable parts of OCEAN CORE Academy, learning to prepare smear slides and identify what existed within the ocean cores. Ocean sediments are fairly recent in that they have not yet been lithified, each layer represents tens to hundreds of years of depositions onto the seafloor. What I looked at was much deeper!
It was a momentous occasion when I first saw a radiolarian beneath the microscope! These tiny fossilized organisms provide surprisingly detailed insights into ancient environments. The conditions in which different groups of microfossils thrive vary, but by tracking how they fluctuate between layers, we can reconstruct climatic shifts over geologic time.
Team Strata That Matta correlated a transition from calcareous to siliceous ooze layers with a cooling climate!
Fig. 3) my first time seeing microfossils

Fig. 4) radiolarian Fig. 5) coccolithophores Fig. 6) sponge spiccules
Bringing OCA Back to AZ
Upon my return to Arizona, I will carry this new perspective with me. As I move forward with future projects and field seasons in New Mexico, volunteer at the Arizona Museum of Natural History, and pursue my degree, the skills I developed here will prove to be invaluable for strengthening my own research.
Prior to attending OCEAN CORE Academy I viewed microfossils as existing, yet somewhat separate from my projects. This place has challenged that perspective. I came to understand that many of the most detailed records of Earth’s past are the microfossils hidden within a single grain of sediment!

Fig. 7) class of OCA 2026
Written by OCA 2026 student, Maddie Baare
Ocean Acidification
Earth’s History at Every Scale
From Desert to Seafloor

Fig. 1) team Strata That Matta: Victoria C., Maeghan D., Maddie B., Vale B. (from left to right)

The months leading up to OCEAN CORE Academy were filled with another type of adventure for me, surveying the badlands of New Mexico in search of dinosaur bones. Yet, my work in the Gulf Coast Repository consisted of examining ocean cores using a microscope. Although these experiences couldn’t be any more different, the two were similar in that each attempted to answer the same question: what did Earth look like in the past?
I focus much of my research on vertebrate paleontological and geological fieldwork, such as prospecting for fossils, measuring strata, or describing ancient paleoenvironments and faunal assemblages. While I knew about microfossils, I had not fully grasped how much geological history is present in them.
Fig. 2) fieldwork, NM (May 2026)
History Through a Microscope
This leads me to one of the most memorable parts of OCEAN CORE Academy, learning to prepare smear slides and identify what existed within the ocean cores. It was a momentous occasion when I first saw a radiolarian beneath the microscope!
Before, I had been hunting for fossils measured in centimeters/meters, but now I am studying those measured in micrometers. These tiny fossilized organisms provide surprisingly detailed insights into ancient environments. The conditions in which different groups of microfossils thrive vary, but by tracking how they fluctuate between layers, we can reconstruct climatic shifts over geologic time.
Using these changing microfossil assemblages, my team correlated a transition from calcareous to siliceous ooze layers with a cooling climate!
Fig. 3) my first time seeing microfossils



Fig. 4) radiolarian Fig. 5) coccolithophores Fig. 6) sponge spiccules
Bringing OCA Back to AZ
Upon my return to Arizona, I will carry this new perspective with me. As I move forward with future projects and field seasons in New Mexico, volunteer at the Arizona Museum of Natural History, and pursue my degree, the skills I developed here will prove to be invaluable for strengthening my own research.
Prior to attending OCEAN CORE Academy I viewed microfossils as existing, yet somewhat separate from my projects. This place has challenged that perspective. I came to understand that many of the most detailed records of Earth’s past are the microfossils hidden within a single grain of sediment!

Fig. 7) class of OCA 2026
Written by OCA 2026 student, Maddie Baare
Ocean Acidification
Microplastic Pollution Research at Sea
I have been studying plastic pollution for more than a decade. I’ve analyzed hundreds of samples in labs, pored over data and spent years thinking hard about where plastics go once they leave our hands and enter the environment. I love doing work on the water—this was a big part of my previous professional roles in Alaska and in Saipan, Northern Mariana Islands.
And here’s where it took me! I was thrilled to have the opportunity to join the first leg of eXXpedition’s voyage in the South Pacific this past spring, trading my lab coat for a lifejacket to study microplastics at sea. Sailing from Auckland, New Zealand, to the Bay of Islands aboard the 70-foot research vessel Wind Shift over 10 days, our crew of 12 women conducted ocean water-surface sampling via manta tow nets (a long cone-shaped mesh net), cleaned up debris on remote beaches and examined city streets with measuring tapes and field equipment. Our purpose? To collect key data to help us better understand the flow of plastics from land to sea.
Our all-female guest crew—hence the XX in “eXXpedition”—brought aboard expertise from the fields of structural engineering, circular economy strategy, sustainable fashion, plastics research, robotics and more. Together, we represented a remarkable cross-section of disciplines united around a shared concern for the health of our ocean.
Seeing it with my own eyes
We found plastics of all shapes and sizes everywhere we went—in the city streets of Auckland, while crossing the Hauraki Gulf and even at Aotea Great Barrier Island (one of the most remote and protected stretches of New Zealand’s coastline). Our ocean is vast and some of these places felt far removed from the centers of human activity, but this eXXpedition was a good reminder that plastic doesn’t respect remoteness. It moves, accumulates and shows up where we least expect.
Working alongside local NGO Sustainable Coastlines, we arrived on a remote stretch of beach on Aotea Great Barrier Island to audit and clean up any plastics we came across. What we found there told the same story our Auckland street surveys did: We found bottle caps, food packaging, fragments, plastic pellets and fishing debris. The everyday materials of modern life—but weathered, broken and scattered.
Science at sea
One of my favorite parts of the voyage (which was also one of the most challenging, if I’m being honest!) was the sea-surface manta trawl analyses we did onboard. I found out quickly that sorting microplastics from krill-laden seawater samples under a microscope while sailing is not for the faint of stomach.
The most common plastic culprit we found in those samples? Microplastic fibers. This type of microplastic is no wider than a human hair and is the most common type of microplastic found in the environment. Microplastic fibers can come from a variety of sources like cigarette butts, weathered ropes or wet wipes, but actually, most microplastic fibers shed from synthetic clothing and textiles. Laundering is a major source— shockingly, a single load of laundry can generate up to 18 million microfibers.
And yet, we found these tiny plastic fibers floating in the ocean many miles away from the nearest washing machine.
In my lab research, I have found microplastic fibers time and time again, but there’s something even more sobering about hand-picking them out of a seawater sample collected from pristine-looking waters. It was a good reminder of why understanding where plastic comes from, how it moves and where it ends up is so critical to addressing the problem at its roots.
Filter Out NSFW Microplastics
What I’m bringing back
Studying plastic pollution from the deck of a boat in some of the most remote waters in the Southern Hemisphere made me appreciate the work I do even more. It also made me appreciate how important people are in this giant puzzle of plastic pollution solutions. The plastic pollution crisis is a human problem, and solving it requires all of us. The courage and dedication of the women I shared those 10 days with is something I won’t forget. Going to sea, doing the science and pushing through discomfort to collect data that matters was not easy. We were seasick some days and exhilarated others. Despite that fact, we showed up for it fully, every day.
The plastic is out there, even in far-flung corners of the ocean. And the answer is not to be paralyzed by that fact, but to use it as fuel. Every sample we collected is now a data point in a larger story about where plastic comes from and where it goes. Every cleanup, every surface trawl, every street block walked and every hour spent at a microscope are parts of building the evidence base that informs policies, regulations and systems-level changes that can actually turn this crisis around.
Cleaning up beaches and coastlines is valuable and necessary work. But we also must stop plastic from entering the ocean in the first place—through stronger policy, better product design and real investment in waste management infrastructure everywhere. Luckily, when it comes to the most common microplastics in the ocean— microplastic fibers—there is already an effective, affordable solution to immediately reduce microplastics coming from our laundry by roughly 90%: washing machine filters. These filters act just like laundry lint filters in our dryers, capturing fibers in tightly-woven mesh and effectively preventing them from leaving our homes and leaking into the environment.
What can you do?
There’s no better time to tackle plastic pollution than right now, during Plastic Free July
! Take two minutes to add your name and call on your elected leaders to combat those pesky, dangerous microfibers that are pouring into our ocean daily—like the ones I found from my samples at sea. Together, we can stop plastic pollution at the source and protect our ocean forever and for everyone.
My biggest takeaways from this experience? People are remarkable. Our ocean is remarkable. And our ocean is worth fighting for, including from 70 feet of sailing vessel in the South Pacific, staring down a microscope with a pair of tweezers and a queasy stomach.
The eXXpedition South Pacific I voyage ran from April 27 to May 6, 2026, sailing from Auckland to the Bay of Islands. Learn more about the research team and our itinerary at https://exxpedition.com/voyage/auckland-to-bay-of-islands/.
The post Microplastic Pollution Research at Sea appeared first on Ocean Conservancy.
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