Walter Munk was a Californian Oceanographer Who Changed Our Understanding of the Seas
From World War II research to wave prediction for modern surfing, the legendary oceanographer helped change the world and our understanding of the ocean.
California has long been shaped by bold, visionary individuals, yet some of its most transformative figures remain largely unknown. In our celebrity-obsessed culture, we too often overlook the scientists whose work has quietly made the world better. Walter Munk is one of them. Though not a household name, this pioneering oceanographer revolutionized our understanding of ocean currents, wave prediction, and climate science. He impacted everything from World War II military operations to today’s climate models. This article is part of a continuing series highlighting underrecognized Californians whose extraordinary contributions still ripple through our lives.
Walter Munk, often referred to as the “Einstein of the Oceans,” was one of the most influential oceanographers of the 20th century. Over a career that spanned more than 70 years, Munk fundamentally altered how we think about the oceans, contributing to our understanding of everything from wave prediction during World War II to deep-sea drilling in California. His work at the Scripps Institution of Oceanography in La Jolla, California, was groundbreaking and continues to influence scientific thinking to this day.
Walter Heinrich Munk was born in Vienna, Austria, on October 19, 1917. At 14, he moved to New York, where he later pursued physics at Columbia University. He became a U.S. citizen in 1939 and earned a bachelor's degree in physics from the California Institute of Technology the same year, followed by a master's in geophysics in 1940. Munk then attended the Scripps Institution of Oceanography and completed his Ph.D. in oceanography from the University of California Los Angeles in 1947.
In the early 1940s, Munk’s career took a defining turn when the United States entered World War II. At the time, predicting ocean conditions was largely guesswork, and this posed a significant challenge for military operations. Munk was recruited by the U.S. Army to solve a problem that could make or break military strategy: accurate wave prediction for amphibious landings.
One of his most famous contributions during the war came in 1944, ahead of the Allied invasion of Normandy. Alongside fellow oceanographer Harald Sverdrup, Munk developed a method to predict the size and timing of ocean waves, ensuring that troops could land safely during the D-Day invasion. Their breakthrough came from applying the physics of wind-wave generation. They realized that if you knew the wind speed, duration, and the distance over which the wind had blown (called "fetch"), you could calculate how large the waves would be. Then, by modeling how those waves traveled—how they refracted, dispersed, and broke as they reached the shore—they could predict surf height days in advance.
Using their model, the Allied forces delayed the invasion by one day, a move that proved crucial in reducing casualties and securing the beachhead. This same wave prediction work was used again in the Pacific theater, particularly for landings on islands like Iwo Jima and Eniwetok. Munk’s contributions not only helped win the war but also laid the foundation for modern oceanography. Wave forecasting is now a standard tool for naval operations, shipping, and even recreational surfers.
After the war, Munk returned to Scripps in San Diego, a place that would remain central to his career. Established in 1903, Scripps had been growing into a major center for oceanographic research, and Munk’s work helped elevate it to new heights. Located in La Jolla, just north of San Diego, Scripps was perfectly positioned on the California coastline to be at the forefront of oceanographic studies. Scripps remains one of the premier oceanographic institutions in the world…and is a lovely place to boot. (We’ll do a whole feature on Scripps at some point.)
During the post-war years, Munk helped pioneer several new areas of research, from the study of tides and currents to the mysteries of the deep sea. California, with its rich marine ecosystems and coastal access, became the perfect laboratory. In La Jolla, Munk studied the Southern California Current and waves that originated across the Pacific, bringing new understanding to local coastal erosion and long-term climate patterns like El Niño. His research had a direct impact on California’s relationship with its coastline, from naval operations to public policy concerning marine environments.
While Munk’s contributions to wave forecasting may be his most widely recognized work, one of his boldest projects came in the 1960s with Project Mohole. It was an ambitious scientific initiative to drill into the Earth’s mantle, the layer beneath the Earth’s crust. The project was named after the Mohorovičić Discontinuity (named after the pioneering Croatian seismologist Andrija Mohorovičić), the boundary between the Earth’s crust and mantle. The goal was revolutionary: to retrieve a sample from the Earth’s mantle, a feat never before attempted.
At the ocean floor the Earth’s crust is thinner than on land, and it was thought this would be the best place to reach the mantle, providing geologists with direct insights into the composition and dynamics of our planet. The project was largely conceived by American geologists and oceanographers, including Munk, who saw this as an opportunity to leapfrog the Soviet Union in the ongoing Cold War race for scientific supremacy.
California was again the backdrop for this audacious project. The drilling took place off the coast of Guadalupe Island, about 200 miles from the Mexican coast, and Scripps played a key role in organizing and coordinating the scientific work. The project succeeded in drilling deeper into the ocean floor than ever before, reaching 600 feet into the seabed. However, funding issues and technical challenges caused the U.S. Congress to abandon the project before the mantle could be reached. Despite its early end, Project Mohole is considered a precursor to modern deep-sea drilling efforts, and it helped pave the way for initiatives like the Integrated Ocean Drilling Program, which continues to explore the ocean’s depths today. And while an overall failure, certain very useful technologies were developed during the project and are still used widely today. For example, techniques for dynamic positioning for ships at sea were largely developed for the Mohole Project.
Munk’s work was deeply tied to California, a state whose coastlines and oceanography provided a wealth of data and opportunities for study. Scripps itself is perched on a stunning bluff overlooking the Pacific Ocean, a setting that greatly inspired Munk and his colleagues. Throughout his career, Munk worked on understanding the coastal dynamics of California, from studying the erosion patterns of beaches to analyzing how global warming might impact the state’s famous coastal cliffs. The erosion of California coastal cliffs remains a huge problem today.
Munk’s legacy continues to shape how California manages its vast coastline. The methodologies and insights he developed in wave prediction are now used in environmental and civil engineering projects that protect harbors, beaches, and coastal infrastructure from wave damage. As climate change accelerates the rate of sea level rise, Munk’s work on tides, ocean currents, and wave dynamics is more relevant than ever for California’s future.
Walter Munk’s contributions to oceanography stretched well beyond his wartime work and Project Mohole, earning him numerous awards and accolades. One of the most notable examples of this work was an experiment led by Munk to determine whether acoustics could be used to measure ocean temperatures on a global scale, offering insights into the effects of global warming. In 1991, Munk’s team transmitted low-frequency underwater acoustic signals from a remote site near Heard Island in the southern Indian Ocean. This location was strategically chosen because sound waves could travel along direct paths to listening stations in both the Pacific and Atlantic Oceans. The experiment proved successful, with signals detected as far away as Bermuda, New Zealand, and the U.S. West Coast. The time it took for the sound to travel was influenced by the temperature of the water, confirming the premise of the study. A more detailed explanation of these studies can be found in Helen Czerski’s excellent book The Blue Machine: How the Ocean Works, which I highly recommend.
Munk passed away in 2019 at the age of 101, but his influence lives on. His approach to science—marked by curiosity, boldness, and a willingness to take on complex, high-risk projects—remains an inspiration for generations of scientists. He was a giant not only in oceanography but also in shaping California’s role in global scientific innovation. As the state faces the challenges of a changing climate, Munk’s legacy as the “Einstein of the Oceans” continues to be felt along its shores and beyond.