Washington D.C. –
The U.S. Naval Research Laboratory (NRL) is celebrating the 60th anniversary of its
Plasma Physics Division, marking six decades of scientific discovery that has advanced the understanding of plasma, and supported technologies critical to national defense, space science, and advanced materials.
Established in 1966, the division brought together researchers studying magnetic fusion, nuclear effects, space plasma physics, and the propagation of intense light and particle beams through the atmosphere. Early plasma research at NRL was strongly influenced by Cold War–era scientific challenges, including the need to understand the effects of high-altitude nuclear detonations on the Earth’s ionosphere. Such events could create large artificial plasma disturbances capable of disrupting radio communications, radar systems, and disabling critical satellites.
“Over time, NRL’s plasma scientists have expanded the scope of the Division,” said Joseph Peñano, Ph.D., superintendent of the NRL Plasma Physics Division. “Today, the Division works through its four research Branches that individually focus on laser-plasma interactions, space plasmas, pulsed power, and directed energy. We’ve developed new experimental facilities to simulate and test in complex environments, built theoretical and computational models to push the boundaries of our understanding, and created new technologies for the Navy that have influenced fields ranging from fusion energy to directed-energy weapons, and advanced materials engineering.”
A Research Culture Blending Science and Mission
From its earliest days, the Plasma Physics Division has balanced fundamental scientific inquiry with mission-focused research.
“I came to the NRL Plasma Physics Division as a postdoc in 1998 and met some of the most influential plasma physicists in the field,” Peñano said. “Everyone was passionate about the science they were advancing and proud of their service to the Nation. That ethic continues to this day. We do leading-edge research and are always thinking about how our discoveries support national security and the operational needs of the Navy now and in the future.”
Understanding Plasma and the Space Environment
Plasma, an electrically charged gas composed of ions and free electrons, is the most common state of matter in the universe. It makes up the Sun and stars, fills much of interplanetary space, and is responsible for the harsh, dynamic environment where satellites must reliably operate in Earth’s ionosphere and magnetosphere.
“Understanding the dynamic behavior of near-Earth space plasma and ultimately forecasting evolving hazardous conditions are critical for protecting valuable military and civilian satellites,” said William Amatucci, Ph.D., head of NRL’s Space and Laboratory Plasma Branch. “To help accomplish this, our Branch has built large-scale laboratory devices to simulate space conditions, designed and deployed advanced sensors in space, and developed theoretical and computer models to bridge the gap between laboratory and space and understand the fundamentals of space plasma behavior.”
Another growing threat to satellite operations is posed by the debris that litter space after more than half-a-century of space flight. These small particles move at such high velocities that a collision with a satellite can be mission ending. The Plasma Physics Division has developed novel concepts for both the detection and removal of these debris, which are frequently impossible to detect using existing methods.
“Speeding charged debris can create unique signatures in the plasma,” said Guru Ganguli, Ph.D., Plasma Physics Division senior scientist. “The plasma signatures can be much larger scale than the debris itself, presenting a unique opportunity for detecting, tracking, and ultimately removing it.”
High-Energy Density Physics and Pulsed Power
Among the division’s major contributions are advances in high-energy density plasma physics, the study of matter under extremely intense pressures, temperatures, and electromagnetic fields.
NRL researchers developed pulsed-power technologies such as the rod-pinch diode, reflex triode, and plasma radiation sources, devices capable of generating extremely intense bursts of X-rays. These technologies are used in taking x-ray photographs of materials in extreme environments, testing systems for radiation hardness, or studying how matter behaves at extremely high-pressure, specifically the “equation of state” of warm dense matter.
Such technologies have supported national laboratory programs studying the physics relevant to nuclear deterrence and strategic systems.
“Our researchers have developed and transitioned novel radiation sources for testing strategic systems and supporting hardware for the past 55 years, and will continue doing so with our newest facilities for the next 50 years,” said Joe Schumer, Ph.D., head of NRL’s Pulsed Power Branch.
Laser-Matter Interactions and Directed Energy
NRL scientists have also played an important role in the study of laser–matter interactions and directed energy, a field that examines how powerful laser beams propagate and interact with matter, often creating high energy particle beams and radiation.
“High power laser beams interact with matter through a wide range of physical processes,” said Daniel Gordon, Ph.D., head of NRL’s Directed Energy Physics Branch. “Interactions with air, water, and various materials, all have their own unique characteristics. We use that knowledge of laser-matter interactions to advance next-generation laser sources and beam control methods to enable shipboard missile defense and counter-UAS missions. To that end we have assembled several unique laser sources, developed AI-driven beam control to extend the range of our lasers, and constructed a mobile laboratory that can be used for field testing.”
NRL scientists first demonstrated and patented the concept of long-range incoherent laser beam combining, which enabled the development of the first shipboard laser weapon, the Navy’s Laser Weapon System (LaWS), and its deployment in 2014 aboard the USS Ponce.
One future-leaning concept that NRL is developing is the use of pulsed lasers for ship defense. “Pulsed laser systems have the potential to revolutionize the field,” says Michael Helle, Ph.D., NRL principal scientist for Directed Energy Physics. “High-power pulsed laser sources produce effects inaccessible to existing High Energy Laser systems, potentially increasing the number of threats neutralized and opening new mission spaces.”
Precision Materials Processing with Plasma
Another important research area is plasma-based materials processing, which uses ionized gases to precisely modify surfaces and manufacture advanced materials.
Plasma-based techniques are foundational in semiconductor manufacturing and utilized to produce the microelectronics found in products ranging from computers to cell phones. The never-ending need to continue developing novel materials and advanced devices necessitates a continuing effort in research and development of plasma systems, processes and novel material to produce critical, advanced materials for the Navy.
In the late 1990s, NRL researchers developed the
Large Area Plasma Processing Source (LAPPS), LAPPS enables modification of the surface of materials without damage to underlying layers in a way that conventional systems struggle to achieve. The system turned out to be well-suited to meet the demands of atomic-precision processing applications.
“The attributes of LAPPS allow one to modify the surface of materials without damage to underlying layers, which had always been a problem,” explained Scott Walton, Ph.D., head of NRL’s Plasma Applications Section. “This was a very exciting realization that allows us to explore the use of LAPPS in materials synthesis and modification needed to drive the next generation of materials and device development.”
Plasma Science and the Future of Fusion
NRL’s plasma expertise also plays a role in the rapidly growing field of fusion energy research. Fusion occurs when light atomic-nuclei combine to form heavier elements, releasing enormous amounts of energy, the same process that powers the Sun. Achieving controlled fusion on Earth has long been a major scientific goal. NRL scientists often collaborate with universities, national laboratories, and emerging private fusion companies seeking to develop practical fusion power systems.
The Plasma Physics Division’s deep expertise in fundamental plasma science and fusion research is now driving new capabilities and advanced systems for the future warfighter. Historically, this transition has often followed an indirect path. For example, electron beam technologies enabled the development of high-power excimer lasers, which in turn were used to generate highly controlled, uniform, high-pressure shock waves for fusion research. These same environments are now being leveraged to evaluate the Department of War (DoW) material performance in regimes that are otherwise difficult to reproduce, yet highly relevant to operational conditions in the battlespace.
"Decades of leadership in plasma physics, laser science, and pulsed-power technology enable NRL to transition knowledge and technology to industry in the pursuit of fusion energy, and to the DoW to advance its nuclear systems,” said Jason Bates, Ph.D., head of NRL’s Laser Plasma Branch.
New Facilities and Future Technologies
Today, NRL’s Plasma Physics Division continues to investigate a broad range of plasma phenomena, including laser-plasma interactions, pulsed-power driven radiation sources, space plasma dynamics, new approaches to directed-energy technologies, including pulsed lasers, and beam control, and electromagnetic launcher technology, railguns, that could provide future offensive and defensive capabilities for naval forces.
Future facilities such as the planned Gamble III pulsed-power system are expected to expand NRL’s ability to study high-energy plasma physics and support national programs related to nuclear deterrence and strategic systems.
Six Decades of Discovery
As the Plasma Physics Division enters its seventh decade, researchers say its enduring strength lies in bridging basic science and operational capabilities.
Its most significant discoveries enabled: high-power neodymium glass lasers that had a major impact on the U.S. laser fusion program; the flux-corrected transport method which enabled simulation tools used for urban defense against weapons of mass destruction; pulsed x-ray radiography to diagnose the performance of nuclear weapons; high-power, high-current pulsed-power generators for nuclear weapons effects simulation; high-energy excimer laser technology for fusion energy applications; and laser concepts that enabled the first operational shipboard laser weapon.
“Plasma research at NRL has always been about pushing the boundaries of physics to solve real-world problems in service to the Navy and the Nation,” Peñano said. “This is our 60-year legacy and we look forward to continuing the mission for the next 60 or more years.”
About the U.S. Naval Research Laboratory
NRL is a scientific and engineering command dedicated to research that drives innovative advances for the U.S. Navy and Marine Corps from the seafloor to space and in the information domain. NRL is located in Washington, D.C. with major field sites in Stennis Space Center, Mississippi; Key West, Florida; Monterey, California.
NRL offers several mechanisms for collaborating with the broader scientific community, within and outside of the Federal government. These include Cooperative Research and Development Agreements (CRADAs), LP-CRADAs, Educational Partnership Agreements, agreements under the authority of 10 USC 4892, licensing agreements, FAR contracts, and other applicable agreements.
For more information, contact NRL Corporate Communications at
NRLPAO@us.navy.mil.