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Degaussing

Degaussing is the process of reducing or eliminating a remnant magnetic field in a material by applying a strong, alternating magnetic field that randomizes magnetic domains, thereby neutralizing the overall magnetization. This technique, named after the gauss—a unit of magnetic flux density—disrupts the alignment of magnetic particles or domains within ferromagnetic materials, rendering any stored magnetic information unreadable or the object magnetically neutral. Originally developed for naval defense, degaussing has evolved into a critical method for secure data destruction and other applications requiring magnetic field control. The historical roots of degaussing trace back to , when it was pioneered to protect Allied ships from magnetic mines that detonated upon detecting a vessel's ferromagnetic signature. In late 1939, British scientists, including Charles Frederick Goodeve, analyzed a recovered magnetic mine from the and devised a system of electromagnetic coils wrapped around ship hulls to generate an opposing , effectively "deperming" the vessel. This innovation, implemented rapidly across the Royal Navy and shared with allies, significantly reduced mine detonations; ships underwent periodic degaussing every four to six months using specialized ranges equipped with magnetometers to measure and adjust their magnetic bias. By the war's end, degaussing stations had been established worldwide, saving countless lives and vessels from magnetic threats. In contemporary contexts, degaussing serves as a primary technique for , such as hard disk drives, magnetic tapes, and floppy disks, by applying a high-intensity —typically at least 30,000 gauss—to permanently alter magnetic domains and data to an unrecoverable state. According to standards from the National Institute of Standards and Technology (NIST), this method achieves ""-level , making infeasible even with advanced laboratory equipment, though it renders the unusable for reuse. The (NSA) evaluates degaussers for compliance, distinguishing between electromagnetic types (using electric currents for variable fields) and permanent magnet types (with fixed fields), ensuring they meet requirements for modern high-density like those using energy-assisted magnetic recording (EAMR). Limitations include its ineffectiveness on non-magnetic , such as solid-state drives, and the need for device-specific field strengths to avoid incomplete . Beyond and naval engineering, degaussing finds applications in scientific instruments, such as calibration and shielded room preparation, where residual fields must be minimized for precise measurements. It is also used in , like () monitors, to correct color distortions from or nearby magnets by briefly applying a decaying alternating field. These diverse uses underscore degaussing's enduring role in managing magnetic phenomena across military, industrial, and everyday technologies.

Fundamentals

Definition and Principles

Degaussing is the process of reducing or eliminating remnant in ferromagnetic materials by applying a reversing , which randomizes the alignment of magnetic domains to achieve near-zero net . The term derives from the gauss, of magnetic flux density. This technique targets the intrinsic magnetic properties of materials like iron or , where exposure to external fields during or use can induce persistent . At the core of degaussing are the principles of magnetic domains and hysteresis in ferromagnetic substances. Magnetic domains are microscopic regions within the material where atomic magnetic moments align uniformly, but in an unmagnetized state, these domains are oriented randomly, resulting in no net magnetic field. When an external magnetic field H is applied, domains aligned with the field grow at the expense of others, leading to overall magnetization M. Hysteresis manifests as the material's resistance to changes in magnetization; even after the external field is removed, some remnant magnetization persists due to the energy barriers (such as domain wall pinning) that maintain domain alignments. The relationship between the magnetic flux density B, the applied field H, and the material's magnetization M is given by the equation B = \mu_0 (H + M), where \mu_0 is the permeability of free space ($4\pi \times 10^{-7} H/m). In degaussing, the goal is to minimize M to near zero, effectively making B \approx \mu_0 H. The demagnetization occurs through the application of an alternating , typically generated by sinusoidal currents in electromagnetic coils, which produces an oscillating [H](/page/H+) field that repeatedly reverses direction. As the field amplitude decreases progressively (e.g., via or stepwise reduction), the material traverses a series of successively smaller loops. This process disrupts the coherent domain alignments: each reversal causes domain walls to move and domains to reorient, but with diminishing , the domains "freeze" in increasingly random configurations due to thermal agitation and pinning losses, ultimately yielding a randomized, low-net-magnetization state. The effectiveness of degaussing depends on several factors, including the material's —the magnetic field strength required to reduce M to zero, measured in oersteds () or amperes per meter (A/m). Materials with high , such as hard magnets, demand stronger reversing fields, typically at least equal to or exceeding the (often around twice for hard magnets), to overcome domain pinning. Additionally, plays a role; heating the material above its Curie point—the at which thermal energy randomizes atomic spins and destroys —facilitates degaussing by eliminating entirely, followed by controlled cooling in a low-field environment.

Historical Development

The concept of degaussing originated in the foundational work on during the , particularly through the contributions of , who in the early 1830s developed a systematic understanding of terrestrial magnetism and defined key units for measuring magnetic intensity, including what would later become the gauss as a unit of density. Gauss's investigations, conducted in collaboration with Wilhelm Weber starting in 1832, laid the groundwork for quantifying and recognizing the Earth's influence on ferromagnetic materials, setting the stage for later demagnetization techniques. Early demagnetization experiments in the late focused on thermal methods to disrupt magnetic alignment, as ferromagnetic materials lose their permanent when heated above a critical threshold. In 1895, demonstrated through precise experiments with strong magnets and balances that heating ferromagnets to their randomizes atomic magnetic moments, effectively demagnetizing the material; this principle of thermal demagnetization, involving the randomization of magnetic domains, became a cornerstone for subsequent techniques. In the early , demagnetization advanced with the invention of (AC) demagnetizers around the , designed for calibrating scientific instruments by applying a decaying AC to gradually reduce remnant magnetism without physical contact. These devices, often used in laboratories for loop measurements and material testing, represented a shift from thermal to electromagnetic methods, enabling non-destructive of magnetic signatures in precision tools. Pre-World War II experiments in , particularly by the British Admiralty, built on these foundations through tests on the magnetic signatures of steel ships, revealing how construction and Earth's field induced permanent that could be mitigated with encircling coils. Starting in 1937, systematic studies using scale models and full-scale ship trials led to initial designs for degaussing coils aimed at neutralizing vertical and longitudinal components of a vessel's field. Deperming techniques, involving exposure to intense magnetic fields from large electromagnets or, in some early cases, explosive shocks to jolt domains into disorder, were explored and refined in the , particularly from onward, in preparation for naval threats. By the late , laboratory-scale demagnetization methods transitioned to industrial applications, with AC-based coil systems scaled for larger structures like ships, enabling practical implementation through facilities and paving the way for widespread naval adoption.

Naval Applications

Degaussing

The development of degaussing for naval vessels accelerated during in response to the introduction of magnetic mines, which detonated upon detecting a ship's caused by its steel hull. A pivotal event occurred on November 23, 1939, when the first intact Type GA magnetic mine was recovered from the mudflats of the at , , after being dropped by parachute from a Luftwaffe seaplane; Lieutenant Commander John Ouvry of HMS Vernon successfully defused it, allowing British scientists to analyze its sensitive magnetic trigger mechanism and initiate urgent countermeasures research. This recovery, combined with the sinking of several British merchant vessels by magnetic mines in late 1939 and early 1940, underscored the immediate threat to Allied shipping, prompting the to prioritize demagnetization techniques to neutralize the mines' sensitivity to ships' induced and permanent magnetism. Key innovations emerged from Admiralty research led by physicist Charles F. Goodeve, who devised a system of large circumferential electrical coils installed around ship hulls to generate opposing that canceled out the vessel's signature. These included the Q coil, which addressed the vertical component of the ; the A coil for the longitudinal component; the M coil for the athwartship component; and the Y coil for additional adjustments, with coils energized by (DC) or low-frequency (AC) to dynamically match local geomagnetic variations and maintain neutrality. The coils were typically wound with non-magnetic cable and powered from the ship's generators, allowing continuous operation without significant interference to navigation. Implementation scaled rapidly under direction, with degaussing stations established across British ports; by mid-1940, over 1,000 ships had undergone "wiping" treatments at shore facilities, while an additional 2,000 vessels were fitted with onboard coil systems for ongoing protection. This effort, coordinated through scientific teams rather than a formal named committee, equipped the majority of the Royal Navy's steel-hulled fleet and key merchant ships, significantly reducing magnetic mine detonations and enabling safer operations in mine-infested waters. Following the U.S. entry into the war after the attack in December 1941, the U.S. Navy adopted the British degaussing methods, installing coils on its warships starting in early 1942 to counter similar threats in the Pacific and Atlantic theaters. Specific techniques included deperming, a one-time high-amperage treatment at specialized stations to erase permanent in a ship's , often using external generators delivering thousands of amperes in short bursts to reverse and neutralize residual fields. Facilities like HMS Vernon in served as central hubs for these operations, processing numerous vessels weekly through coordinated wiping and deperming procedures that combined precise magnetic measurements with coil energization to achieve fields reduced by factors of three or more. These wartime adaptations proved vital, saving countless ships from magnetic mine losses and restoring confidence in naval operations against Germany's mining campaigns.

Degaussing Ranges and Facilities

Degaussing ranges are specialized naval installations used to measure and calibrate the magnetic signatures of ships following degaussing procedures, ensuring their fields are sufficiently reduced to evade detection by magnetic sensors or mines. These facilities typically consist of sensor arrays, including arrays of magnetometers, deployed in controlled waterways such as harbors or basins to capture detailed mappings of a ship's across three dimensions: the vertical (V), transverse (T), and longitudinal (L) components. The setup allows for precise as the vessel transits over the sensors, providing a comprehensive profile of induced and permanent magnetic influences from the and . Originating from World War II efforts to protect Allied vessels from magnetic mines, degaussing ranges have evolved into essential infrastructure for modern navies. A prominent historical example is the Bedford Basin Degaussing Range in Halifax, Canada, established in 1940 as the first such facility in and still operational in 2025 for signature measurements and calibrations. In the United States, key facilities include the Magnetic Silencing Degaussing Range in , which supports degaussing for U.S. Navy and allied vessels, and the Degaussing Range at , , focused on assessing submerged sensor conditions and magnetic data. The operational process requires ships to pass over the range at controlled speeds, often multiple times in varying orientations, to generate accurate signature profiles for analysis. Calibration at these ranges involves analyzing the collected magnetic data to adjust degaussing coil currents and ampere-turns, neutralizing the ship's induced magnetization and minimizing its overall signature to levels below typical magnetic mine activation thresholds. For example, reductions target signatures under 50 nT at 100 meters for many systems, though exact limits depend on operational requirements and threat profiles. Due to ongoing changes in a ship's magnetic properties—such as those caused by hull steel stress from voyages, repairs, or environmental exposure—vessels generally require annual re-calibration to maintain effectiveness. Contemporary degaussing ranges have incorporated advancements like GPS integration for precise transit tracking and automated networks for efficient, processing and analysis. These enhancements support compliance with standards, including those under the Foreign Acoustic, Magnetic, and Electric Ranging Calibration (FORACS), which ensures standardized calibration for and surface ships across allied forces.

Advanced Superconducting Techniques

Advanced superconducting techniques in naval degaussing leverage high-temperature superconductors (HTS), such as (YBCO), which exhibit zero electrical resistance at temperatures achievable with cooling (77 K or -196°C). These materials enable the creation of degaussing coils that support persistent currents, allowing stable magnetic fields to be maintained without continuous power input once induced. In persistent mode operation, the current I in a closed superconducting loop is given by I = \frac{\Phi}{L}, where \Phi is the magnetic flux trapped in the loop and L is the inductance of the coil. This capability is particularly advantageous for generating the precise, counteracting fields needed to neutralize a ship's magnetic signature against mines and sensors. Research into HTS for degaussing began in the 1990s as part of broader U.S. Navy efforts to explore superconductivity for naval applications, with focused studies on degaussing systems emerging in the early 2000s. Prototypes were tested in the mid-2000s, culminating in successful sea trials on the USS Higgins (DDG-76) in 2008, where HTS coils demonstrated approximately 90% reduction in installed cable length compared to traditional copper systems, leading to substantial energy savings. These tests, conducted in collaboration with American Superconductor Corporation (AMSC), validated the use of YBCO-based HTS wires for shipboard environments. The primary advantages of HTS degaussing systems include significant weight reductions—critical for and surface vessels—due to the higher of superconductors (up to 10,000 A/mm²) compared to . Zero resistance ensures highly stable fields with minimal power dissipation, enhancing and reducing the thermal signature. Additionally, the compact design lowers overall system volume, allowing for easier integration into modern hulls. As of 2025, HTS degaussing systems are being integrated into select U.S. Navy vessels, including the San Antonio-class amphibious transport docks, with prototypes demonstrated and ongoing expansions to allied navies, such as a June 2024 AMSC contract valued at $75 million for the Canadian Navy with first delivery in 2026. Despite these advances, challenges persist, particularly in developing reliable cryogenic cooling systems using liquid nitrogen to maintain superconductivity under dynamic shipboard conditions, including vibrations and temperature fluctuations.

Electronic Applications

Cathode-Ray Tube Displays

In color () displays, degaussing corrects magnetic distortions that misalign beams from the , , and guns, ensuring they strike the appropriate dots on the screen for accurate color reproduction. External , such as the Earth's geomagnetic field or those from nearby speakers and magnets, deflect these high-velocity beams, causing them to land off-target and produce color fringing or impurities visible as rainbow-like distortions across the . The —a perforated metal sheet positioned between the guns and the phosphor screen—can also become magnetized by these fields, further shifting beam paths and degrading image purity by allowing to illuminate adjacent phosphors. To counteract this, degaussing generates a controlled, decaying alternating via dedicated coils, which demagnetizes the and neutralizes residual , restoring beam alignment without introducing new distortions. Most color CRTs incorporate an automatic degaussing system that activates upon power-up after the device has been off for about 15-20 minutes, preventing unnecessary cycling that could overheat components. A degaussing , typically wound with 100 or more turns of wire around the perimeter of the CRT's front faceplate, receives () at the local line of 50 or 60 Hz from the power supply. A positive (PTC) in series with the coil initially allows high to , creating a strong reversing that randomizes magnetic domains in the shadow mask; as the thermistor heats up over 5-20 seconds, its increases exponentially, causing the field to decay gradually and leaving the mask in a neutral state. This process, which relies on the principles of alternating field demagnetization to reduce , ensures color purity without manual intervention in standard operation. For cases of severe contamination, such as after exposure to strong magnets, manual degaussing employs a handheld electromagnetic or external ; the operator powers the device and moves it slowly in expanding circular patterns around the CRT face from close proximity (about 6-12 inches) outward to several feet, allowing the field to diminish progressively to avoid re-magnetizing the . Degaussing became essential for color televisions and computer monitors during the and , as CRT sizes grew to 20-32 inches and became more sensitive to geomagnetic variations, which could otherwise cause persistent purity errors in everyday orientations. By the , automatic degaussing circuits were ubiquitous in high-quality devices, reflecting advancements in integrated that made manual correction rare except for professional servicing. The applied fields are calibrated to low strengths—starting just above the Earth's horizontal component of 0.16-0.27 gauss in typical regions—to effectively neutralize interference while preventing mechanical stress on the delicate , which could warp under excessive force and cause irreversible misconvergence. Failure to degauss periodically, especially after relocating a or exposing it to strong fields, results in permanent of the shadow mask, leading to fixed color bleed, patches of impure hues, or overall screen discoloration that automatic cycles cannot fully resolve. These effects stem from uncorrected beam deflections that misalign the landing points, producing visible purity errors across the display and potentially requiring adjustments or placement for correction in extreme cases.

Monitor and Television Degaussing Procedures

Degaussing procedures for monitors and televisions primarily target (CRT) displays, where external magnetic fields can cause color impurities and distortions by deflecting the electron beam. For most consumer CRT models from the late , the process begins with the built-in degaussing circuit, which activates automatically upon powering on after a period of being off. To initiate this, turn off the or and unplug it for at least 20-30 minutes to allow cooling and dissipation of residual fields; then plug it back in and power on while pressing the degauss button or access the on-screen menu option if available, typically indicated by a buzzing or slight screen flicker as the coil demagnetizes the tube. Repeat the power cycle 2-3 times if initial distortions persist, ensuring each off period is at least 20 minutes to prevent overheating the internal components. For older CRT models without reliable built-in degaussing or persistent issues, external tools are employed. Position the degausser 6-12 inches from the screen surface, power it on, and slowly rotate it in a around the front of the display, starting from the center and moving outward to the edges over 10-15 seconds; then gradually pull it away to at least 3 feet while keeping it active until the end to avoid re-magnetization. off the display during this process and perform it only when the unit is at for optimal results. Handheld solenoid wands serve as common external tools for consumer degaussing, often AC-powered with relative magnetic fields around 70 millitesla (equivalent to approximately 700 gauss) and limited to under 3 minutes of continuous use to prevent warming. Battery-powered variants exist for portability, though they typically deliver lower outputs suitable for minor corrections. For high-end or professional-grade monitors, such as those in or , consult specialized service technicians who use calibrated equipment to avoid risks like overheating the housing, which can warp under prolonged exposure to heat-generating coils. Always wear protective gloves and keep the tool away from pacemakers or sensitive , as the strong fields can interfere with nearby devices. Common issues prompting degaussing include color distortions appearing after relocating the device, often due to transport-induced from vehicles or Earth's varying fields altering the CRT's magnetic state. In environments with high magnetic interference, such as proximity to unshielded speakers or subwoofers, purity problems may recur; experts recommend checking and degaussing monthly if distortions are observed, though only as needed to avoid unnecessary wear on the circuits. Since the , the need for these procedures has declined sharply with the widespread adoption of flat-panel LCD and LED televisions, which are immune to magnetic distortions. However, degaussing remains relevant as of 2025 for maintaining vintage equipment in retro , arcade , and specialized applications where authentic displays are preferred, driven by trends in low-latency retro setups.

Data Storage Applications

Magnetic Media Erasure

Degaussing serves as a critical method for securely erasing data from hard disk drives (HDDs) by applying a strong that disrupts the magnetic domains on the platters, including servo tracks and encoded data bits, thereby rendering the information irrecoverable through any known recovery techniques. This process is exclusively effective for media like HDDs and does not apply to non-magnetic devices such as solid-state drives (SSDs). The randomization of magnetic domains ensures that original data patterns are lost beyond forensic reconstruction. In practice, degaussing involves exposing the HDD to pulses from a compliant degausser, with NSA/CSS Policy Manual 9-12 requiring the use of devices from the NSA Evaluated Products List to achieve sanitization. These degaussers must generate a minimum magnetic field of 30,000 gauss across the media chamber to effectively erase data on commercial HDDs, exceeding the coercivity of typical platters. For HDDs employing perpendicular magnetic recording—introduced commercially around 2006—the erasure is irreversible, as the high field strength permanently aligns domains to noise levels, preventing data restoration. Modern HDDs often have coercivities around 5,000 oersteds (Oe) or higher, necessitating degaussing fields exceeding the platter's coercivity, typically 4,000–7,000 Oe for effective erasure. The advantages of degaussing include its speed, typically completing in seconds per drive, and its reliability in making unrecoverable without physical disassembly. However, it renders the HDD inoperable by damaging servo tracks and magnetic alignment, prohibiting reuse and generating . This destruction of functionality contrasts with less invasive methods but aligns with high-security needs where recoverability must be zero. As of 2025, degaussing remains a standard practice in data centers for sanitizing end-of-life HDDs, often integrated with physical to provide layered assurance in with NIST Special Publication 800-88, which classifies it as a "" technique for magnetic . For advanced technologies like (HAMR) introduced in 2023, degaussers must provide fields exceeding 10,000 Oe to match higher coercivities, with NSA approving specialized models as of 2025. This combination ensures triple-level security for sensitive data disposal amid rising e-waste volumes.

Analog Tape Demagnetization

Degaussing analog tapes involves the application of an (AC) to randomize the orientation of magnetic particles in the tape's layer, effectively erasing residual signals, accumulated hiss, and any unintended that can degrade audio or video . This process targets the ferromagnetic particles coated on the , which retain low-level magnetism from previous recordings or environmental exposure, leading to increased and reduced signal fidelity. Bulk erasers generate a continuous AC field, typically at line frequencies around 50-60 Hz, that is passed over the path to achieve thorough demagnetization without leaving a . The field strength required is generally in the range of 200-500 gauss to ensure at least 60-90 of erasure depth, randomizing particle alignment to restore the to a neutral state suitable for rerecording. In professional analog tape recorders, degaussing procedures often include built-in head demagnetizers to prevent magnetization of playback, record, and erase heads, which can otherwise imprint stray fields onto the tape during operation. For instance, professional decks from the mid-20th century featured dedicated head degaussers, such as handheld units designed for precise application along the tape path without contacting sensitive components. Manual bulk erasers are commonly used for cassettes and tapes, where the media is slowly passed through or near the eraser's field to avoid uneven ; these devices require careful handling to ensure the tape remains at a consistent distance (typically 1-2 inches) from the coil for optimal results. In environments, such procedures became standard by the as adoption grew for audio production, helping maintain in multi-generation workflows. The primary benefit of degaussing analog tapes is the restoration of by eliminating low-level from residual , which can otherwise mask quiet signals and limit the effective to below 60 in untreated media. In the 2020s, demagnetizing tape heads has seen a revival among analog audio restoration enthusiasts and vinyl/ collectors, who employ it as part of routine to ensure clear playback on modernized decks, preserving the medium's warm sonic characteristics amid a broader resurgence in analog formats.

Degaussing Equipment

Electromagnetic Degaussers

Electromagnetic degaussers generate alternating magnetic fields through electrically powered coils to demagnetize ferromagnetic materials or erase data from magnetic media. These devices commonly utilize solenoid coils, which produce a uniform field along their axis, or pairs, consisting of two identical circular coils separated by a equal to their radius to achieve enhanced field uniformity in a central region. The coils are energized either by (AC) sources for sustained operation or by high-voltage capacitors for pulsed discharge, following the principle of AC demagnetization where the field's amplitude is gradually reduced to randomize magnetic domains. In pulse-type electromagnetic degaussers, capacitors are charged to several kilovolts and discharged rapidly through the , delivering a high-energy electromagnetic burst typically lasting a fraction of a second to effectively sanitize without prolonged exposure. For instance, models like the EMP1000 achieve peak coercive forces of up to 20,000 gauss (2 ) via capacitive discharge, enabling efficient erasure of hard disk drives and tapes. Continuous-wave variants, powered directly by line (e.g., 60 Hz), employ fixed or rotating assemblies to ensure uniform field exposure over larger volumes or moving objects, with output fields typically reaching 1-2 depending on and input. These degaussers find versatile applications in laboratory settings for calibrating magnetic sensors, in secure data erasure for magnetic storage devices compliant with standards like NSA specifications requiring a minimum of 30,000 gauss to sanitize media with coercivity up to 5,000 oersteds, as listed in the NSA/CSS Evaluated Products List (EPL) as of January 2025, and in calibration processes for sensitive equipment. As of January 2025, the NSA/CSS EPL lists only electromagnetic degaussers for sanitizing magnetic media up to 5,000 oersteds coercivity; degaussing is not approved for EAMR or HAMR media without subsequent physical destruction. Safety features are integral, including interlock switches that disable operation if access panels are open, preventing unintended exposure to strong fields that could affect pacemakers or cause injury, along with emergency stops and shielding to contain stray fields below hazardous levels.

Permanent Magnet Degaussers

Permanent magnet degaussers are non-powered devices that utilize arrays of high-strength rare-earth magnets, such as neodymium-iron-boron (NdFeB) or samarium-cobalt (SmCo), to generate magnetic fields typically ranging from 1 to 2 tesla for demagnetizing objects. These magnets are arranged in specific configurations, often in linear or curved arrays positioned near a media path, to produce varying field gradients when the device or target is moved relative to the array, thereby randomizing magnetic domains through exposure to changing field directions. Neodymium magnets, in particular, offer high remanence up to 1.4 tesla at room temperature, enabling compact designs suitable for portable applications. In operation, these degaussers involve manual or motorized sweeps of the magnet array over the surface of the target object, ensuring close proximity—often near-direct contact—to maximize field exposure and achieve effective demagnetization. They are particularly suited for small items, such as hand tools, audio/video tapes, or small media like floppy disks, where exposure times typically range from 5 to 30 seconds suffice to disrupt remnant up to 1100 oersteds in . For tapes, the device is swept along the length or rotated around the spool to ensure uniform field application without unwinding the media. The primary advantages of permanent magnet degaussers include their portability and lack of need for an external power source, making them ideal for fieldwork or environments without electrical access, while their simple mechanical design allows for straightforward use without complex setup. However, limitations arise from the static of the field, resulting in less demagnetization for larger or irregularly shaped objects, as the magnetic field strength decays rapidly with distance according to the for dipole approximations in close range. This distance-dependent attenuation restricts their effectiveness to smaller-scale applications compared to powered alternatives. Common use cases encompass field maintenance for magnetometers, where metallic components are demagnetized to minimize in precise measurements, and pre-degaussing preparations in settings for tools or sensors to ensure accurate experimental conditions. As of 2025, permanent magnet degaussers are not included in the NSA/CSS Evaluated Products for magnetic , with electromagnetic types preferred for high-security applications due to higher and more uniform fields.

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