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Parker Solar Probe

The Parker Solar Probe is a spacecraft launched on August 12, 2018, from , aboard a rocket, designed to revolutionize understanding of by repeatedly flying through its outer atmosphere, or , at distances as close as 3.8 million miles (6.2 million kilometers) from the solar surface—closer than any prior human-made object. Named in honor of pioneering solar astrophysicist Eugene N. Parker, who theorized the existence of in the 1950s, the probe employs a revolutionary capable of withstanding temperatures up to 2,500°F (1,377°C) and speeds reaching approximately 430,000 miles per hour (692,000 kilometers per hour), making it the fastest human-created object relative to . The mission's primary objectives are to trace the flow of that heats the to millions of degrees—far hotter than the Sun's surface—investigate the origins and of the , and explore the mechanisms behind the of energetic particles that can disrupt technology on through events. Equipped with four instrument suites—FIELDS for measuring electric and , Integrated Investigation of the Sun (IS☉IS) for detecting particles across a wide range, Solar Wind Electrons Alphas and Protons (SWEAP) for sampling , and Wide-field Imager for Solar Probe (WISPR) for imaging the and —the probe collects data during its 24 planned orbits, using seven Venus gravity assists to gradually tighten its solar orbit over the nominal seven-year primary ending in 2025. Key achievements include the historic first entry into the corona on April 28, 2021, confirming the existence of a boundary layer called the Alfvén surface where solar wind becomes supersonic, and subsequent flybys that have set records for proximity and speed while revealing unexpected structures like "switchbacks" in the solar wind. As of November 2025, the probe has completed its 25th close approach to the Sun on September 15, 2025, at the record distance of 3.8 million miles, and remains in excellent health, with NASA reviewing options for an extended mission beyond the primary phase to conduct even closer passes in 2026 and beyond.

Mission Overview

Objectives

The Parker Solar Probe is designed to address fundamental questions about the Sun's outer atmosphere by tracing the flow of energy that heats the to millions of degrees , far exceeding the temperature of the Sun's surface. A primary is to determine the mechanisms driving this "coronal heating problem," through direct measurements of , waves, and particle distributions within the itself. Another core goal is to understand the acceleration of the , particularly how it transitions from subsonic speeds near to supersonic velocities farther out, by examining the energy transfer processes in the and inner . The mission aims to explore the origins and dynamics of this flow, which influences throughout the solar system. Additionally, the probe seeks to investigate the energization of high-energy particles near , including their sources and interactions with the solar environment. To achieve these objectives, the Parker Solar Probe conducts in-situ observations during close approaches to , targeting measurements that reveal the physical processes unresolved by from Earth-orbiting observatories. The seven-year primary mission encompasses 24 perihelion passes, progressively reducing the spacecraft's closest approach distance from an initial 24.8 million kilometers to a final 6.1 million kilometers from the solar surface, enabling unprecedented proximity to the .

Scientific Importance

The Parker Solar Probe plays a pivotal role in by directly addressing enduring mysteries of , particularly the coronal heating problem, where the Sun's outer atmosphere reaches temperatures of millions of degrees —far hotter than the surface's approximately 6,000 —despite being farther from the energy source. By flying through the , the mission samples freshly accelerated particles and at their origin, providing unprecedented in-situ data that ground-based or distant observations cannot capture, thus enabling breakthroughs in understanding energy transfer mechanisms in solar . This work builds on decades of theoretical and remote-sensing efforts, offering direct tests of models for wave propagation, , and that heat the . The mission's insights into solar wind acceleration and dynamics have profound applications for space weather forecasting, enhancing predictions of how solar eruptions disrupt Earth's magnetosphere, damage satellites, endanger astronauts, and induce geomagnetic storms that threaten power grids and communication systems. Data from the probe traces the origins of solar wind streams, revealing their fine-scale structures and switchbacks, which improve models for propagation from the Sun to Earth, potentially reducing economic losses from space weather events estimated in billions annually. Beyond Earth, these findings extend to stellar astrophysics, informing how similar processes drive winds and activity in other Sun-like stars, aiding interpretations of exoplanet habitability and galactic magnetic fields. As the first to enter and sample the Sun's , the Parker Solar Probe achieved pioneering feats, including perihelion speeds of up to 192 km/s—making it the fastest human-made object—and enduring surface temperatures of 1,370°C on its while keeping instruments at . These accomplishments, enabled by innovative like the carbon-composite and Venus gravity assists, have set new benchmarks for extreme-environment exploration, inspiring future missions to other and planetary atmospheres. In recognition of these advances, the mission team, including , Johns Hopkins , and partners, received the 2024 Robert J. Collier Trophy in March 2025 for the greatest achievement in or .

Development and History

Proposal and Approval

The concept for a solar probe mission originated in 1958, when astrophysicist Eugene Parker proposed the existence of a continuous stream of charged particles emanating from , now known as the , in his seminal paper published in . This theoretical framework highlighted the need for in-situ measurements near the Sun to verify and study the phenomenon, laying the groundwork for a dedicated to approach the solar corona. The idea was initially discussed by the Space Science Board's Simpson Committee in October 1958, which recommended a solar probe as a priority for early efforts. The mission concept was revived in the late 2000s as part of NASA's Living With a Star (LWS) program, aimed at understanding the Sun's influence on the solar system and Earth. In 2008, the (JHU/APL) conducted an initial engineering study to assess feasibility, building on prior mission concepts from the and early that had been deferred due to technological and budgetary constraints. issued an Announcement of Opportunity in December 2009, soliciting proposals for the renamed Solar Probe Plus mission, which sought to address key questions through close solar encounters. In September 2010, selected Solar Probe Plus for full development following a competitive of proposals, with JHU/ designated as the principal investigator institution responsible for mission management, spacecraft design, and operations. The approval came with an estimated total mission cost of $1.5 billion, covering development, launch, and operations through the primary seven-year mission phase. On May 31, 2017, Administrator announced the renaming of the mission to the Parker Solar Probe, honoring Eugene Parker for his pioneering theory and marking the first time a was named for a living individual. This decision underscored the mission's scientific roots in Parker's foundational work, which had faced initial skepticism but was later confirmed by observations from earlier like in 1962.

Design, Construction, and Testing

Development of the Parker Solar Probe began in September 2010 when selected the mission as part of its Living with a Star program. The (APL) served as the prime contractor, responsible for overall spacecraft design, integration, and operations under oversight. Key partners included for program management, the for instrument contributions such as the FIELDS suite, and additional collaborators like the Naval Research Laboratory, , , , and , along with international partners supporting scientific objectives. Assembly of the spacecraft commenced at APL in 2015 following approval for advanced development, with major structural and systems integration occurring through 2017. Instrument integration, including delivery and installation of science payloads, took place primarily from 2016 to 2017, ensuring compatibility with the spacecraft's core bus before final encapsulation. Engineering challenges centered on enabling operations in extreme solar proximity, where the spacecraft would face intense solar radiation and particle environments, necessitating radiation-hardened electronics to protect against particle damage and single-event upsets. Additionally, the design incorporated robust autonomous operations to handle faults independently, given the approximately 16-minute round-trip communication delay with Earth during perihelion, allowing the probe to detect anomalies, adjust attitude, and recover without ground intervention. Pre-launch testing began with the spacecraft's relocation from APL to in December 2017 for environmental qualification. Phases included vibration and acoustic testing in Goddard's facilities to simulate launch stresses from the rocket, reaching up to 150 decibels; thermal vacuum testing to verify performance in space-like conditions, including simulated solar heating; and assessments to ensure no interference among systems. Full spacecraft environmental testing spanned 2017 to 2018, culminating in successful validation of the probe's resilience ahead of its August 2018 launch.

Spacecraft Design

Structure and Thermal Protection

The Parker Solar Probe features a compact structure designed for extreme solar proximity, with an overall height of approximately 3 meters and a width of 2.3 meters at the , while the main body diameter below the protection system measures about 1 meter; its launch mass totaled 685 kilograms. The employs a lightweight aluminum honeycomb frame for , consisting of hexagonal panels that support the instrument vault positioned directly behind the to shield sensitive components from solar radiation and heat. This vault houses the and scientific payload in a protected environment, minimizing exposure to the harsh environment during perihelion passes. Central to the spacecraft's survival is its Thermal Protection System (TPS), a 2.3-meter-diameter made of a carbon-carbon composite with a carbon foam core—composed of 97% air for low —and coated in a white ceramic paint on the sun-facing side to reflect radiation. The , which is 11.43 centimeters thick and weighs 73 kilograms, is engineered to endure temperatures up to 1,370°C on its exterior during closest approaches, while maintaining the interior vault at around 30°C through minimal conduction at six attachment points to the truss structure. This design enables the probe to achieve unprecedented distances of about 6.2 million kilometers, where intensity reaches 475 times that at orbit. Thermal management relies on passive elements, including (MLI) blankets to reduce radiative . These systems, integrated with the TPS, ensure operational stability by isolating the spacecraft's core from external extremes, preventing overheating of electronics and maintaining performance throughout the mission's 24 planned orbits.

Power, Propulsion, and Avionics

The Parker Solar Probe's power system relies on two deployable arrays to generate in the extreme solar environment. These arrays, each measuring approximately 1.1 by 0.7 , provide a total collecting area of 1.6 square meters and can produce up to 388 watts of power, depending on their orientation and distance from . To manage intense heat near perihelion, the arrays feature via a -based system that circulates deionized through channels, dissipating excess while maintaining operational efficiency; they are also tilted away from direct solar exposure during close approaches to limit power output and prevent overheating. Complementing the arrays, lithium-ion batteries supply power during periods when the arrays are stowed or unavailable, such as shortly after launch or rare events in the spacecraft's orbit. The spacecraft employs a blowdown monopropellant propulsion system using for attitude control, momentum management, and trajectory correction maneuvers, without a dedicated main for primary insertion, which is achieved via assists. This system includes 12 thrusters, each delivering 4.4 newtons of thrust, fed from a central tank holding 82 kilograms of . The ensures reliable operation over the mission's duration, with the thrusters having executed multiple corrections, consuming only about 7.6 kilograms of through the first five years of flight while maintaining precise pointing for scientific observations. Avionics on the Parker Solar Probe are built for and resilience to high-radiation conditions, centered on the Applied Physics Laboratory's Integrated Electronics Module (IEM), which houses radiation-hardened processors in a triple-redundant configuration: a prime unit, , and backup. This setup supports command and data handling, integrating inputs from star trackers, inertial measurement units, and seven sun sensors to enable precise attitude determination and control via reaction wheels and thrusters. Communications occur over X-band frequencies using two cross-strapped transponders, with a 0.6-meter high-gain enabling science data downlinks at rates up to 8.3 megabits per second, supplemented by fan-beam and low-gain antennas for command uplinks and during off-Earth-pointing periods; all interactions route through 's Deep Space Network. Autonomy is a core feature, with an onboard fault protection system that autonomously detects anomalies, sequences commands, and executes safe-mode recoveries during the 24 planned perihelion passes when real-time communication with Earth is unavailable for up to several weeks.

Scientific Instruments

In-situ Instruments

The in-situ instruments on the Parker Solar Probe directly sample the , particles, and fields in the solar corona and inner , providing essential data on the local environment during close solar approaches. These instruments, comprising the FIELDS suite, the Solar Wind Electrons Alphas and Protons (SWEAP) , and the Integrated Science Investigation of the Sun (ISʘIS), are designed to withstand extreme temperatures and while capturing high-fidelity measurements of electromagnetic fields, properties, and energetic particles. The FIELDS instrument suite measures electric and magnetic fields from DC to 7 MHz, enabling studies of plasma waves, turbulence, shocks, and magnetic reconnection in the solar atmosphere. It includes five antennas—four 2-meter niobium alloy dipoles exposed to sunlight (withstanding up to 2,500°F) and one monopole in the spacecraft's shadow—for electric field detection, along with three magnetometers: two fluxgate sensors (MAGi and MAGo) for low-frequency magnetic fields up to ±65,536 nT and a search-coil magnetometer (SCM) for frequencies from 10 Hz to 1 MHz. These components allow coordinated observations of field fluctuations, plasma density profiles (inferred from spacecraft potential and wave modes), and electron temperatures, with the suite operating in sunlight and umbra configurations to optimize plasma coupling via bias currents. The SWEAP investigation uses Faraday cups and electrostatic analyzers to measure the velocity distribution functions of solar wind electrons, protons, and helium ions (alphas), covering energies from a few to tens of keV, and determines bulk velocities, densities, and temperatures with uncertainties below 20% and 1% for flows, respectively. Its components include the sun-pointing (SPC), a with four collectors and a 60° for one-dimensional flux measurements, and two (SPAN) units: SPAN-A (ram-side, for ions and electrons with time-of-flight mass/charge sorting) and SPAN-B (anti-ram electron analyzer), both providing three-dimensional distributions with high angular and energy resolution. This setup resolves anisotropies and species composition, essential for understanding origins. ISʘIS detects energetic particles to trace their acceleration, transport, and injection into the , measuring electrons from 20 keV to 6 MeV and ions (including protons, ³He, ⁴He, and heavier species up to iron) from 20 keV/nuc to 200 MeV/nuc. The features two Energetic Particle Instruments: EPI-Lo, with 80 viewing elements using solid-state detectors and time-of-flight for low-energy spectra, , and angular distributions; and EPI-Hi, a stack of silicon telescopes for higher energies, capable of processing up to 100,000 particles per second. These detectors provide full-sky coverage and resolve particle trajectories, linking suprathermal to high-energy populations. During perihelion encounters, the in-situ instruments switch to high-rate operational modes to maximize in the dynamic near-Sun , capturing density and strength variations at elevated cadences. FIELDS' SCM achieves 2 million samples per second for wave spectra, while SWEAP's records 146 measurements per second for ion fluxes, and ISʘIS processes particle events at peak rates, ensuring comprehensive sampling of short-lived phenomena like bursts despite the brief windows below 20 solar radii.

Remote Sensing Instruments

The Wide-Field Imager for Parker Solar Probe (WISPR) is the sole instrument on the , consisting of two nested coronagraph-style s that capture visible-light images of the and inner . The inner provides a 40-degree extending from approximately 13.5° to 53° from , while the outer covers a 58-degree from 50° to 108° , together enabling imaging of structures as close as 40 solar radii from the Sun's center. Equipped with radiation-hardened 2048 × 1920 pixel detectors, WISPR operates in white light, detecting Thomson-scattered light from free electrons in the and , with a nominal of about 6.4 arcminutes per pixel that improves to under 2 arcminutes when binning is applied. Operationally, WISPR conducts synoptic imaging during 10-day windows centered on the spacecraft's perihelion passages, capturing high-cadence sequences—up to 1 image per second at closest approach—to observe the evolution of solar wind streams, coronal mass ejections, and other dynamic features like sungrazing comets as the probe flies through them. Data from each orbit totals around 23 gigabits, which is compressed using techniques such as pixel binning and JPEG-style encoding to fit downlink constraints, with flexible electronics allowing summation of multiple exposures for improved signal-to-noise ratio farther from the Sun. Calibration occurs pre- and post-perihelion using onboard LED lamps and standard stars visible in the field of view, achieving photometric accuracy of about 3%. WISPR's ram-side mounting on the provides a unique capability to image the "" from within the , offering the first direct visual linkage between large-scale heliospheric structures and complementary measurements of and fields. This perspective, achieved as close as 8.5 solar radii during later orbits, resolves fine-scale coronal features and tracks their 3D evolution over co-rotation periods lasting hours to days.

Launch and Trajectory

Launch and Initial Orbit

The Parker Solar Probe launched on , , at 3:31 a.m. EDT from Space Launch Complex 37B at Air Force Station in aboard a rocket. The payload fairing separated approximately 6 minutes after liftoff, exposing the to . The rocket performed nominally throughout ascent, with the side boosters jettisoning at T+3:58, the core stage separating at T+5:42, and the spacecraft deploying from the third stage Star 48BV motor at T+43:18. The launch achieved on a with a () of 154 km²/s², equivalent to a hyperbolic excess velocity of approximately 12.4 km/s relative to , placing the probe on course for its initial solar orbit. No anomalies were reported during the ascent or separation phases, confirming the rocket's successful delivery of the 685-kilogram . The initial trajectory targeted the first on October 3, 2018, at an altitude of about 1,500 miles (2,400 kilometers) above the planet's surface, which adjusted the probe's path for subsequent solar encounters. Post-launch commissioning began immediately after separation, with the solar arrays deploying successfully within hours to provide power. By early September 2018, key activities included a trajectory correction maneuver on August 31, deployment of the FIELDS instrument antennas on September 2, activation of the SWEAP suite's Solar Probe Cup and SPAN sensors, and power-on checks for the ISʘIS energetic particle instruments and WISPR imager. Initial health and status checks through September confirmed all subsystems operated nominally, with the spacecraft traveling at over 44,700 mph (20 km/s) en route to Venus.

Gravity Assists and Orbital Evolution

The Parker Solar Probe mission relies on a strategy of seven Venus gravity assists to gradually reshape its highly elliptical orbit, enabling progressively closer approaches to the Sun without expending significant onboard propellant. These flybys exploit Venus's gravitational pull to modify the spacecraft's velocity relative to the Sun, reducing the perihelion altitude above the Sun's surface from an initial ~24 million km after launch to a final 6.1 million km (3.8 million miles; equivalent to a perihelion radius of approximately 6.9 million km, 0.046 AU, or about 9.9 solar radii from the Sun's center). Each assist effectively slows the spacecraft in its solar orbit, converting hyperbolic excess velocity into a tighter elliptical path while maintaining an inclination of approximately 3.4 degrees relative to the ecliptic plane. The orbital periods decrease accordingly, starting at around 150 days for the initial orbits and shortening to 88 days for the final science orbits. The sequence of Venus flybys began with the first on October 3, 2018, which primarily raised the apoapsis to position the for subsequent maneuvers, followed by the second on December 26, 2019; the third on July 11, 2020; the fourth on February 20, 2021; the fifth on October 16, 2021; the sixth on August 21, 2023; and culminated with the final flyby on November 6, 2024, which provided the last tightening of the . Each flyby imparts a delta-V change ranging from approximately 6 to 10 km/s, achieved purely through gravitational interaction, with the magnitude varying based on the geometry of the encounter. The first flyby delivered about 8.5 km/s, while later ones, such as the final in 2024, provided around 6.4 km/s to fine-tune the ultimate . Precise navigation is critical for these maneuvers, with ground-based tracking using the Deep Space Network achieving accuracy better than 1 kilometer at Venus encounter distances, ensuring the hits targeted flyby altitudes as low as 376 kilometers above 's surface. This high precision allows for minimal use of the 's propulsion system solely for fine trajectory corrections between flybys.

Perihelion Encounters

The Parker Solar Probe's perihelion encounters represent the mission's core opportunities for close solar observations, with 24 primary passes completed between 2018 and mid-2025. These encounters progressively brought the closer to , starting at a distance of approximately 24 million km from 's center during the first perihelion in November 2018 and reaching a minimum distance of 6.1 million km (3.8 million miles) above 's surface by the 22nd encounter in December 2024, while attaining maximum speeds of up to 192 km/s. This orbital evolution, facilitated by gravity assists, enabled the to penetrate deeper into the solar over successive orbits. Notable examples include the inaugural perihelion on November 6, 2018, when the probe approached within 24 million km of the Sun's center at a speed of 95 km/s, marking the beginning of its record-setting trajectory. The 22nd encounter on December 24, 2024, achieved the mission's closest pass at 6.1 million km (3.8 million miles) above the Sun's surface, with the spacecraft traveling at approximately 192 km/s. Subsequent passes, including the 25th on September 15, 2025, and the planned 26th on December 12, 2025, have maintained this record distance, allowing sustained access to extreme solar conditions. Each perihelion encounter unfolds in distinct phases: the approach phase, beginning several days prior to closest approach, enables active as the spacecraft accelerates toward ; the closest approach itself lasts mere hours and involves a high-risk period of due to the shield's blocking the high-gain ; and the departure phase follows, during which recorded data is downlinked to over subsequent days. To mitigate risks during these intense passes, the autonomously orients its carbon-composite —capable of withstanding temperatures up to 1,370°C (2,500°F)—directly toward , ensuring the remains at a stable of about 29°C (85°F). Additionally, onboard autonomous safing systems activate if anomalies are detected, such as excessive heating or deviations, temporarily halting non-essential operations to prioritize protection and structural integrity.

Mission Operations

Operational Timeline

The Parker Solar Probe launched on August 12, 2018, from Air Force Station aboard a rocket, initiating its seven-year primary mission to study the Sun's . Following deployment, the spacecraft underwent initial checkout and commissioning, with instrument testing beginning in early September 2018. The first occurred on October 3, 2018, adjusting the probe's orbit for subsequent solar encounters. The initial perihelion took place on November 5, 2018, at a distance of approximately 15 million miles (24 million kilometers) from the Sun's surface, during which the instruments collected the mission's first dataset. Science data from this encounter was successfully downlinked starting in late November 2018, confirming nominal operations and instrument performance. Subsequent early maneuvers included the second perihelion on April 4, 2019, followed by the third on September 1, 2019, both supported by ongoing trajectory refinements. The second on December 26, 2019, further tightened the orbit, enabling closer approaches in later years. Data collection continued through these phases, with downlinks occurring after each encounter to relay observations back to . From 2021 onward, the probe achieved progressively deeper entries into the solar corona, beginning with the first confirmed crossing on April 28, 2021, during its eighth perihelion. Additional flybys on July 11, 2020; February 20, 2021; October 16, 2021; August 21, 2023; and November 6, 2024 refined the trajectory for even closer passes. By mid-mission, the spacecraft had completed 17 perihelions, including the 17th on September 27, 2023, during which its Wide-field Imager for Solar Probe (WISPR) captured images of multiple sungrazing comets. The primary mission's later stages featured the 22nd perihelion on December 24, 2024, the closest approach to date at 3.8 million miles (6.2 million kilometers) from the Sun's surface, with the spacecraft's health confirmed via signal on December 26, 2024. This was followed by the 23rd perihelion on March 22, 2025, and the 24th on June 19, 2025, both maintaining the record proximity. The 25th perihelion occurred on 15, 2025. By September 2025, data from encounters 22 and 23 had been released and made available to researchers, contributing to a cumulative archive of observations from prior downlinks.

Current Status and Extension Plans

As of November 2025, the Parker Solar Probe remains in excellent health following its 25th perihelion encounter on September 15, 2025, during which it approached to within 3.8 million miles (6.2 million kilometers) of the Sun's surface. All onboard scientific instruments continue to function nominally, enabling ongoing data collection on the solar corona and . The spacecraft is currently traversing its orbit toward the 26th perihelion, anticipated around mid-December 2025. The probe's primary mission officially concluded with the 24th perihelion on June 19, 2025, marking the end of its core operational phase after seven years of progressively closer solar approaches. The mission continues beyond the primary phase, with planning additional perihelion passes. These extended operations are projected to continue at least through 2028, potentially reaching 2029, with the spacecraft's substantial remaining reserves supporting more than 30 total perihelion encounters overall. As of late 2025, margins far exceed initial projections and are limited primarily by long-term degradation of the solar arrays rather than constraints. Mission teams continue to monitor challenges such as cumulative to from repeated close passages, which has been mitigated by the probe's robust thermal shield but requires vigilant health checks. Additionally, data downlink rates are constrained during high-speed perihelion phases, when the spacecraft's velocity—approaching 430,000 (692,000 kilometers per hour)—temporarily limits communication with ground stations.

Scientific Findings

Early Discoveries (2018-2023)

During its initial orbits from 2018 to 2023, the Parker Solar Probe provided groundbreaking in-situ measurements of the and coronal environment, revealing fundamental processes shaping the inner . One of the earliest discoveries was the prevalence of magnetic switchbacks—sudden reversals in the direction—observed ubiquitously in the as close as 0.166 AU from during the probe's first encounters in late 2018 and early 2019. These structures, lasting from seconds to hours, were found to be highly Alfvénic, with deflections often exceeding 90 degrees, and linked to events at their boundaries, suggesting origins in coronal processes that transport energy outward. Switchbacks were not isolated phenomena but occurred in patches within slow streams, challenging prior models by indicating that such reversals are a common feature near rather than rare interplanetary artifacts. A pivotal milestone came in December 2021, when the probe confirmed crossing the Alfvén critical surface for the first time during its eighth perihelion on April 28, 2021, at approximately 18.8 solar radii (about 13 million km) above the solar photosphere. This boundary marks the transition from sub-Alfvénic flow in the magnetically dominated to super-Alfvénic , where speeds exceed the Alfvén speed, enabling outward propagation of disturbances. The crossing lasted about five hours, during which the probe measured steady radial magnetic fields and low turbulence levels, consistent with open field lines emerging from a , and provided direct evidence of the surface's location closer to than previously predicted by models. Observations from the probe's early encounters also unveiled a dust-free zone in the inner heliosphere, a region devoid of interplanetary dust particles inward of approximately 5.6 million kilometers (3.5 million miles, or about 8 solar radii) from the Sun's center, as inferred from impact data collected through 2020. This void, predicted theoretically due to intense solar radiation pressure and Poynting-Robertson drag sublimating or expelling micron-sized grains, was directly imaged and quantified using the Wide-field Imager for Solar Probe (WISPR), showing a sharp depletion in dust density beyond 0.25 AU but confirming the inner boundary at around 8 solar radii. The findings highlighted solar heating as the dominant mechanism clearing this zone, with implications for dust dynamics and zodiacal light emission near the Sun. Further insights into coronal heating emerged from measurements of ubiquitous Alfvén waves during 2021 and 2022 encounters, establishing them as a primary energy source for maintaining the corona's million-degree temperatures. These waves, characterized by outward-propagating magnetic fluctuations with high cross-helicity, were detected pervasively in the near-Sun , carrying sufficient Poynting flux to account for observed heating rates without invoking sporadic nanoflares. Data below the reinforced this, showing a turbulent spectrum consistent with wave dissipation via ion or instabilities, providing empirical support for wave-based heating models over decades of debate.

Advanced Measurements and Recent Insights (2024-2025)

During its closest-ever approach to the Sun on December 24, 2024, the Parker Solar Probe flew at a distance of approximately 6.1 million kilometers (3.8 million miles) from the surface, achieving a speed of 692,000 km/h and enabling high-resolution measurements within the . This perihelion pass provided further measurements of sub-Alfvénic flows, where speeds fell below the local Alfvén speed, indicating regions of magnetic dominance close to the that influence wind acceleration. Observations also showed enhanced particle acceleration mechanisms, with energetic electrons and ions exhibiting increased fluxes driven by wave-particle interactions in these dense environments. In 2024, analysis of Wide-field Imager for Parker Solar Probe (WISPR) data provided the first direct imaging of Kelvin-Helmholtz instabilities within a coronal mass ejection (CME), observed along the ejection's flank during an earlier encounter but detailed in recent publications. These instabilities, characterized by rolling vortex-like structures formed at velocity shear interfaces, explain the generation of turbulence in the solar corona and its role in dissipating energy and accelerating particles during CME propagation. The findings highlight how such instabilities contribute to the chaotic mixing observed in solar transients, offering a conceptual framework for modeling coronal heating and eruptive events. WISPR has continued to detect sungrazing comets during perihelion encounters, with notable observations including two Kreutz-group comets in December 2023 that provided detailed views of their tails and disruption processes near the Sun. Earlier detections, such as the first PSP-discovered comet PSP-001 in May 2022, along with subsequent ones through 2024, reveal how intense solar radiation and gravitational tides cause cometary nuclei to fragment, releasing dust and gas that scatter sunlight and trace magnetic field lines. These insights elucidate the physical limits of cometary survival in extreme proximity to the Sun, informing models of volatile loss and inner heliospheric dust dynamics. In 2025, during its 25th perihelion on September 15, WISPR captured images of the at unprecedented resolution, gathering on solar wind structures during a more active phase of the Sun's 11-year cycle. These observations demonstrate how localized instabilities shape the nascent , with implications for improved forecasting by better predicting the evolution of solar wind streams and their geomagnetic impacts on . Additionally, late 2025 analyses of from the 2024 perihelion revealed in-situ evidence of 5-minute oscillations in the sub-Alfvénic . The underscore the probe's role in linking coronal activity to heliospheric variability, enhancing predictive models for solar energetic particle events.

Inter-mission Collaborations

With Solar Orbiter

The Parker Solar Probe operates in a near-equatorial orbit with an inclination of approximately 3.8° relative to the ecliptic plane, enabling in-situ sampling of structures primarily in low-latitude regions close to the Sun. In synergy, the European Space Agency's achieves orbital inclinations up to 24° relative to the solar equator through Venus gravity assists, providing the first high-resolution views of the Sun's polar magnetic fields and . This complementary geometry allows the two missions to jointly probe the origins of the , connecting remote-sensing observations of coronal dynamics with direct measurements of heliospheric evolution, thereby revealing how streams form and propagate from diverse latitudes. Coordinated joint campaigns have maximized these observational synergies. During a quadrature configuration in June 2022, 's captured remote images of coronal features, while Parker Solar Probe traversed the same lines closer to , enabling end-to-end tracking of parcels from their coronal sources to approximately and revealing the role of mesoscale structures in wind acceleration. Similarly, in late March/early April 2024, the missions aligned their perihelion passages—Parker Solar Probe at about 0.053 (4.51 million miles or 7.26 million km from the surface) and at 0.29 —for co-pointed observations, which facilitated precise mapping of the interplanetary and its to surface magnetic features. A similar alignment occurred in March 2025, with Parker Solar Probe's 23rd perihelion on March 22 at 3.8 million miles (6.1 million km) from the surface and 's perihelion on March 31 at 0.29 , enabling further joint studies of dynamics and energetic particles. These efforts have produced significant shared scientific findings. Analysis of 2022 quadrature data confirmed that interplanetary magnetic switchbacks—sharp reversals in the solar wind's —originate from reconnection events at the base of the solar corona, with Solar Orbiter's polar views linking them to network boundaries and Parker Solar Probe's in-situ data tracing their outward evolution. Combined datasets from both have further elucidated the dynamics of energetic particles, showing how suprathermal ions and electrons are accelerated near and scattered by Alfvén waves, with multi-point observations revealing spatial variations in particle fluxes during transient events. Data from Parker Solar Probe and are archived in public repositories managed by and ESA, including the Heliophysics Data Portal and the Solar Orbiter Science Archive, promoting for global researchers to integrate datasets for further analysis. By 2025, these collaborations have resulted in over 10 joint peer-reviewed publications, underscoring the missions' role in advancing through multi-viewpoint observations of the inner .

With SOHO and STEREO

The integration of (PSP) data with observations from the () enhances the understanding of by combining in-situ measurements from PSP's close encounters with the and remote-sensing imagery from SOHO's Large Angle and Spectrometric (LASCO). LASCO's images provide contextual views of the outer and inner , allowing researchers to correlate PSP's direct and data with large-scale structures like coronal rays and transients. For instance, multi-spacecraft analyses have used LASCO imagery to interpret PSP's in-situ observations of solar energetic particle (SEP) events, revealing propagation patterns from the outward. SOHO and PSP have also collaborated in tracking sungrazing comets, offering multiple viewpoints that illuminate the solar environment during these events. Between 2023 and 2024, SOHO's LASCO captured numerous Kreutz-group sungrazers, including C/2024 S1 (ATLAS) with perihelion on October 28, 2024, at 0.008 AU (1.2 million miles or 1.9 million km from the surface), while PSP's Wide-field Imager for Solar Probe (WISPR) provided complementary inner-corona perspectives during its 21st encounter (September–October 2024), aiding in the study of comet-solar wind interactions. These multi-viewpoint observations have helped map the dynamic plasma conditions near the Sun, with SOHO's long-baseline imaging contextualizing PSP's proximity data.) PSP's collaboration with the Solar Terrestrial Relations Observatory () leverages STEREO's heliospheric imagers to validate streams encountered by PSP during its perihelion passes. STEREO-A's COR2 and Heliospheric Imager (HI) instruments capture outbound structures, particularly during quadrature alignments when STEREO views material streaming toward PSP's trajectory, confirming in-situ velocity and density profiles. This validation has been crucial for tracing stream evolution from the to the inner . In 2024, a coordinated multi-mission campaign utilized and observations to link coronal mass ejections (CMEs) to their Earth impacts, improving forecasting. For example, predictions from the Community Coordinated Modeling Center (CCMC) integrated PSP's near-Sun CME data with STEREO-A's side-view imagery of fronts heading Earthward, enabling accurate arrival time estimates for events like the September 2024 CME. These efforts highlighted STEREO's role in bridging PSP's inner-heliosphere measurements with 1 AU conditions. The multi-mission synergy between , , and connects inner dynamics observed by PSP to observations at , significantly improving models of magnetic across the . By combining PSP's sub-Alfvénic wind data with SOHO's LASCO and STEREO's COR2 images, researchers have refined estimates of open magnetic field lines and flux transport, as demonstrated in white-light studies that enhance for SEP propagation and CME evolution. This approach has led to more accurate simulations of heliospheric magnetic structures. Merged datasets from , , and are accessible through the Virtual Solar Observatory (VSO), facilitating joint analyses of solar events. The VSO aggregates in-situ and imaging data into unified products, supporting coordinated studies of 2025 solar activity, such as SEP events and CMEs, where multi-spacecraft observations from these missions have provided comprehensive coverage of widespread heliospheric disturbances.

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