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New Frontiers program

The is a initiative established in 2003 to conduct principal investigator-led, medium-class robotic spacecraft missions focused on high-priority investigations throughout the Solar System. Designed to bridge the scale between smaller Discovery-class missions and larger flagship endeavors, it emphasizes efficient management, innovative technologies, and cost caps to enable focused exploration of solar system origins, evolution, potential habitability, and resources. To date, the program has selected and launched three missions—New Horizons (NF-1) for a flyby of Pluto and Kuiper Belt objects, Juno (NF-2) for orbital study of Jupiter's atmosphere and magnetosphere, and OSIRIS-REx (NF-3) for sample return from the asteroid Bennu—while developing Dragonfly (NF-4), a rotorcraft-lander for Titan's surface and atmosphere. These missions have delivered pivotal empirical data, including the first resolved images of Pluto's surface features and composition, detailed gravity and magnetic field measurements revealing Jupiter's internal structure, and direct evidence of organic molecules and water-bearing minerals on a carbonaceous asteroid. The program's structure promotes competition among proposed concepts aligned with decadal survey priorities, ensuring selection of investigations that advance causal understanding of planetary formation and dynamics through targeted, verifiable observations.

Program Objectives and Framework

Core Goals and Scientific Priorities

The New Frontiers program's core goals center on conducting competitively selected, -led missions to address high-priority scientific questions about the solar system's origins, , and . These medium-class missions, capped at approximately $1.25 billion (in real-year dollars as of recent announcements of ), enable frequent access to destinations beyond low-Earth orbit, including primitive bodies, inner planets, and outer solar system targets, while excluding Mars surface landed missions and large flagship endeavors. By fostering leadership, the program promotes innovative, focused investigations that advance empirical understanding of planetary formation processes, comparative planetology, and the potential for extraterrestrial , drawing on community-vetted priorities rather than agency-directed agendas. Scientific priorities are established through decadal surveys conducted by the National Academies of Sciences, Engineering, and Medicine, which synthesize peer-reviewed input from the community to rank mission themes based on their potential to yield transformative data. For example, the 2003 survey "New Frontiers in the Solar System" emphasized reconnaissance of the outer solar system and sample returns from primitive bodies to test models of solar system accretion and volatile delivery. Subsequent surveys, such as the 2011 "Vision and Voyages for in the Decade 2013-2022," prioritized themes like a Uranus orbiter, multiple-flyby, or Trojan asteroid tour, though actual selections like (asteroid sample return) and ( rotorcraft) aligned with enduring questions on compositions and prebiotic chemistry on icy moons. These priorities privilege missions capable of delivering in-situ measurements, orbital , and sample analysis to constrain causal models of and atmospheric retention, often leveraging radioisotope power for deep-space operations unavailable in smaller Discovery-class efforts. The program's framework ensures alignment with broader Science Mission Directorate objectives, such as characterizing solar system bodies (excluding ) to inform habitability assessments and dynamical evolution theories, while incorporating and public outreach to disseminate findings. Priorities evolve with each announcement of opportunity; for instance, New Frontiers 4 emphasized outer planet satellites and Trojan asteroids to probe water-rock interactions and solar nebula remnants, reflecting empirical gaps in Kuiper Belt object origins and giant planet satellite formation. This approach has yielded missions like , which targeted Jupiter's interior structure and to test core accretion models, demonstrating the program's emphasis on hypothesis-driven exploration over exploratory surveys.

Cost Parameters and Management Model

The New Frontiers Program operates under a (PI)-led management model, in which the selected PI holds primary authority and accountability for mission design, development, integration, and scientific execution, while oversees programmatic elements such as launch services and certain ground infrastructure. Missions are competitively solicited via Announcements of Opportunity (AOs) aligned with priorities, with proposals evaluated on scientific merit, feasibility, and cost realism by and external panels. This PI-centric approach decentralizes decision-making to foster innovation and efficiency, distinct from centrally managed missions, but includes -imposed milestones, reviews, and oversight to mitigate risks and ensure alignment with agency objectives. Cost parameters emphasize strict caps on the PI-Managed Mission Cost (PMMC), which covers , instruments, mission operations, and but excludes NASA-furnished items like launch vehicles, deep space network usage, and select facilities. For the New Frontiers 5 AO released in 2022, the PMMC is limited to $900 million for Phases A through D (concept to launch) and $300 million for Phase E (operations and data return), both in FY 2022 dollars, with adjustments for in proposals. Earlier competitions featured varying caps, such as $700 million (FY 2003 dollars) for under New Frontiers 1, reflecting program evolution toward tighter controls amid budget pressures. These caps enforce cost discipline, targeting total mission costs below $1.2 billion including non-PMMC elements, while development timelines are compressed—typically 48 months for Phases B through D—to reduce overhead. Risk and cost integrate parametric estimating tools from Phase A onward, such as NASA's NICM model for system-level projections based on mass, complexity, and heritage, supplemented by three-point probabilistic estimates for uncertainty. Missions must submit detailed plans, prioritizing validated technologies to avoid overruns, with retaining authority to impose reserves (typically 25-50% for contingencies) and conduct independent cost reviews. Phase E caps, introduced more stringently in recent AOs, address historical operations growth—evident in missions like exceeding initial projections—by incentivizing efficient post-launch planning, though critics note potential disadvantages for distant targets requiring prolonged operations. Program-level budgeting allocates roughly $200-500 million annually across active missions, drawn from 's Science Mission Directorate, with selections paced every 4-5 years to balance portfolio demands.

Historical Development

Origins in NASA's Planetary Exploration Strategy

The New Frontiers program emerged from NASA's strategic shift in planetary exploration during the late 1990s, when persistent budget constraints following major missions like Galileo and Cassini necessitated a more efficient, tiered approach to mission development. The , initiated in the early 1990s, emphasized small, principal investigator-led missions costing under $500 million to enable frequent, focused investigations, but it lacked capacity for higher-priority targets requiring greater resources, such as outer planet flybys or sample returns from primitive bodies. To bridge this gap between low-cost Discovery efforts and expensive flagship projects exceeding $1 billion, developed the concept for medium-class missions around 2000–2001, aiming for costs capped at approximately $700–$1 billion per mission (in then-current dollars) while maintaining competitive selection and scientific rigor. This structure aligned with NASA's broader Mission Directorate goals of advancing understanding of solar system origins, evolution, and habitability through balanced investment. Congress approved funding for the New Frontiers program in fiscal years 2002 and 2003, formalizing it as a series of competitively selected missions to implement high-priority objectives outlined in community inputs, including the 2003 National Research Council decadal survey New Frontiers in the Solar System: An Integrated Exploration Strategy. That survey, requested by , advocated an integrated exploration framework prioritizing medium-scale missions for targets like , Jupiter's satellites, and Mercury, emphasizing cost-effective pathways to transformative science amid flat budgets. The program's inaugural selection, to the system and , occurred in November 2001, preceding full congressional endorsement but demonstrating 's proactive alignment with strategic recommendations for sustained, PI-led exploration. By targeting a launch cadence of one mission every 36–42 months, New Frontiers sought to mitigate risks of over-reliance on infrequent large missions while fostering innovation in and . This origins reflect causal pressures from fiscal realism: post-1990s overruns in flagship programs prompted a pivot to modular, scalable missions, enabling NASA to pursue decadal priorities without exceeding congressional appropriations, which hovered around $1.1–1.3 billion annually for planetary science in the early 2000s. Unlike agency-directed flagships, New Frontiers' PI-led model drew from Discovery's successes in cost control and rapid development, but scaled up for complex objectives, such as magnetospheric studies or asteroid sampling, thereby enhancing overall program resilience and scientific output.

Evolution Through Decadal Surveys and Selections

The was established by in 2001 to fund a series of competitively selected, medium-class missions with development costs capped at approximately $1 billion, designed to address key scientific questions in as prioritized by the community. These priorities are primarily shaped by decadal surveys, independent assessments conducted roughly every ten years by the National Academies of Sciences, Engineering, and Medicine, which evaluate scientific objectives, recommend mission architectures, and propose implementation pathways including New Frontiers-class opportunities. The surveys integrate input from hundreds of experts via white papers, workshops, and peer-reviewed analyses to rank targets such as outer planet satellites, primitive bodies, and sample returns based on potential for transformative discoveries in Solar System origins, evolution, and . The inaugural , "New Frontiers in the Solar System: An Integrated Exploration Strategy," released in 2003, explicitly endorsed the nascent New Frontiers program as a mechanism for executing two medium-class missions per decade, with top priorities including a Pluto-Charon flyby (already underway as New Frontiers 1), a Pole-Aitken basin sample return from the , and a comet sample return. This survey formalized the program's role in bridging flagship missions like Cassini and Discovery-class smaller efforts, emphasizing cost-effective, PI-led investigations that advance understanding of Solar System formation and dynamical processes. Subsequent selections, starting with New Frontiers 2 in 2005, adhered to this framework by requiring proposals to align with survey-recommended themes, undergoing a rigorous peer-review process involving science definition teams that assess merit, feasibility, and alignment with NASA's strategic goals. Evolving priorities across decadal surveys have refined selection criteria, incorporating advances in technology and new data from prior missions. The 2011 survey, "Vision and Voyages for Planetary Science in the Decade 2013-2022," elevated investigations of primitive bodies, Venus, and outer planet systems, influencing New Frontiers 3 (asteroid sample return, selected 2011) and New Frontiers 4 (Titan exploration, selected 2019) through predefined Announcement of Opportunity themes that narrowed proposal scopes to high-priority targets like near-Earth objects and ocean worlds. For each cycle, NASA issues an Announcement of Opportunity soliciting proposals from principal investigators, followed by a downselection to Phase A concept studies (typically 3-4 finalists) evaluated on scientific return, technical risk, and lifecycle cost estimates not exceeding $1.2 billion including launch. Final selections, confirmed after independent reviews, ensure missions remain within the program's PI-led, competitively awarded model, adapting to budgetary constraints while prioritizing surveys' consensus-driven objectives. The 2022 decadal survey, "Origins, Worlds, and Life: A Decadal Strategy for and 2023-2032," continues this trajectory by recommending New Frontiers missions to probe , geology, and lunar volatiles, setting the stage for New Frontiers 5 solicitations announced in 2024 with themes drawn from prior surveys but updated for emerging questions in and comparative planetology. This iterative process has enabled the program to maintain scientific relevance, with selections reflecting not only decadal rankings but also NASA's ability to integrate peer feedback, cost realism, and technological maturation, resulting in four launched missions by 2025 that collectively span diverse Solar System regimes. Challenges, such as funding shortfalls delaying cadence to one mission per 7-8 years rather than the surveyed two per , underscore ongoing tensions between ambition and fiscal discipline.

Mission Portfolio

New Frontiers 1: New Horizons

New Horizons, the inaugural mission of NASA's , was competitively selected in 2001 to conduct a flyby reconnaissance of the Pluto-Charon system and subsequently a object, fulfilling priorities outlined in the 2003 Planetary Decadal Survey for medium-class missions costing under $700 million. The principal investigator, of the , led the effort, with the serving as the primary mission operations center. The spacecraft, powered by a producing about 200 watts, carried seven science instruments: the multi-spectral imager for visible and infrared mapping, the ultraviolet spectrometer, the radio science experiment, the LORRI long-range reconnaissance imager, the SWAP solar wind analyzer, the PEPSSI plasma spectrometer, and the SDC student dust counter. These instruments enabled comprehensive of composition, , atmosphere, and plasma environment during high-speed flybys. Launched on January 19, 2006, at 19:00 UTC from Station aboard an 551 rocket with a Star 48B third stage, achieved a record-breaking of 36,400 mph relative to , the fastest launch speed for any at that time. A from on February 28, 2007, at a closest approach of 1.4 million miles, boosted the , shortened the arrival by three years, and provided valuable data on 's atmosphere and . After a decade-long cruise, the reached on July 14, 2015, passing 7,800 miles above the surface at 30,800 mph relative to , marking the first close-up exploration of the and its satellites. The encounter revealed 's diverse geology, including nitrogen ice plains on , water-ice mountains up to 11,000 feet high, a tenuous nitrogen-methane atmosphere extending 1,000 miles, and evidence of ongoing geological activity despite the frigid temperatures averaging -387°F. , 's largest moon, displayed a vast canyon system four times deeper than the Grand Canyon and a reddish polar cap likely from captured hydrocarbons. Following the Pluto flyby, New Horizons entered an extended mission approved in 2016, targeting Kuiper Belt objects discovered via Hubble Space Telescope observations. On January 1, 2019, it executed a flyby of (provisionally 2014 MU69), approaching within 2,200 miles at 32,000 mph, the most distant close encounter by any spacecraft at over 4 billion miles from . Arrokoth, a 22-mile-long resembling a "snowman," exhibited a flattened, reddish surface with minimal craters, indicating a pristine, formed gently via pebble accretion rather than violent collisions, providing for models of early Solar System body formation. Data downlink continued into 2020, revealing uniform low-density composition and water beneath the surface. The mission faced challenges, including a entry on July 4, 2015, due to a planned computer swap timing error, which delayed some observations but did not compromise core data collection, and ongoing concerns about impacts in the . As of 2025, remains operational, shifting focus to observations of the and from beyond 50 AU, with fuel and power sufficient for potential additional targets. Total mission cost through the Pluto encounter was approximately $700 million, adhering to New Frontiers cost caps.

New Frontiers 2: Juno

The mission, designated New Frontiers 2, was selected by on June 1, 2005, following a competitive process to investigate Jupiter's interior structure, atmospheric composition and dynamics, magnetic field, and polar magnetosphere, with the goal of elucidating the planet's origin and evolution. Managed by NASA's with principal investigator Scott J. Bolton from the , the mission operates under a New Frontiers cost cap of approximately $700 million excluding launch vehicle, though total expenditures reached $1.13 billion including development, instruments, launch, and operations through the primary phase. Launched on August 5, 2011, from Air Force Station aboard an 551 rocket, Juno executed an in October 2013 to adjust its trajectory, covering 1.74 billion miles (2.8 billion kilometers) before orbit insertion on July 4, 2016, via a 35-minute burn. The employs a spinning, solar-powered design in a highly elliptical , with perijove altitudes as low as 4,170 kilometers (2,590 miles) above cloud tops to minimize radiation exposure while enabling and observations during brief close passes. Originally planned for 37 orbits over 20 months, the faced from valve issues and radiation-induced faults, prompting extensions: first to July 2021, then further to September 2025 with 42 additional orbits focused on 's moons and rings. Juno's payload includes nine science instruments: the Microwave Radiometer (MWR) for probing atmospheric composition and temperature to depths of 350 miles (560 km); dual Magnetometers (MAG) for mapping the magnetic field; Gravity Science (GS) using Doppler tracking for interior mass distribution; Jovian Auroral Distributions Experiment (JADE) and Jupiter Energetic Particle Detector Instrument (JEDI) for plasma and particle analysis; Waves for electromagnetic phenomena; Ultraviolet Spectrograph (UVS) for auroral studies; and Jovian Infrared Auroral Mapper (JIRAM) for infrared imaging of polar regions and ammonia. JunoCam, a visible-light camera, provides public outreach imagery but is not a formal science instrument. The spacecraft's three solar arrays generate up to 500 watts at Jupiter's distance, powering operations despite intense radiation mitigated by a titanium vault shielding electronics. Scientific results from have revealed Jupiter's atmospheric jet streams extend at least 1,900 miles (3,000 km) deep, far beyond prior expectations; water abundance is higher near the equator than poles, suggesting dynamic redistribution; the is asymmetrical and 30 times stronger than Earth's in equatorial regions, generated by a layer of liquid ; and the core appears "fuzzy" and dilute rather than compact, spanning about 10-20% of the planet's radius with implications for formation models involving accretion. Polar observations uncovered cyclonic storms forming regular polygons, including eight-pole arrays, contrasting equatorial banded flows; plumes rise from deep interiors, fueling cloud variability; and auroral features link to moon-plasma interactions, including Callisto's faint footprint. These findings, derived from perijove data and radio occultations, challenge uniform interior models and inform formation theories, with data volumes exceeding 1.5 terabits processed via ground stations worldwide. 's extended phase has yielded close-up imaging of Io's volcanic resurfacing and Ganymede's surface, enhancing understanding of the Jovian system ahead of planned deorbit in late 2025 to avoid contamination risks.

New Frontiers 3: OSIRIS-REx


The mission, formally Origins, Spectral Interpretation, Resource Identification, and Security–Regolith Explorer, was selected in 2011 as the third New Frontiers mission to conduct the first U.S. sample return. Launched on September 8, 2016, aboard an rocket from Air Force Station, the spacecraft targeted the carbonaceous near-Earth 101955 , a primitive body selected for its potential to hold unaltered materials from the solar system's formation. The mission's principal investigator was of the , with responsible for spacecraft development. Primary objectives encompassed returning a minimum of 60 grams of for laboratory analysis to investigate molecules, water-bearing minerals, and solar system origins; global of Bennu's shape, surface features, and ; documentation of the sample site environment; and measurement of the Yarkovsky effect, a non-gravitational influencing the asteroid's due to . The spacecraft carried five instruments: the OSIRIS-REx Camera Suite (OCAMS) for high-resolution imaging; the OSIRIS-REx (OLA) for 3D topography; the Visible and Spectrometer (OVIRS) for mineralogical ; the Thermal Emission Spectrometer (OTES) for thermal infrared analysis; and the Regolith X-ray Imaging Spectrometer (REXIS) for elemental abundance detection. A sample collection employed gas to disturb and capture surface particles during a touch-and-go , avoiding propulsion contamination. Following an on September 22, 2017, arrived at on December 3, 2018, entering a series of reconnaissance orbits and flybys to characterize the asteroid's unexpectedly rugged, boulder-strewn surface. The sample acquisition, termed Touch-and-Go (), occurred on October 20, 2020, at site Nightingale, yielding 121.6 grams of material—more than double the target amount. Departure from followed on May 10, 2021, with the sample return capsule reentering 's atmosphere and landing in on September 24, 2023. Initial analyses of the pristine samples revealed carbon- and nitrogen-rich dust, phosphates, and other compounds suggestive of aqueous alteration and potential prebiotic chemistry precursors. Developed under a New Frontiers cost cap of approximately $800 million excluding the $183.5 million , demonstrated efficient management within program constraints. Post-return, the spacecraft was repurposed as OSIRIS-APEX for an extended mission to observe asteroid during its 2029 flyby, leveraging remaining fuel and instruments for planetary defense studies.

New Frontiers 4: Dragonfly

The mission, designated as New Frontiers 4, involves deploying an autonomous rotorcraft-lander to Saturn's moon to investigate prebiotic chemical processes and potential. Selected by on June 27, 2019, from a competitive field of proposals, it represents the program's focus on innovative exploration of outer solar system bodies. The mission, led by the , aims to sample diverse sites across Titan's surface, leveraging the moon's thick nitrogen-rich atmosphere to enable powered flight without traditional propulsion fuel. Dragonfly's primary scientific objectives include analyzing in Titan's diverse environments, such as dunes and impact craters, to assess pathways to prebiotic complexity similar to conditions. It will examine the moon's methane-based hydrological cycle and search for chemical precursors to life, though the mission explicitly targets abiotic processes rather than direct detection. The rotorcraft carries instruments for geochemical analysis, including a spectrometer for subsurface detection, gamma-ray and alpha-particle spectrometers for elemental composition, and /sampling tools for characterization. These capabilities enable in-situ measurements at multiple locations, covering up to 180 kilometers over the nominal mission duration. The spacecraft design features eight rotors for vertical takeoff and horizontal flight, allowing autonomous navigation to scientifically promising sites identified via onboard imaging and . With a of approximately 500 kilograms, including a for power and thermal control, relies on Titan's low and dense atmosphere for efficient aerial mobility. operations emphasize radiation-hardened to withstand the journey and Titan's environment, with flight durations of up to 0.5 kilometers per hop. Following selection, encountered development challenges, including technical complexities in integration and issues, leading to cost growth and schedule slips. confirmed the mission on April 17, 2024, with a revised life-cycle cost of $3.35 billion—roughly double the initial estimate—and a launch readiness date of July 2028 aboard a rocket. The interplanetary trajectory involves a six-year cruise, with arrival at in 2034 for aerocapture and descent. Integration and testing commence in January 2026, amid ongoing scrutiny from oversight reports highlighting management risks and baseline exceedances.

Future Mission Opportunities

New Frontiers 5 Announcement and Candidate Concepts

delayed the release of the New Frontiers 5 (NF-5) Announcement of Opportunity (AO) multiple times owing to budgetary pressures within the Division, shifting the target from an initial 2020-2021 timeframe to no earlier than 2026 for the final AO. This postponement creates a projected launch window around 2033 or later, extending the interval since the New Frontiers 4 launch in 2027 and risking misalignment with decadal survey priorities due to inflation, technological evolution, and supply chain factors. In light of the delay overlapping potential NF-6 planning, requested input from the National Academies of Sciences, Engineering, and Medicine on science themes, resulting in a February 2025 report evaluating options against the 2023-2032 decadal survey's priority questions. The report assessed themes originally outlined in the decadal survey (such as surface sample return and in exploration) alongside newer concepts, recommending a hybrid approach that incorporates updates from recent scientific advances rather than strict adherence to 2011 priorities. It prioritized themes addressing high-priority questions from the Origins, Worlds, and (OWL) decadal survey, emphasizing missions feasible within New Frontiers cost caps (approximately $1.2 billion in real-year dollars) and capable of advancing understanding of planetary formation, , and dynamics. Recommended themes include centaur exploration for insights into objects and solar system evolution, sample return to probe geochemistry, surface sample return for primitive material analysis, multiple flyby to assess subsurface ocean , observer for volcanic processes, lunar geophysical network for interior structure, and Saturn probe for atmospheric composition. Candidate mission concepts studied or proposed under these themes encompass:
  • Centaur Orbiter and Lander (CORAL): Dual spacecraft to orbit and land on a object, targeting surface composition and volatile retention.
  • Ceres Sample Return: Orbiter and sample collection from the to analyze water-rock interactions and organic preservation.
  • Comet Surface Sample Return (CSSR): Lander and ascent vehicle for pristine sampling to study solar system origins.
  • Enceladus Multiple Flyby (EMF): High-resolution flybys of plumes to characterize organics, salts, and potential biosignatures in its ocean.
  • Io Observer: Orbiter focused on 's , , and plasma interactions with Jupiter's .
  • Lunar Geophysical Network (LGN): Network of seismometers and heat flow probes on the to map core-mantle boundary and .
  • Lunar South Pole-Aitken Basin Sample Return: Targeting the basin's deep crustal and mantle materials via sample return to constrain lunar .
  • Saturn Probe: Atmospheric probe to measure , isotopes, and deep structure, complementing Cassini data.
Other concepts like orbiter and Venus In Situ Explorer (VISE) were considered but received lower priority due to overlap with ongoing missions (e.g., at ) or shifting emphases toward outer solar system and small body targets. The selection process, once the issues, will follow standard New Frontiers steps: concept studies, down-selection to 1-2 missions for Phase A, and final approval contingent on confirmation reviews and funding. As of October 2025, no proposals have been solicited, and continues community announcements to prepare for the forthcoming .

Prospects for New Frontiers 6 and Beyond

The Announcement of Opportunity (AO) for New Frontiers 5 has been delayed to no earlier than 2026, a postponement attributed to budgetary constraints and prioritization of ongoing missions within NASA's Division. This shift extends the overall program timeline, positioning New Frontiers 5 selection around 2028 and potential launch in the early 2030s, thereby deferring New Frontiers 6 to an AO likely in the early 2030s with launch opportunities in the mid-to-late 2030s. The program's cost cap of approximately $1.2 billion (in real-year dollars) remains in place, emphasizing efficient, principal investigator-led missions focused on high-priority solar system targets. Prospects for New Frontiers 6 draw from the Origins, Worlds, and Life: A Decadal Strategy for Planetary Science and 2023-2032 (OWL), which endorses continued New Frontiers selections to address enduring questions in , evolution, and . Recommended themes overlapping potential NF-5 and NF-6 opportunities include Observer for volcanic and interior studies, Venus In Situ Sample Return for atmospheric and surface analysis, Saturn Probe for deep atmospheric composition, and comet surface or sample return missions to probe primitive solar system materials. A February 2025 National Academies report further evaluates updates to these themes, incorporating advances in and modeling since the 2011 decadal survey, to ensure relevance amid the NF-5 delay's overlap with NF-6 planning. Longer-term outlook for missions beyond New Frontiers 6 anticipates alignment with the next (2033-2042), sustaining a cadence of one to two medium-class missions per amid fiscal pressures that have historically compressed selections. Emphasis on innovative technologies, such as advanced or in-situ utilization, could enable of challenging targets like or , provided funding stabilizes; however, persistent delays risk eroding scientific momentum and principal investigator pipelines. The program's success hinges on competitive prioritizing measurable scientific return over exploratory breadth.

Scientific Contributions and Impacts

Key Discoveries and Data Yields

The spacecraft, launched in 2006 as the first , conducted a close flyby of on July 14, 2015, revealing a geologically active with a diverse surface featuring nitrogen plains, jagged water-ice mountains up to 11,000 feet tall, and vast dune fields of methane and ices. The imaged 's hazy atmosphere extending over 1,000 miles, composed primarily of with trace hydrocarbons, and detected cryovolcanic features potentially involving ammonia-water slurries, challenging prior models of as a frozen relic. , a 1,000-km-wide basin of convective , was identified as the solar system's largest known , with evidence of ongoing geological resurfacing driven by internal heat. Extending to the , the 2019 flyby of Arrokoth (2014 MU69) yielded data on a pristine, bilobed roughly 22 miles across, rich in organics and consistent with pebble accretion formation theories, providing direct evidence of early solar system building blocks. NASA's Juno mission, inserted into orbit on July 5, 2016, has mapped the planet's gravity field, disclosing that zonal winds extend over 1,800 miles deep, with alternating jet streams rooted far into the interior, influencing models of dynamics. Microwave radiometry revealed a dilute, fuzzy comprising 5-15% of 's mass, rather than a compact rocky body, suggesting gradual accretion and mixing during formation. Juno's observations of polar cyclones—clusters of eight stable, Earth-sized storms—demonstrated their interaction via vorticity exchange, while auroral data tied emissions to asymmetries, with water abundance measured at 0.25% globally, below prior estimates. Recent flybys of identified individual magma chambers powering its 400+ volcanoes, with quantified through gravity perturbations. The OSIRIS-REx mission returned 121.6 grams of material from asteroid Bennu on September 24, 2023, analysis of which confirmed abundant carbon (over 4.7% by weight) and organic compounds including polycyclic aromatic hydrocarbons, indicative of solar system primordial chemistry. Phosphate minerals like magnesium sodium phosphate, formed in water-rich environments, suggest Bennu originated from a differentiated parent body with past aqueous alteration, while the presence of 14 amino acids and nitrogen-rich materials supports delivery of life's precursors to Earth. Magnesium carbonate and iron-bearing phyllosilicates further evidence fluid-rock interactions billions of years ago, with sample purity exceeding expectations at 99% asteroid material, enabling isotopic studies revealing interstellar organics and solar nebula dust. These yields have refined carbonaceous chondrite compositions and impact hazard assessments for near-Earth objects.

Influence on Broader Solar System Understanding

The New Frontiers program's missions have provided critical empirical data that reshaped models of solar system formation, emphasizing the role of small bodies and giant planets in volatile delivery, , and primordial disk evolution. By targeting and differentiated targets, these investigations revealed unexpected geological dynamism and compositional heterogeneity, constraining the Nice model of early dynamical instability where Jupiter's migration scattered planetesimals and influenced inner planet habitability. New Horizons' 2015 Pluto encounter documented a nitrogen-dominated surface with convective resurfacing on Sputnik Planitia, water-ice mountains exceeding 3 km in height, and evidence of past cryovolcanic activity, indicating internal heat retention billions of years after formation. These features, absent in pre-flyby models of static Kuiper Belt objects, suggest tidal or radiogenic heating sustains processes in distant trans-Neptunian bodies, with implications for the retention of volatiles from the solar nebula and the diversity of dwarf planets as remnants of the planet-forming disk. The 2019 Arrokoth flyby further evidenced hierarchical accretion of bilobate planetesimals via low-velocity mergers, supporting pebble-growth theories over catastrophic collisions in the outer protoplanetary disk. Juno's polar orbits since mapped Jupiter's gravity field, revealing a dilute, fuzzy comprising heavy elements diluted in rather than a compact solid, consistent with heterogeneous accretion during rapid formation within the first million years of solar system history. Microwave radiometry detected ammonia-rich plumes penetrating 350 km deep, while data traced auroral currents to mid-latitudes, informing models and the planet's role in sculpting the outer solar system via orbital resonances that depleted the . Such insights challenge uniform disk-collapse scenarios, highlighting giant planets' influence on small-body populations and the delivery of water-rich materials to inner worlds. OSIRIS-REx's 2023 return of 121.6 grams from Bennu exposed a rubble-pile aggregate of primitive CM chondrite-like material, including hydrated silicates, carbonates from parent-body aqueous alteration, and solar nebula-derived dust mixed with presolar grains and interstellar organics. Phosphate minerals indicate a vanished salty ocean world as Bennu's progenitor, providing direct evidence for hydrothermal processes in the main asteroid belt and the radial transport of volatiles during planetary migration. This compositional fidelity to early solar system conditions refines meteorite-asteroid linkages and quantifies carbon delivery fluxes, bolstering hypotheses that impacts from such bodies supplied Earth's water and organic precursors circa 4.5 billion years ago. Collectively, these missions underscore the system's compositional gradients and dynamical history, with New Frontiers data enabling refined simulations of grand tack scenarios where Jupiter's inward-then-outward trek redistributed primitives, fostering the observed dichotomy between volatile-poor inner planets and enriched outer architectures.

Challenges, Criticisms, and Operational Realities

Budgetary Pressures and Program Delays

The New Frontiers program operates under stringent cost constraints, with missions typically capped at approximately $1.2 billion in total lifecycle costs (in real-year dollars), excluding expenses, to ensure affordability within NASA's budget. These limits, intended to foster principal investigator-led missions without the overruns common in larger programs, have nonetheless contributed to broader budgetary pressures amid competing priorities in NASA's portfolio, including Discovery-class missions and efforts like . Flat or declining funding for —exacerbated by overall NASA budget stagnation relative to —has forced trade-offs, such as prioritizing ongoing operations over new starts. A primary manifestation of these pressures has been delays in program solicitations. For New Frontiers 5, postponed the Announcement of Opportunity () multiple times due to fiscal limitations, shifting the target release from fall to no earlier than 2026, a deferral of about three years from initial plans. This lag stems from insufficient funding to support concurrent mission development and proposal evaluations, risking compression of the pipeline between NF-5 and NF-6 selections. To mitigate historical cost growth, imposed a $300 million (FY2022 dollars) cap on operations-phase expenses for NF-5 missions, a measure critics argue disadvantages complex outer-planet concepts requiring extended cruise phases. Individual missions have also encountered overruns tied to these constraints. The rotorcraft mission (New Frontiers 4), selected in 2019 with a planned 2026 launch, has faced schedule slips to 2028 and cost increases beyond initial estimates, prompting a Office of review that highlighted management challenges in balancing innovation with fiscal limits. Such issues reflect broader patterns in projects, where even cost-capped endeavors average 20-30% schedule growth and 15-50% from baseline, per historical analyses, due to technical complexities and evolving requirements. These delays compound program risks by extending "standing army" costs for development teams and deferring scientific returns.

Technical Risks, Overruns, and Selection Debates

The New Frontiers program's emphasis on innovative, PI-led missions introduces inherent technical risks from unproven technologies and complex operations in extreme environments. For (New Frontiers 3), the Touch-and-Go Sample Acquisition Mechanism (TAGSAM) unexpectedly collected over 100 grams of —far exceeding the 60-gram goal—during the October 20, 2020, touch-and-go maneuver at , jamming the sampler head and causing particle leakage into space before operators sealed the sampler on November 4, 2020. During re-entry on September 24, 2023, the sample capsule's failed to deploy due to crossed wiring from inconsistent "main" labeling between design schematics and manufacturing, though the main parachutes functioned, enabling safe landing. These issues stemmed from underestimation of 's surface cohesiveness and in assembly documentation, highlighting risks in sampling hardware reliability. Dragonfly (New Frontiers 4), a nuclear-powered for , faces elevated risks from its novel design for flight in a dense, nitrogen-rich atmosphere, autonomous navigation over cryovolcanic terrain, and endurance against extreme cold (-179°C) during a 2034 arrival after an 8-year cruise. Delaying full-scale testing to manage costs has heightened late-stage risk identification, potentially amplifying mitigation expenses for propulsion, avionics, and integration. Cost overruns plague the program, with a life-cycle cost study of early and New Frontiers missions revealing drivers like optimistic baselining and Phase C/D growth, where projects often exceeded $700 million caps due to technical complexities and funding instability. exemplifies this, with a September 2025 NASA OIG audit citing nearly $1 billion in increases and a two-year launch slip to no earlier than 2028, pushing total s over $3 billion—attributed to NASA-directed replans, inflation, and initial underfunding rather than inherent technical flaws. Broader audits note planetary missions routinely underrate risks, contributing to $4.4 billion in major project overruns as of 2024. Selection debates center on balancing scientific priority, feasibility, and decadal survey recommendations amid constrained budgets. The 2019 choice of over Venus proposals like and prioritized outer solar system despite inner-planet advocacy in the 2011 decadal, prompting community discussions on target diversity. NASA's 2023 delay of the New Frontiers 5 announcement—pushing proposals to 2025 or later—intensified critiques of pacing, as it creates launch gaps exceeding 12 years post-, limiting cadence and risking talent attrition. Peer reviews emphasize technical maturity, yet selections often weigh broader portfolio needs, as seen in critiques of processes favoring established teams over higher-risk concepts.

References

  1. [1]
    NASA SOMA: New Frontiers AO Homepage
    May 26, 2022 · The New Frontiers Program is a science program of medium-sized, PI-led spacecraft missions. It has launched three missions and is developing a ...
  2. [2]
    New Frontiers - NASA Science
    The New Frontiers Program is designed to accomplish focused planetary science investigations, using innovative and efficient management approaches.
  3. [3]
    [PDF] Program Plan New Frontiers Program - NASA
    This is the New Frontiers Program Plan document, document number NWFR-PLAN-001, baseline effective March 3, 2006.
  4. [4]
    [PDF] Discovery/New Frontiers Missions - NASA
    The missions in the program will tackle specific solar system exploration goals iden- tified as top priorities by consensus of the planetary community. New ...
  5. [5]
    NASA Announcement of Opportunity for New Frontiers Program
    The New Frontiers Program conducts Principal Investigator (PI)-led space science investigations in SMD's planetary programs under a not-to-exceed cost cap for ...
  6. [6]
    [PDF] You Get What You Pay For: The New Frontiers 5 Operations Cost Cap
    The purpose of this study is not to criticize the implementation of a Phase E cost cap, nor is it to campaign for the removal of the cost ...
  7. [7]
    NASA Advance Notice Regarding Forthcoming Release of the New ...
    Sep 1, 2022 · Cost Cap: PI-Managed Mission Cost (PMMC) for investigations will have two cost caps. The PMMC for Phases A-D will be capped at $900M (FY22$) ...
  8. [8]
    [PDF] Cost Estimating Module
    NASA's New Frontier's Program: (example mission: Pluto New Horizons). $700M cost cap (FY03$). 48 month development for Phases B/C/D. NASA's Mars Scout Program ...
  9. [9]
    Controlling Cost Growth of NASA Earth and Space Science Missions
    Parametric cost models should be used as the primary source of cost estimates in Phase A, and they remain applicable in phases B, C, and D (NASA, 2008).
  10. [10]
    PP&C Models & Tools - NASA
    NICM estimates cost and schedule for new developments utilizing key technical parameters such as mass. NICM can provide system level and subsystem level cost ...
  11. [11]
    [PDF] NASA Space Flight Program and Project Management Handbook
    ... Cost and Schedule Analysis Work to Support Decisions ... Model Using a Three-Point Estimate ...
  12. [12]
    [PDF] NASA's Discovery Program - GovInfo
    • Encourage the use of new technologies in achieving program objectives, ... New Frontiers Program Office (D&NFPO) got involved. The office, explained ...
  13. [13]
    New Frontiers in the Solar System: An Integrated Exploration Strategy
    This survey was requested by the National Aeronautics and Space Administration (NASA) to determine the contemporary nature of solar system exploration.
  14. [14]
    Most Recent Decadal Surveys - NASA Science
    Our decadal surveys provide detailed insights into the strategic priorities and mission directives set for the next decade across key scientific domains.
  15. [15]
    NASA SOMA: NF-4 AO- Announcements - New Frontiers
    The New Frontiers Program conducts Principal Investigator (PI)-led space science investigations in SMD's planetary programs under a not-to-exceed cost cap for ...
  16. [16]
    Here's what we know about the 12 proposals for NASA's next New…
    Aug 10, 2017 · The list of possible missions for the New Frontiers program are pre-selected by a panel of scientists once a decade in a process that sets ...
  17. [17]
    New Frontiers 5 - NASA Spaceflight Forum
    Aug 7, 2023 · ... New Frontiers missions at the cadence that the decadal survey planners recommended back in 2001. They wanted two NF missions per decade, and ...
  18. [18]
    New Horizons - NASA Science
    Jan 19, 2006 · NASA's New Horizons spacecraft was the first spacecraft to explore Pluto up close, flying by the dwarf planet and its moons on July 14, 2015.
  19. [19]
    15 Years Ago: New Horizons Launched to Pluto and Beyond - NASA
    Jan 20, 2021 · The actual encounter phase took place between January and June 2007, with the closest approach occurring on Feb. 28 at 1.4 million miles.
  20. [20]
    Five Years after New Horizons' Historic Flyby, Here Are 10 ... - NASA
    Jul 14, 2020 · After a voyage of nearly 10 years and more than 3 billion miles, the intrepid piano-sized probe flew within 7,800 miles of Pluto. For the first ...
  21. [21]
    The Path to Arrokoth - New Horizons
    After Pluto, New Horizons was diverted to Arrokoth. It took images of Arrokoth, made course corrections, and then performed intensive observations before the ...
  22. [22]
    New Horizons Team Uncovers a Critical Piece of the Planetary ...
    Feb 13, 2020 · The New Horizons spacecraft flew past the ancient Kuiper Belt object Arrokoth (2014 MU69) on Jan. 1, 2019, providing humankind's first close-up ...
  23. [23]
    https://pluto.jhuapl.edu/Arrokoth/Arrokoth.php
  24. [24]
    NASA New Horizons to Continue Exploring Outer Solar System
    Sep 29, 2023 · Beginning in fiscal year 2025, New Horizons will focus on gathering unique heliophysics data, which can be readily obtained during an extended, low-activity ...
  25. [25]
    NASA Selects New Frontiers Mission Concept Study
    Jun 1, 2005 · The New Frontiers Program is designed to provide opportunities to conduct several of the medium-class missions identified as top priority ...Missing: goals | Show results with:goals
  26. [26]
    Juno - NASA Science
    Aug 5, 2011 · NASA's Juno spacecraft has explored Jupiter, its moons, and rings since 2016, gathering breakthrough science and breathtaking imagery.
  27. [27]
    [PDF] Jupiter Orbit Insertion - Press Kit - NASA's Jet Propulsion Laboratory
    Jun 2, 2016 · The Juno mission investment is $1.13 billion in total. This cost includes spacecraft development, science instruments, launch services, mission ...
  28. [28]
    Juno (New Frontiers 2) - Gunter's Space Page
    Jun 2, 2025 · The selected New Frontiers science mission must be ready for launch within a mission cost cap of $700 million. Launch on an Atlas-5(551)¹ ...Missing: budget | Show results with:budget
  29. [29]
    NASA's Juno Spacecraft in Orbit Around Mighty Jupiter
    Jul 5, 2016 · After an almost five-year journey to the solar system's largest planet, NASA's Juno spacecraft successfully entered Jupiter's orbit during a 35-minute engine ...Missing: timeline | Show results with:timeline
  30. [30]
    Mission Juno
    NASA's Mission Juno is exploring Jupiter, seeking to unlock secrets of the giant planet and our solar system.JunoCam · The Team · Juno's 10th Launch Anniversary · Mission
  31. [31]
    Spacecraft - Mission Juno
    Juno is a spinning, solar-powered spacecraft in a polar orbit, built by Lockheed Martin, with components from worldwide, and tested for harsh space conditions.
  32. [32]
    Science Findings - Mission Juno
    Juno discovers that Jupiter's core is large, fuzzy and dilute. A surprise that has implications on how Jupiter formed and evolved.
  33. [33]
    OSIRIS-REx Returns to Earth, Carrying Clues to the Origin of Life
    Oct 11, 2023 · ... selected for development in 2011. OSIRIS-REx was the third mission of NASA's New Frontiers Program, a class of medium-sized missions ...
  34. [34]
    Mission Timeline
    The OSIRIS-REx spacecraft launched on Sep. 8, 2016, completed an Earth Gravity Assist on Sep. 22, 2017, and arrived at asteroid Bennu on Dec. 3, 2018.
  35. [35]
    Bennu - OSIRIS-REx Mission
    Scientists chose Bennu, a rare B-type asteroid, as the target of the OSIRIS-REx mission because of its composition, size, and proximity to Earth.
  36. [36]
    The Mission - OSIRIS-REx - The University of Arizona
    OSIRIS-REx mission launch: September 8, 2016 Sample return: September 24, 2023. OSIRIS-REx timeline graphic. Why was the University of Arizona chosen to lead?
  37. [37]
    OSIRIS-REx | Lockheed Martin
    The Lockheed Martin-built OSIRIS-REx spacecraft brought a sample of the asteroid Bennu back to Earth in September 2023, completing its 7-year mission.Missing: details | Show results with:details
  38. [38]
    THE MISSION - OSIRIS-REx Mission
    MISSION OBJECTIVES · Return and analyze a sample of Bennu's surface · Map the asteroid · Document the sample site · Measure the orbit deviation caused by non- ...
  39. [39]
    Instruments - OSIRIS-REx Mission
    OSIRIS-REx contains five instruments that will map Bennu and establish what makes up the asteroid, including elements, minerals and organic material.
  40. [40]
    OSIRIS-REx In Depth - NASA Science
    The mission, developed by scientists at the University of Arizona, will give us more information about how the early solar system formed and how life began. It ...
  41. [41]
    NASA Announces OSIRIS-REx Bulk Sample Mass
    Feb 15, 2024 · NASA's OSIRIS-REx spacecraft delivered 4.29 ounces (121.6 grams) of material from asteroid Bennu when it returned to Earth on Sep. 24, 2023.Missing: findings | Show results with:findings
  42. [42]
    Surprising Phosphate Finding in NASA's OSIRIS-REx Asteroid Sample
    Jun 26, 2024 · Early analysis of the asteroid Bennu sample returned by NASA's OSIRIS-REx mission has revealed dust rich in carbon, nitrogen, ...
  43. [43]
    NASA's OSIRIS-REx Mission Passes Critical Design Review, Moves ...
    Apr 20, 2014 · ... budget doesn't exceed a cost cap of $800 million, excluding launch costs. OSIRIS-REx is the third mission under the New Frontiers program ...<|control11|><|separator|>
  44. [44]
    OSIRIS-REx → OSIRIS-APEX (New Frontiers 3) - Gunter's Space Page
    Jun 2, 2025 · The OSIRIS-REx mission will return the first samples ever taken from a special type of asteroid holding clues to the origin of the solar system.
  45. [45]
    NASA's Dragonfly Will Fly Around Titan Looking for Origins, Signs of ...
    Jun 27, 2019 · Dragonfly will launch in 2026 and arrive in 2034. The rotorcraft will fly to dozens of promising locations on Titan looking for prebiotic chemical processes.Missing: timeline | Show results with:timeline
  46. [46]
    Dragonfly | Johns Hopkins University Applied Physics Laboratory
    Dragonfly is a NASA New Frontiers mission that will send a rotorcraft lander to explore the prebiotic chemistry and habitability of Saturn's largest moon, ...Missing: 4 | Show results with:4
  47. [47]
    Dragonfly - NASA Science
    Dragonfly, the first-of-its-kind rotorcraft to explore another world, will fly to various locations on Saturn's moon Titan to investigate the moon's ...NASA Awards Launch... · NASA’s Dragonfly Mission...Missing: objectives | Show results with:objectives<|separator|>
  48. [48]
    Science Goals and Objectives for the Dragonfly Titan Rotorcraft ...
    Jul 19, 2021 · NASA's Dragonfly mission will send a rotorcraft lander to the surface of Titan in the mid-2030s. ... Consideration of both of these solvents ...Missing: timeline | Show results with:timeline
  49. [49]
    Dragonfly Spacecraft and Instruments - NASA Science
    NASA's Dragonfly mission has cleared several key design, development and testing milestones and remains on track toward launch in July 2028. Read More. A man in ...
  50. [50]
    NASA's Dragonfly Rotorcraft Mission to Saturn's Moon Titan Confirmed
    Apr 17, 2024 · ... cost of $3.35 billion and a launch date of July 2028. This reflects a cost increase of about two times the proposed cost and a delay of more ...
  51. [51]
    NASA Awards Launch Services Contract for Dragonfly Mission
    Nov 25, 2024 · The firm-fixed-price contract has a value of approximately $256.6 million, which includes launch services and other mission related costs. The ...
  52. [52]
    Dragonfly Mission Faces Schedule Delays and Nearly $1 Billion in ...
    Sep 9, 2025 · The project's baseline commitment now exceeds $3 billion—significantly more than past New Frontiers missions that launched at a 5-year cadence.Missing: selection | Show results with:selection<|control11|><|separator|>
  53. [53]
    [PDF] New Frontiers 5 (NF5) Announcement of Opportunity Release Date ...
    NASA SMD's new target is no later than fall 2024 for the release of the final AO. This is a delay of approximately two years compared to the November 5, 2020 ...
  54. [54]
    NASA SOMA: New Frontiers 5 AO Home Page
    Aug 24, 2023 · The New Frontiers Program conducts Principal Investigator (PI)-led space science investigations in SMD's planetary programs under a not-to- ...
  55. [55]
    4 Upcoming New Frontiers 5 Announcement of Opportunity
    Each decadal review strives to strike a balance between scientific priorities, programmatic balance, and cost estimates (as compared to AO cost caps); however, ...
  56. [56]
    Scientific Themes for NASA's Next New Frontiers Class Mission
    Feb 25, 2025 · Centaur Orbiter and Lander · Ceres Sample Return · Comet Surface Sample Return · Enceladus Multiple Flyby · Io Observer · Lunar Geophysical Network ...
  57. [57]
    Proposed Science Themes for NASA's Fifth New Frontiers Mission | The National Academies Press
    ### Summary of Key Findings on Proposed Science Themes for NF-5 and Implications
  58. [58]
    Proposed Science Themes for NASA's Fifth New Frontiers Mission
    HISTORY OF THE NEW FRONTIERS PROGRAM. The NF program was developed by NASA and approved by Congress in 2002. With a cost cap of ~$1 billion, double that of ...Missing: beginnings | Show results with:beginnings
  59. [59]
    3 Impact on New Frontiers 5 Mission Theme Considerations
    The science objectives and overall goals of each New Frontiers (NF)-5 and NF-6 mission theme summarized in the Chapter 2 set the stage to evaluate the second ...
  60. [60]
    [PDF] Proposed Science Themes for NASA's Fifth New Frontiers Mission
    The science objectives and overall goals of each New Frontiers (NF)-5 and NF-6 mission theme ... “New Frontiers Program.” https://www.nasa.gov/planetarymissions/ ...<|control11|><|separator|>
  61. [61]
    NASA SOMA: New Frontiers 5 AO Announcements
    03/29/2023 - The New Frontiers 5 Program Library has been initiated, with European Space Agency Partnership and Contribution; Version 1, March 29, 2023.
  62. [62]
    NASA confirms multi-year delay in next New Frontiers competition
    Aug 28, 2023 · NASA has confirmed it is delaying the release of the call for proposals for the next New Frontiers planetary science mission, originally planned for this fall, ...<|separator|>
  63. [63]
    A billion dollars short: A progress report on the Planetary Decadal…
    Aug 21, 2024 · The PSD budget began the last decadal period at just over $1.2 billion and, over 10 years, more than doubled to $3.1 billion in FY 2022. This ...
  64. [64]
    New Frontiers 5 - NASA Spaceflight Forum
    Jun 25, 2023 · (Think of it this way: you have a proposal and your chief instrument scientist is working on a current project that ends in 2025--if you win ...
  65. [65]
    Pluto: Exploration - NASA Science
    New Horizons was the first spacecraft to explore Pluto and its five moons up close and, later, made the first close exploration of a Kuiper Belt Object. Learn ...
  66. [66]
    NASA's Juno Mission Uncovers Heart of Jovian Moon's Volcanic Rage
    Dec 12, 2024 · Scientists with NASA's Juno mission to Jupiter have discovered that the volcanoes on Jupiter's moon Io are each likely powered by their own chamber of roiling ...Missing: key | Show results with:key
  67. [67]
    NASA's Asteroid Bennu Sample Reveals Mix of Life's Ingredients
    Jan 29, 2025 · “Data from OSIRIS-REx adds major brushstrokes to a picture of a solar system teeming with the potential for life. Why we, so far, only see life ...
  68. [68]
    Asteroid Bennu comes from a long-lost salty world with ingredients ...
    Jan 29, 2025 · These samples from Bennu are an incredible discovery, showing that the building blocks of life were widespread across the early solar system.
  69. [69]
    Juno Mission to Jupiter - eoPortal
    Aug 9, 2021 · NASA's Juno mission will allow us to examine this gas giant planet from its innermost core to the outer reaches of its enormous magnetic force field.
  70. [70]
    Discovery Stories - New Horizons
    A decade-long search for distant, icy objects in the Kuiper Belt resulted in the discovery of the mission's first post-Pluto flyby target, Arrokoth. Read more » ...
  71. [71]
    New Horizons NASA's Mission to Pluto and the Kuiper Belt
    Mar 14, 2023 · The discovery of these features just adds to our understanding of the processes that shape Pluto and other icy planets in our solar system, and ...
  72. [72]
    Kuiper Belt: Exploration - NASA Science
    Nov 3, 2024 · The Kuiper Belt is named for astronomer Gerard Kuiper, who published a scientific paper in 1951 that speculated about objects beyond Pluto.
  73. [73]
    NASA Juno finds Jupiter's Jet-Streams Are Unearthly
    Mar 7, 2018 · Data collected by NASA's Juno mission to Jupiter indicate that the atmospheric winds of the gas-giant planet run deep into its atmosphere.Missing: broader | Show results with:broader
  74. [74]
    NASA's Bennu Samples Reveal Complex Origins, Dramatic ...
    Aug 22, 2025 · Asteroid Bennu, sampled by NASA's OSIRIS-REx mission in 2020, is a mixture of dust that formed in our solar system, organic matter from ...
  75. [75]
    Samples from asteroid Bennu contain secrets of the early solar system
    Aug 25, 2025 · Their work, published in Nature Astronomy, shows that the elements in the asteroid Bennu reflect the early composition of the solar system. “We ...
  76. [76]
    Connolly: Bennu samples reveal clues to solar system origins, water ...
    Aug 22, 2025 · Three newly published studies from NASA's OSIRIS-REx mission team are shedding light on the complex history of asteroid Bennu and its parent ...
  77. [77]
    Jupiter's Influence - Mission Juno
    By learning about Jupiter, we can better understand the early history of the solar system and the conditions in which Earth was born. View Mission Section.Missing: discoveries broader implications
  78. [78]
    [PDF] NASA Assessments of Major Projects - GAO
    Jun 23, 2022 · program or project cost parameters, such as if development cost growth is 15 percent or more of the estimate in the baseline report or a ...
  79. [79]
    FY23 Budget Outcomes: NASA - AIP.ORG
    Jan 27, 2023 · The overall New Frontiers budget increased from $284 million to $478 million, as requested. Of the portion not going to Dragonfly, the OSIRIS- ...
  80. [80]
    Next NASA New Frontiers mission could face extended delay
    Jul 27, 2023 · NASA, in its fiscal year 2024 budget proposal, requested $3.38 billion for planetary science programs. That did not include any money for the ...
  81. [81]
    Budget Archives - NASA Watch
    ... NASA's Management Of The Dragonfly Project“ from the NASA Office of Inspector General which highlights schedule delays and cost overruns for Dragonfly. NASA ...
  82. [82]
    [PDF] Using Historical NASA Cost and Schedule Growth to Set Future ...
    An examination of this historical data has shown that such space projects often experience schedule delays and higher costs relative to initial estimates and ...
  83. [83]
    What Happens When Space Projects Go Over Budget? The Curious ...
    Dec 8, 2014 · The AO release and mission selection for New Frontiers 2 (Juno) occurred on schedule, but the New Frontiers 3 AO release missed the target date ...
  84. [84]
    Overstuffed Nasa spacecraft Osiris-Rex losing particles after ...
    Oct 23, 2020 · A Nasa spacecraft is stuffed with so much asteroid rubble from this week's grab that it's jammed open and precious particles are drifting away ...
  85. [85]
    NASA OSIRIS-REX Mission Springs Leak After Touching Asteroid
    Oct 23, 2020 · The OSIRIS-REX spacecraft collected rock and dirt samples from Bennu, but it appears to be losing some of what it grabbed.
  86. [86]
    OSIRIS-REx parachute deployment affected by wiring error
    Dec 6, 2023 · The drogue parachute on the OSIRIS-REx sample return capsule failed to deploy properly because of a design error, a flaw that did not prevent a safe landing of ...Missing: overruns | Show results with:overruns
  87. [87]
    Crossed wires caused parachute problem during OSIRIS-REx ...
    Dec 7, 2023 · Crossed wires likely prevented OSIRIS-REx's return capsule from deploying its drogue parachute during its descent through Earth's atmosphere ...
  88. [88]
    Bad Wiring Almost Ruined NASA's Asteroid Sample Mission
    Dec 7, 2023 · The primary cause for the mishap was confusing labels in the design plans. NASA said the word “main” was used inconsistently between the device ...
  89. [89]
    [PDF] IG-25-011 - NASA's Management of the Dragonfly Project
    Sep 9, 2025 · The project also plans to delay development and testing activities, which can lead to late risk identification and more costly risk mitigations ...
  90. [90]
    [PDF] Life Cycle Cost Growth Study for the Discovery and New Frontiers ...
    At the time of this study, the Discovery mission cost cap was $425M and the New Frontiers mission cost cap was $700M.
  91. [91]
    [PDF] Improving the Life-Cycle Cost Management of Planetary Missions
    In second year of phase C/D, the Project experienced significant cost overruns. Cost History Data Examples. Page 9. 8. New. Frontiers.
  92. [92]
    NASA: Assessments of Major Projects | U.S. GAO
    Jun 20, 2024 · Cost overruns decreased from $7.6 billion in 2023 to $4.4 billion in 2024. Schedule overruns decreased from a total of 20.9 years in 2023 to ...Missing: Frontiers | Show results with:Frontiers
  93. [93]
    [PDF] NASACOST AND SCHEDULE OVERRUNS - NASA OIG
    Jun 14, 2018 · NASA faces challenges with cost and schedule overruns, underestimating technical complexity, funding instability, and an overly optimistic ...