New Horizons Venetia Burney Student Dust Counter Observes Higher than Expected Fluxes Approaching 60 AU (2401.01230v1)

Abstract: The NASA New Horizons Venetia Burney Student Dust Counter (SDC) measures dust particle impacts along the spacecraft's flight path for grains with mass $\ge$ $10^{-12}$ g, mapping out their spatial density distribution. We present the latest SDC dust density, size distribution, and flux measurements through 55 au and compare them to numerical model predictions. Kuiper Belt Objects (KBOs) are thought to be the dominant source of interplanetary dust particles (IDP) in the outer solar system due to both collisions between KBOs, and their continual bombardment by interstellar dust particles (ISD). Continued measurements through 55 au show higher than model-predicted dust fluxes as New Horizons approaches the putative outer edge of the Kuiper Belt (KB). We discuss potential explanations for the growing deviation: radiation pressure stretches the dust distribution to further heliocentric distances than its parent body distribution; icy dust grains undergo photo-sputtering that rapidly increases their response to radiation pressure forces and pushes them further away from the sun; and the distribution of KBOs may extend much further than existing observations suggest. Ongoing SDC measurements at even larger heliocentric distances will continue to constrain the contributions of dust production in the KB. Continued SDC measurements remain crucial for understanding the Kuiper Belt and the interpretation of observations of dust disks around other stars.

• The paper reports unexpectedly high dust fluxes near 60 AU measured using PVDF detectors, exceeding predictions from current models.
• The paper employs in-situ impact counts to calculate spatial dust density, converting these counts into mass fluxes with assumed silicate properties and impact velocities.
• The paper highlights discrepancies from established Kuiper Belt dust models, suggesting significant roles for radiation pressure and photo-sputtering on icy particles.

Investigating the Dust Environment Beyond 55 AU with the New Horizons Venetia Burney Student Dust Counter

The research conducted by Doner et al. presents an analysis of data collected by the Venetia Burney Student Dust Counter (SDC) on the New Horizons spacecraft, which reveals higher-than-anticipated dust fluxes as the spacecraft approaches 60 AU from the Sun. Utilizing in-situ measurements, the paper focuses on the spatial density and distribution of interplanetary dust particles (IDPs) primarily sourced from Kuiper Belt Objects (KBOs). This paper provides a critical comparison between the empirical data and current models, highlighting discrepancies and proposing potential causes.

Instrumentation and Methodology

The SDC is an experimental instrument comprising polyvinylidene fluoride (PVDF) detectors configured to measure dust particle impacts. These detectors are capable of identifying particles with a minimum mass of 10^-12 grams. Over the span of its mission, beginning from its launch in 2006, New Horizons and its SDC have gathered data through its journey beyond the Kuiper Belt's outer regions.

Key Findings

1. Unexpected Dust Flux: The measurements obtained through 55 AU show increased dust flux densities compared to predictive models of the interplanetary dust environment.
2. Analytical Method: The paper analyzed the spatial density of dust, computed using counts of micro-particle impacts, which are then converted into mass fluxes by assuming typical silicate material properties and impact velocities derived from spacecraft speed and dust orbital characteristics.
3. Deviations from Model Predictions: Beyond 42 AU, a noticeable rise in dust flux not predicted by established models was recorded. Several explanations for this deviation include the dynamic behavior of dust influenced by radiation pressure, suggesting that smaller, icy particles might be affected differently than initially modeled.

Theoretical Implications

The findings require reconsideration of current theoretical models of the creation and distribution dynamics of dust in the Kuiper Belt region. The discrepancies suggest either an incomplete understanding of the source distributions of KBOs or the evolving nature of IDPs due to forces such as radiation pressure and the photo-sputtering of icy particles.

1. Increased Dust Distribution Likely Due to Radiation Pressure: Radiation pressure may extend the dust particle distribution beyond their sources more than previously accounted for, particularly affecting smaller, icy particles.
2. Potential Underestimation of Dust Sources: The possibility exists that the spatial extent or population of dust-producing bodies in the Kuiper Belt is greater than identified, necessitating reevaluation of KBO observations or assumptions.
3. Photo-sputtering Effects: Photo-sputtering of icy particles could alter the mass and response of dust grains to radiation pressure, leading to greater distribution of dust than anticipated.

Future Research Directions

The research underscores the importance of continued monitoring by SDC as New Horizons progresses further into the heliosphere beyond 100 AU. This will not only refine models that predict dust flux from KBOs but also provide insights applicable to understand circumstellar dust disks more broadly.

Understanding the characteristics and distribution of dust in this region may help bridge knowledge gaps regarding dust disks around other stars and the broader dynamics of the solar system's periphery. Continued SDC operations could also elucidate transition zones where interstellar dust begins to predominate or contribute significantly to the micrometeoroid environment.

In summary, this research by Doner et al. presents an important set of observations necessitating the reevaluation of theoretical models of the outer solar dust environment and underscores the potential complexity inherent in these interstellar interactions.