Ionization Rate of Interstellar Neutral Helium from New Horizons/SWAP Observations

TL;DR

This study uses SWAP data from New Horizons to measure interstellar helium ionization rates, confirming previous IBEX findings that models underestimate these rates by about 43%, improving understanding of the local interstellar medium.

Contribution

The paper introduces a new method for analyzing SWAP data to accurately determine the interstellar helium ionization rate, validating previous underestimations by models.

Findings

SWAP observations show a 43% higher helium ionization rate than models predict.

The new analysis method accounts for spacecraft rotation and response function.

Results confirm IBEX findings of underestimated helium photoionization rates.

Abstract

Interstellar neutral (ISN) atoms enable studies of the physical conditions in the local interstellar medium surrounding the heliosphere. ISN helium, which is the most abundant species at 1 au, is directly observed by space missions, such as Interstellar Boundary Explorer (IBEX). However, some of these atoms are ionized by solar ultraviolet radiation before reaching 1 au, producing pickup ions (PUIs). A recent analysis of IBEX data suggests that the helium photoionization rates predicted by models are underestimated by up to 40%. The Solar Wind Around Pluto (SWAP) instrument on board New Horizons enables the study of PUIs giving complementary insight into the other side of the ionization process. Our goal is to verify this increased helium ionization by determining the ionization rate of ISN helium in the heliosphere based on the SWAP observations of helium PUIs. For this purpose, we analyze SWAP data collected between 2012 and 2022, at distances 22 to 54 au from the Sun. We develop a new method for fitting model distribution functions to the observational data using the maximum likelihood method. Our approach accounts for the spacecraft's rotation and the SWAP response function, which depends on both energy and inflow direction. We estimate SWAP's efficiency for helium relative to that for hydrogen and determine the ISN helium ionization rate. We find that the photoionization rate obtained from the SWAP observations is 43% larger than the rates predicted by models, confirming the IBEX results.