An Analysis of the Shapes of Interstellar Extinction Curves. VI. The Near-IR Extinction Law

TL;DR

This study analyzes near-infrared interstellar extinction curves, finding that a simple power-law model varies significantly across sight lines and proposing a new functional form that better fits data and yields consistent R(V) estimates.

Contribution

It introduces a new functional form for NIR extinction that overcomes limitations of the power-law model, providing more accurate and consistent R(V) estimates across different wavelengths.

Findings

Power-law fits vary significantly with sight line.

A new functional form provides better fits and consistent R(V) estimates.

The relation R(V) = -1.36 E(K-V)/E(B-V) - 0.79 estimates R(V) with ±0.12 accuracy.

Abstract

We combine new HST/ACS observations and existing data to investigate the wavelength dependence of NIR extinction. Previous studies suggest a power-law form, with a "universal" value of the exponent, although some recent observations indicate that significant sight line-to-sight line variability may exist. We show that a power-law model provides an excellent fit to most NIR extinction curves, but that the value of the power, beta, varies significantly from sight line-to-sight line. Therefore, it seems that a "universal NIR extinction law" is not possible. Instead, we find that as beta decreases, R(V) [=A(V)/E(B-V)] tends to increase, suggesting that NIR extinction curves which have been considered "peculiar" may, in fact, be typical for different R(V) values. We show that the power law parameters can depend on the wavelength interval used to derive them, with the beta increasing as longer wavelengths are included. This result implies that extrapolating power law fits to determine R(V) is unreliable. To avoid this problem, we adopt a different functional form for NIR extinction. This new form mimics a power law whose exponent increases with wavelength, has only 2 free parameters, can fit all of our curves over a longer wavelength baseline and to higher precision, and produces R(V) values which are consistent with independent estimates and commonly used methods for estimating R(V). Furthermore, unlike the power law model, it gives R(V)'s that are independent of the wavelength interval used to derive them. It also suggests that the relation R(V) = -1.36 E(K-V)/E(B-V) - 0.79 can estimate R(V) to +/-0.12. Finally, we use model extinction curves to show that our extinction curves are in accord with theoretical expectations.