Abstract
Aims. We investigate the influence of three basic factors on water production rate as a function of heliocentric distance: nucleus shape, the spin axis orientation, and the distribution of activity on a comet’s surface. Methods. We used a basic water sublimation model driven by solar insolation to derive total production rates for different nuclei shapes and spin axis orientations using the orbital parameters of 67P/Churyumov-Gerasimenko. We used known shape models derived from prior missions to the Jupiter Family and short period comets. The slopes of production rates versus heliocentric distance were calculated for the different model setups. Results. The standard (homogeneous) outgassing model confirms the well-known result regarding the heliocentric dependence of water production rate that remains invariant for different nuclei shapes as long as the rotation axis is perpendicular to the orbital plane. When the rotation axis is not perpendicular, the nucleus shape becomes a critically important factor in determining the water production curves as the illuminated cross section of the nucleus changes with heliocentric distance. Shape and obliquity can produce changes in the illuminated cross section of up to 50% over an orbit. In addition, different spin axis orientations for a given shape can dramatically alter the pre- and post-perihelion production curves, as do assumptions about the activity distribution on the surface. If, however, the illuminated cross section of the nucleus is invariant, then the dependence on the above parameters is weak, as demonstrated here with the 67P/Churyumov-Gerasimenko shape. The comets Hartley 2 and Wild 2 are shown to yield significantly different production curve shapes for the same orbit and orientation as 67P/CG, varying by as much as a factor of three as a result of only changing the nucleus shape. Finally, we show that varying just three basic parameters, shape, spin axis orientation, and active spots distribution on the surface can lead to arbitrary deviations from the expected inverse square law dependence of water production rates near 1 au. Conclusions. With the results obtained, we cannot avoid the conclusion that, without prior knowledge of basic parameters (shape, spin axis orientation, activity locations), it is difficult to reveal the nature of cometary outgassing from the heliocentric water production rates. Similarly, the inter-comparison of water production curves of two such comets may not be meaningful.
Highlights
Comets are icy bodies that heat up as they approach the Sun and sublimate volatile material from their nuclei to create a surrounding tenuous gas coma
We investigate the influence of three basic factors on water production rate as a function of heliocentric distance: nucleus shape, the spin axis orientation, and the distribution of activity on a comet’s surface
The water production rate, Q, increases as the distance between the nucleus and the Sun decreases due to increasing solar flux, nearly with an inverse square law dependence, but this is heliocentric-distance dependent: for volatile ices such as CO and CO2, the production rates can be theoretically approximated by an inverse square law at distances less than ∼4 au; for water, which has a higher sublimation temperature, the slope is usually much steeper between 1 and 4 au, and only approaches rh−2 within 1 au of the Sun (Cowan & A’Hearn 1979)
Summary
Comets are icy bodies that heat up as they approach the Sun and sublimate volatile material from their nuclei to create a surrounding tenuous gas coma. We explore how the three basic factors – nucleus shape, obliquity of the rotation axis, and activity distribution – affect the water production rate of comets and their respective slopes. We explore how the three basic factors – nucleus shape, obliquity of the rotation axis, and activity distribution – affect the water production rate of comets and their respective slopes1 It has been known for a long time (Sekanina 1981) that the orientation of the spin axis is very important for the light curves (brightness) of comets, with highly oblique objects like 6P/d’Arrest being able to sustain their brightness weeks after perihelion. With more free parameters added to the problem it is unlikely that we can break the demonstrated degeneracy, if at least the basic nucleus shape, spin axis orientation, and the active spot distributions are unknown
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