Saturn being at 10 A.U. means sunlight on Titan's cloud tops is about 1/100 that on Earth's. That's 4000 times the illumination of Earth's moon. Titan's atmosphere is described as opaque smog. If it were 99.97% opaque the surface would still be illuminated like a full moon. Photos from Huygens seem to show some light gets through.
Would a (warmly-insulated) astronaut see pitch black? A diffusely glowing brown sky? A foggy city streetlamp? I'm finding it hard to picture.
Newbie Titan researcher here! I was wondering about this same question, but there are a few papers that have since answered your questions. I'll summarize their findings below:
TLDR: For an astronaut, the sunset would be quite underwhelming, much like being in a sand storm or thick smog. The sky will have no real change in its orange color. The Sun disappears well before reaching the horizon. You will need infrared goggles to see better sunsets.
Long answer
Overall, we actually observe that the twilight periods (sunrise/sunset) are brighter than the day on Titan from infrared to UV wavelengths due to the intense forward Mie scattering from the haze. This finding was found with Cassini images in various wavelengths (Garcia Muñoz et al. 2017) and confirmed with radiative-transfer models (Barnes et al. 2018).
The models of Barnes et al. 2018 provide useful insights into a standard sunny day on Titan. This figure shows the Sun setting from early afternoon and until after dusk in visible, near-infrared, 5 micron light. The image shows a "rolled-out" version of the sky as seen from the surface of Titan. The leftmost column shows the Sun and progresses toward the antisolar point to the right side. The top and bottom of the image are zenith and the horizon respectively. The ZD represents the angle between the Sun and zenith. The first diagram below explains the format of the "rolled-out" sky images in the 2nd figure:
We can note some key details about the sunsets:
Another crazy detail is that the twilight zone may extend 30° past the terminator line. This means that the surface visibility at infrared and visible wavelengths will be brighter than the full Moon for up to 1.25 days before sunrise or after sunset! This is about 20x longer than the usual twilight period on Earth.
One final result from the paper was the intriguing lack of near-horizon illumination at all wavelengths and times of day. On Earth, the opposite occurs due to Rayleigh scattering and its lower optical depth. However, this effect may be occurring since the paper explicitly did not consider Rayleigh scattering from liquid methane-ethane droplets.
The Huygens probe that landed on Titan back in 2005 had a special flood-light affixed to its cameras because it's supposedly too dark to take pictures with any detail during Titans day without it.
Images from the DISR Side-Looking Imager and from the Medium Resolution Imager, acquired after Huygens' landing on Titan, were merged to produce this image.
Little sunlight reaches the surface, due to its thick haze, and large distance from the sun. I would imagine it being like an extremely overcast, late afternoon here on earth, everyday.
Above is a picture of the cameras that Huygens used to snap the pictures. They were aided by the spotlight in the middle (the larger, goldish disc)
It should be like about 5-10 minutes after sunset on Earth. At that time the global horizontal irradiance (with clear skies) is typically measured (e.g. with the NOAA SurfRAD network) to be about 1 W/m**2, about .001 times the mid-day value. Similarly, about 10% of the light incident on Titan reaches the surface via scattering, based on a green light optical depth of 8 and reasonable assumptions of backscatter fraction and single scattering albedo. This combines with a baseline value of 1% solar irradiance at the top of Titan's atmosphere compared with Earth's (due to being 10AU from the Sun).
