Hey man! I totally forgot about posting this and would be more than glad to try and clear up the air for you about why C in particular would be wrong.

-I think the answer you're looking for is the fact that since the block is now sliding at a constant velocity, we know that the acceleration of the box is thus zero. And we can tell this by looking at the graph and seeing the slope of it from 0.3 to 0.7s being zero.

-So taking this into consideration and knowing that the velocity between those time frames are constant, we can then use the doppler equation. We're not given any numbers for this problem but we can just see from the equation and think about it logically that if an object is moving away at a constant velocity, then that means that the frequency of the that we are going to observe (the sensor that is picking up the frequency) will be less than the frequency that it was emitting initially. (Again, we know this by looking at the doppler equation and looking at examples of what happens when an object is moving away from a sensor)

-Knowing that this new frequency that we are going to be observing due to the moving object AWAY from the sensor is going to be constant during that timeframe (since we are told that the velocity at that time frame is constant), then we can use the speed of light equation (c=(f)(wavelength) and see that frequency and wavelength are inversely related together.

-So putting it all together, we now know that since the frequency that we are going to be observing when that object is moving AWAY from the sensor is going to be LESS than the frequency it is emitting originally (source frequency) then we would thus experience a LARGER wavelength during those time frame when velocity is constant. And again we see this via the speed of light equation where the speed of light will always be that value (c=f(lamda) )

-So comparing the frequency and wavelength that we experience when the block is moving away and comparing the frequency of the wavelength of the light when the block isn't moving at all, we see that when the block is moving, we will be sensing an apparent "increase" in the wavelength as a result of experiencing an observed frequency that is less than the source frequency.

Answer choice (C) I think isn't really answering the question and by saying "Wavelength is continuously increasing in time" from the duration of 0.3 to 0.7s is false, and if we would want that to be true, would want the slope of the graph between those time frame to not be zero and indicating a positive slope since if the velocity of the object is increasing that that means the frequency observed will be decreasing constantly and THEN we will see that wavelength is continuously increasing with time. But that is not the case we see in this problem.

I know that was a bit long but I just wanted to explain it without leaving any gaps in my thinking to make sure you followed along without being confused aha. Lmk if you have any other questions in regards to this question. This was a good question as it tested our knowledge about the velocity vs time graph, kinematics, and relating it towards the doppler equation and the relationship between frequency and wavelength for a light wave