Let's look at the details of each example before drawing any conclusions.
Vector of Objects
A vector of Objects has first, initial performance hit. When an object is added to the vector, it makes a copy. The vector will also make copies when it needs to expand the reserved memory. Larger objects will take more time to copy, as well as complex or compound objects.
Accessing the objects is very efficient - only one dereference. If your vector can fit inside a processor's data cache, this will be very efficient.
Vector of Raw Pointers
This may have an initialization performance hit. If the objects are in dynamic memory, the memory must be initialized first (allocated).
Copying a pointer into a vector is not dependent on the object size. This may be a performance savings depending on the object size.
Accessing the objects takes a performance hit. There are 2 deferences before you get to the object. Most processors don't follow pointers when loading their data cache. This may be performance hit because the processor may have to reload the data cache when dereferencing the pointer to the object.
Vector of Smart Pointers
A little bit more costly in performance than a raw pointer. However, the items will automatically be deleted when the vector is destructed. The raw pointers must be deleted before the vector can be destructed; or a memory leak is created.
The safest version is to have copies in the vector, but has performance hits depending on the size of the object and the frequency of reallocating the reserved memory area. A vector of pointers takes performance hits because of the double dereferencing, but doesn't incur extra performance hits when copying because pointers are a consistent size. A vector of smart pointers may take additional performance hits compared to a vector of raw pointers.
The real truth can be found by profiling the code. The performance savings of one data structure versus another may disappear when waiting for I/O operations, such as networking or file I/O.
Operations with the data structures may need to be performed a huge amount of times in order for the savings to be significant. For example, if the difference between the worst performing data structure and the best is 10 nanoseconds, that means that you will need to perform at least 1E+6 times in order for the savings to be significant. If a second is significant, expect to access the data structures more times (1E+9).
I suggest picking one data structure and moving on. Your time developing the code is worth more than the time that the program runs. Safety and Robustness are also more important. An unsafe program will consume more of your time fixing issues than a safe and robust version.