Here is one approach I would try: separate the flag for isAlive from the rest of the data structure. This seems like a piece of data that is read often, but hardly written. Use a single uint to track the state of 32 particles. Use zero for alive, and 1 for dead -- essentially creating an isDead list. I assume you will have many more alive particles than dead ones.
The values can be read (32 at a time) into local memory when you need. This allows you to make a kernel that quickly iterates through the data, looking for a non-zero value. The big performance boost here comes with the dense data and thereby reducing the memory overhead of storing and loading the flags. This makes checking one of these values a much cheaper operation, allowing you to iterate through them more quickly. You will need to be careful when changing the 32 bit values so as to not corrupt the other data sharing the same uint (interlacing could help with this). The instructions clz, and popcount will be helpful when you need to narrow down the exact position of the 1 bits. opencl 1.2 refcard
possible optimization #1:
If you want, you can try interlacing the values so that the first uint is tracking indices 0,32,64,96,...,992 and the second uint represents 1,33,65,97,...,993 and so on. This may allow the work item that typically works on specific particles to read 32 consecutive isDead states. This could turn out to be more effort than it is worth, but that depends on your application.
possible optimization #2:
If the dead particles are really sparse, it might be worth it to track the isDead list on higher level. Using the same technique, it is easy to reduce the isDead bit/uint list again by a factor of 32. Each bit on the 2nd level represents the corresponding uint's state. ie: if any bits in uint N are set, bit N of this list will also be set. Only useful when a lot of zeros are expected in your data, but this extra step can save a lot of cycles searching for rare 'on' bits in the data. The total memory overhead for this including the original isDead data would amount to: memBits = ceil(particleCount/32) + ceil(particleCount/32^2), or about 128kb + 4kb for every 2^20 particles.
Using the above, it is possible to write a kernel that will return the number of dead particles in a given range, and quickly find one of the next available dead particles.