Since you marked your question with "Linux" tag I'm going to answer it according to standard pthreads implementation under linux. If you are talking about "green" threads, which are scheduled at the VM/language level instead of the OS, then your answers are mostly correct. But my comments below are on Linux pthreads.
1) Posix threads are user level threads and kernel is not aware of it.
No this is certainly not correct. The Linux kernel and the pthreads libraries work together to administer the threads. The kernel does the context switching, scheduling, memory management, cache memory management, etc.. There is other administration done at the user level of course but without he kernel, much of the power of pthreads would be lost.
2) Kernel scheduler will treat Process( with all its threads) as one entity for scheduling. It is the thread library that in turn chooses which thread to run. It can slice the cpu time given by the kernel among the run-able threads.
No, the kernel treats each process-thread as one entity. It has it's own rules about time slicing that take processes (and process priorities) into consideration but each sub-process thread is a schedulable entity.
3) User threads can run on different cpu cores. ie Let threads T1 & T2 be created by a Process(T), then T1 can run in Cpu1 and T2 can run in Cpu2 BUT they cant run concurrently.
No. Concurrent executing is expected for multi-threaded programs. That's why synchronization and mutexes are so important and why programmers put up with the complexity of multithreaded programming.
One way to prove this to you is to look at the output of
-L option to show the associated threads.
ps usually wraps multiple threaded processes into one line but with
-L you can see that the kernel has a separate virtual process-id for each thread:
ps -ef | grep 20587
foo 20587 1 1 Apr09 ? 00:16:39 java -server -Xmx1536m ...
ps -eLf | grep 20587
foo 20587 1 20587 0 641 Apr09 ? 00:00:00 java -server -Xmx1536m ...
foo 20587 1 20588 0 641 Apr09 ? 00:00:30 java -server -Xmx1536m ...
foo 20587 1 20589 0 641 Apr09 ? 00:00:03 java -server -Xmx1536m ...
I'm not sure if Linux threads still do this but historically pthreads used the
clone(2) system call to create another thread copy of itself:
Unlike fork(2), these calls allow the child process to share parts of its execution context with the calling process, such as the memory space, the table of file descriptors, and the table of signal handlers.
This is different from
fork(2) which is used when another full process is created.