There are some terminology problems due more to historical accident than anything else here.
"Thread" usually refers to thread-of-control within a process, and may (does in this case) mean "a task with its own stack, but which shares access to everything not on that stack with other threads in the same protection domain".
"Process" tends to refer to a self-contained "protection domain" which may (and does in this case) have the ability to have multiple threads within it. Given two processes P1 and P2, the only way for P1 to affect P2 (or vice versa) is through some particular defined "communications channel" such as a file, pipe, or socket; via "inter-process" signals like Unix/Linux signals; and so on.
Since threads don't have this kind of barrier between each other, one thread can easily interfere with (corrupt the data used by) another thread.
All of this is independent of user vs kernel, with one exception: in "the kernel"—note that there is an implicit assumption here that there is just one kernel—you have access to the entire machine state at all times, and full privileges to do anything. Hence you can deliberately (or in some cases accidentally) disregard or turn off hardware protection and mess with data "belonging to" someone else.
That mostly covers several possibly-confused items in Q1. As for Q2, the answer to the question as asked is "it doesn't". In general, because threads do not involve (as much) protection, it's cheaper to switch from one thread to another: you do not have to tell the hardware (in whatever fashion) that it should no longer allow various kinds of access, since threads T1 and T2 have "the same" access. Switching between processes, however, as with P1 and P2, you "cross a protection barrier", which has some penalty (the actual penalty varies widely with hardware, and to some extent the skills of the OS writers).
It's also worth noting that crossing from user to kernel mode, and vice versa, is also crossing a protection domain, which again has some kind of cost.
In Linux, there are a number of ways for user processes to create what amount to threads, including both "POSIX threads" (pthreads) and the
clone call (details for
clone, which is extremely flexible, are beyond the scope of this answer). If you want to write portable code, you should probably stick with pthreads.
Within the Linux kernel, threads are done completely differently, and you will need Linux kernel documentation.
I can't properly answer Q4 since I don't have the book and am not sure what they are referring to here. My guess is that they mean that whenever any user process-or-thread makes a "system call" (requests some service from the OS), this crosses that user/kernel protection barrier, and it is then up to the kernel to verify that the user code has appropriate privileges for that operation, and then to do that operation. The part of the kernel that does this is running with kernel-level protections and thus needs to be more careful.
Some hardware (mostly obsolete these days) has (or had) more than just two levels of hardware-provided protection. On these systems, "user processes" had the least direct privilege, but above those you would find "executive mode", "system mode", and (most privileged) "kernel" or "nucleus" mode. These were intended to lower the cost of crossing the various protection barriers. Code running in "executive" did not have full access to everything in the machine, so it could, for instance, just assume that a user-provided address was valid, and try to use it. If that address was in fact invalid, the exception would rise to the next higher level. With only two levels—"user", unprivileged; and "kernel", completely-privileged—kernel code must be written very carefully. However, it's possible to provide "virtual machines" at low cost these days, which pretty much obsoletes the need for multiple hardware levels of protection. One simply writes a true kernel, then lets it run other things in what they "think" is "kernel mode". This is what VMware and other "hypervisor" systems do.