1) a .com file is the simplest place to start and will run on a dosbox, basically the program starts at something like offset 0x100 in the file, I think the first 0x100 can be whatever, dont remember
2) although true that first programs are often written and assembled by hand into machine code, we are talking about when you add two numbers save them in memory and are so happy that you take the rest of the day off. a "hello world" program that prints stuff to a video card is significantly more complicated. Now you can make a very simple one using dos system calls, and perhaps that is not what you are interested in, perhaps it is.
3) based on 2, anything more complicated than one or a few instructions at a time for testing back in the 1960s or 1970s, even when writing hand assembling a program you write your program in assembler by hand, then assemble it to machine code, then load it. Basically learn assembly language first, then learn how to generate the machine code for it, then start typing those bytes into a hex editor. It is not then 1960s, unless you enjoy excessive pain, learn the above by writing asm, using an assembler to generate the machine code, then use a disassembler to disassemble it and examine the assembly language and the machine code side by side to significantly improve the amount of time it is going to take you to get a working program. If you worked for a chip company before there were operating systems and instruction sets, you would still take advantage of other members of the team, the chip designers, etc for understanding how to make the machine code and arrange it. You wouldnt be coming at this with only high level language experience and doing it all on your own with a hope of success.
4) x86 is a horrible instruction set, if you dont know assembly I strongly discourage you to not learn it first. having an x86 is the worst excuse I have heard to learn x86 first. you already mentioned dosbox so are already planning to emulate/simulate so use a good instruction set and simulate it or buy that hardware (under $50 even under $20 will buy you a board with a much better instruction sets). I recommend simulate/emulate first and in parallel with the hardware if you choose to buy some. If you really want an education write your own simulator it is not difficult at all. Perhaps invent your own instruction set.
5) I have a collection of simulators and other bare metal resources http://github.com/dwelch67 the msp430 is not bad, you can get the hardware for under $5 if you feel the need. Arm is good, both 32/16 based (raspberry pi, sam7s, etc) and 16 bit thumb based (cortex-m based, mbed, maple mini, stm32f4 discovery, etc). The amber simulator comes from an opencores processor that I am simulating using verilator, so you can if you choose have the advantage of looking inside the processor to see what is going on at the signal level. thumbulator doesnt require anything but a c/c++ compiler to get it up and running, the "binary" file format you can type the "machine code" in hex and just go for it, with a hex editor you will be doing that anyway. I have a number of instruction set simulators to choose from, plus examples for bare metal embedded on some boards costing between $5 and say $80.
6) none of this will help you understand what a compiler does. Knowing assembly language then disassembling the compilers output is your best path toward that knowledge, machine code is not involved, no need to actually run the programs. A compiler goes from the higher level language to a lower level language (C to asm or C++ to asm for example). Then understand what an assembler does, there are many different solutions, both due to history and due to other reasons. The typical solution today is a separate compiler, assembler and linker (your compiler calls the assembler and linker for you unless you tell it not to, the three steps are hidden from view, in fact the compile process may be more than one program that is run to complete that task). Assemblers that output a binary will have to resolve the whole program, assemblers that output to an object will leave holes in the machine code for the linker to fill in. things like branching or calling items in another object that it cannot encode until the linker places things in the binary and knows the spacing/addressing. Also accessing variables that live in other objects.
You are likely not seeing actual examples on hex editing a program because first off it is such a broad question there isnt a simple answer (what operating, system, what system calls or are you creating those, what file format, what hex editor, etc). Also because it is a high level question and problem, the real questions are where do I learn assembly, where do I learn about the relationship between assembly and machine code, where do I learn about system calls (which are not an assembly question, they are unrelated to learning asm, you learn assembly language itself then you learn to USE it as a tool to perform system calls if you cannot perform the system calls directly using a higher language), where do I learn about executable file formats like .com, .exe, coff, elf, etc. What is a good or easy or some adjective, hex editor that runs on xyz operating system or environment. Ask those questions separately and you will find the answers and examples and once you have those answers you will know how to make a program using a hex editor typing in machine code. A shorter example is that you ARE seeing hex examples of complete programs when you see the disassembly of a program posted at SO, some of those are complete programs shown in hex. and if you know the file format you can simply type that stuff into a hex editor.