Answer:
Because each term of the sequence generates numbers with more than 1 and itself as dividers
Step-by-step explanation:
Just for the sake of correction.
[tex]1. Explain\: why\: the\: numbers\: n! +2, n!+ 3, n!+ 4, ..., n! \\n \:must\: all\: be\: composite.[/tex]
1) Let's consider that
n! =n(n-1)(n-2)(n-3)...
2)And examine some numbers of that sequence above:
[tex]n!+2[/tex]
Every Natural number plugged in n, and added by two will a be an even number not only divisible by two, but in some cases by other numbers for example,n=4, then 4!+2=26 which has four dividers.
3) Similarly, the same happens to
[tex]n!+3[/tex] and [tex]n!+4[/tex]
Where we can find many dividers.
There's an example of a sequence, let's start with a prime number greater than 1
Let n=11
[tex]\left \{ n!+2,n!+3,n!+4,n!+5,n!+6,...n!+n. \right \}\\\left \{ 11!+2,11!+3,11!+4,11!+5,11!+6,11!+7,11!+8,...11!+11 \right \}\\\\[/tex]
That's a long sequence of consecutive composite numbers, n=11.
[tex]\left \{39916802, 39916803,39916804,39916805,39916806,39916807,...,39916811,39916812 \right \}[/tex]
