I have to show that for any pair of sets [imath]A,B \subseteq X[/imath], if [imath]A\cap B=\emptyset[/imath] then [imath]A\cap B^c=A[/imath]; with [imath]B^c[/imath] I mean the complement of [imath]B[/imath] in [imath]X[/imath].
Since the intersection of two sets is always a subset of both sets, it is immediate that [imath]A \cap B^c \subseteq A[/imath].
Let now [imath]x \in A[/imath]. By hypothesis it is [imath]A \cap B=\emptyset[/imath], hence for any [imath]x \in X[/imath] it is [imath]x \notin A \cap B[/imath]. That is, for any [imath]x \in X[/imath] it is [imath]x \in (A \cap B)^c[/imath] and so [imath]x \in A^c \cup B^c[/imath]. But we assumed that [imath]x \in A[/imath], so from [imath]x \in A^c \cup B^c[/imath] it follows that [imath]x \in B^c[/imath]. Hence we have both [imath]x \in A[/imath] and [imath]x \in B^c[/imath], that is [imath]x \in A \cap B^c[/imath]. Since [imath]x \in A[/imath] is arbitrary, it follows that [imath]A \subseteq A \cap B^c[/imath]. It this proof valid?
Since the intersection of two sets is always a subset of both sets, it is immediate that [imath]A \cap B^c \subseteq A[/imath].
Let now [imath]x \in A[/imath]. By hypothesis it is [imath]A \cap B=\emptyset[/imath], hence for any [imath]x \in X[/imath] it is [imath]x \notin A \cap B[/imath]. That is, for any [imath]x \in X[/imath] it is [imath]x \in (A \cap B)^c[/imath] and so [imath]x \in A^c \cup B^c[/imath]. But we assumed that [imath]x \in A[/imath], so from [imath]x \in A^c \cup B^c[/imath] it follows that [imath]x \in B^c[/imath]. Hence we have both [imath]x \in A[/imath] and [imath]x \in B^c[/imath], that is [imath]x \in A \cap B^c[/imath]. Since [imath]x \in A[/imath] is arbitrary, it follows that [imath]A \subseteq A \cap B^c[/imath]. It this proof valid?
