Exponents

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\( a^{b}\)

\( a_{b}^{c}\)

\({a_{b}}^{c}\)

\(a_{b}\)

\(\sqrt{a}\)

\(\sqrt[b]{a}\)

\(\frac{a}{b}\)

\(\cfrac{a}{b}\)

\(+\)

\(-\)

\(\times\)

\(\div\)

\(\pm\)

\(\cdot\)

\(\amalg\)

\(\ast\)

\(\barwedge\)

\(\bigcirc\)

\(\bigodot\)

\(\bigoplus\)

\(\bigotimes\)

\(\bigsqcup\)

\(\bigstar\)

\(\bigtriangledown\)

\(\bigtriangleup\)

\(\blacklozenge\)

\(\blacksquare\)

\(\blacktriangle\)

\(\blacktriangledown\)

\(\bullet\)

\(\cap\)

\(\cup\)

\(\circ\)

\(\circledcirc\)

\(\dagger\)

\(\ddagger\)

\(\diamond\)

\(\dotplus\)

\(\lozenge\)

\(\mp\)

\(\ominus\)

\(\oplus\)

\(\oslash\)

\(\otimes\)

\(\setminus\)

\(\sqcap\)

\(\sqcup\)

\(\square\)

\(\star\)

\(\triangle\)

\(\triangledown\)

\(\triangleleft\)

\(\Cap\)

\(\Cup\)

\(\uplus\)

\(\vee\)

\(\veebar\)

\(\wedge\)

\(\wr\)

\(\therefore\)

\(\left ( a \right )\)

\(\left \| a \right \|\)

\(\left [ a \right ]\)

\(\left \{ a \right \}\)

\(\left \lceil a \right \rceil\)

\(\left \lfloor a \right \rfloor\)

\(\left ( a \right )\)

\(\vert a \vert\)

\(\leftarrow\)

\(\leftharpoondown\)

\(\leftharpoonup\)

\(\leftrightarrow\)

\(\leftrightharpoons\)

\(\mapsto\)

\(\rightarrow\)

\(\rightharpoondown\)

\(\rightharpoonup\)

\(\rightleftharpoons\)

\(\to\)

\(\Leftarrow\)

\(\Leftrightarrow\)

\(\Rightarrow\)

\(\overset{a}{\leftarrow}\)

\(\overset{a}{\rightarrow}\)

\(\approx \)

\(\asymp \)

\(\cong \)

\(\dashv \)

\(\doteq \)

\(= \)

\(\equiv \)

\(\frown \)

\(\geq \)

\(\geqslant \)

\(\gg \)

\(\gt \)

\(| \)

\(\leq \)

\(\leqslant \)

\(\ll \)

\(\lt \)

\(\models \)

\(\neq \)

\(\ngeqslant \)

\(\ngtr \)

\(\nleqslant \)

\(\nless \)

\(\not\equiv \)

\(\overset{\underset{\mathrm{def}}{}}{=} \)

\(\parallel \)

\(\perp \)

\(\prec \)

\(\preceq \)

\(\sim \)

\(\simeq \)

\(\smile \)

\(\succ \)

\(\succeq \)

\(\vdash\)

\(\in \)

\(\ni \)

\(\notin \)

\(\nsubseteq \)

\(\nsupseteq \)

\(\sqsubset \)

\(\sqsubseteq \)

\(\sqsupset \)

\(\sqsupseteq \)

\(\subset \)

\(\subseteq \)

\(\subseteqq \)

\(\supset \)

\(\supseteq \)

\(\supseteqq \)

\(\emptyset\)

\(\mathbb{N}\)

\(\mathbb{Z}\)

\(\mathbb{Q}\)

\(\mathbb{R}\)

\(\mathbb{C}\)

\(\alpha\)

\(\beta\)

\(\gamma\)

\(\delta\)

\(\epsilon\)

\(\zeta\)

\(\eta\)

\(\theta\)

\(\iota\)

\(\kappa\)

\(\lambda\)

\(\mu\)

\(\nu\)

\(\xi\)

\(\pi\)

\(\rho\)

\(\sigma\)

\(\tau\)

\(\upsilon\)

\(\phi\)

\(\chi\)

\(\psi\)

\(\omega\)

\(\Gamma\)

\(\Delta\)

\(\Theta\)

\(\Lambda\)

\(\Xi\)

\(\Pi\)

\(\Sigma\)

\(\Upsilon\)

\(\Phi\)

\(\Psi\)

\(\Omega\)

\((a)\)

\([a]\)

\(\lbrace{a}\rbrace\)

\(\frac{a+b}{c+d}\)

\(\vec{a}\)

\(\binom {a} {b}\)

\({a \brack b}\)

\({a \brace b}\)

\(\sin\)

\(\cos\)

\(\tan\)

\(\cot\)

\(\sec\)

\(\csc\)

\(\sinh\)

\(\cosh\)

\(\tanh\)

\(\coth\)

\(\bigcap {a}\)

\(\bigcap_{b}^{} a\)

\(\bigcup {a}\)

\(\bigcup_{b}^{} a\)

\(\coprod {a}\)

\(\coprod_{b}^{} a\)

\(\prod {a}\)

\(\prod_{b}^{} a\)

\(\sum_{a=1}^b\)

\(\sum_{b}^{} a\)

\(\sum {a}\)

\(\underset{a \to b}\lim\)

\(\int {a}\)

\(\int_{b}^{} a\)

\(\iint {a}\)

\(\iint_{b}^{} a\)

\(\int_{a}^{b}{c}\)

\(\iint_{a}^{b}{c}\)

\(\iiint_{a}^{b}{c}\)

\(\oint{a}\)

\(\oint_{b}^{} a\)

No problem sis

I taught of that too.

Well, nobody is above mistake 💯

Then who is the antagonist in the novel?

Aliya is the antagonist in the novel.

There's no antagonist in the novel

correction noted thanks.

You're welcome dear

Add me on Facebook @Clinton physicist

Good morning, sorry I'm not on Facebook.

Oh sorry, if you don't mind, how about whatsApp?

Well,even though i have access to electronics,i decided not to be on any social media platforms,i only use my email because it helps me to study.

Oh, that's a sign of a serious student

Well, it's nice replying your comment

Have a nice day

Same here,i see you exhibiting one too,thanks

You're welcome

Your always welcome

Am so sorry for the previous answer,there is no antagonist in the novel.

Please ignore my reply, I taught you were talking to me

Hi, no though,but ur right,we all make mistakes but i think that the ability to acknowledge and take responsibility for our actions is what makes each and everyone of us special and unique.

It's nice hearing from you again.