Linear Independence of Harmonic Numbers over the field of Algebraic Numbers
Abstract: Let $H_n =\sum\limits_{k=1}n \frac{1}{k}$ be the $n$-th harmonic number. Euler extended it to complex arguments and defined $H_r$ for any complex number $r$ except for the negative integers. In this paper, we give a new proof of the transcendental nature of $H_r$ for rational $r$. For some special values of $q>1,$ we give an upper bound for the number of linearly independent harmonic numbers $H_{a/q}$ with $ 1 \leq a \leq q$ over the field of algebraic numbers. Also, for any finite set of odd primes $J$ with $|J|=n,$ define $$W_J=\overline{\mathbb{Q}}-\text {span of } { H_1, \ H_{a_{j_i}/q_i} | \ 1 \leq a_{j_i} \leq q_i -1, \ 1 \leq j_i \leq q_i-1, \ \ \forall q_i \in J}.$$ Finally, we show that $$\text{ dim }{\overline{\mathbb{Q}}} ~W_J=\sum\limits{\substack{i=1 \ q_i \in J}}n \frac{\phi (q_i )}{2} + 2.$$
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