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Mana in Haar-random states

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 Added by Christopher White
 Publication date 2020
  fields Physics
and research's language is English




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Mana is a measure of the amount of non-Clifford resources required to create a state; the mana of a mixed state on $ell$ qudits bounded by $le frac 1 2 (ell ln d - S_2)$; $S_2$ the states second Renyi entropy. We compute the mana of Haar-random pure and mixed states and find that the mana is nearly logarithmic in Hilbert space dimension: that is, extensive in number of qudits and logarithmic in qudit dimension. In particular, the average mana of states with less-than-maximal entropy falls short of that maximum by $ln pi/2$. We then connect this result to recent work on near-Clifford approximate $t$-designs; in doing so we point out that mana is a useful measure of non-Clifford resources precisely because it is not differentiable.



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