The Linear Slicing Method for Equal Sums of Like Powers: Modular and Geometric Constraints

Abstract

We study the Diophantine equation ak + bk = ck + dk with integer variables and exponent k>1, under the linear constraint (c+d) - (a+b) = h. We analyze the geometry and arithmetic of these linear slices. On the central slice h=0, we prove strictly convex uniqueness: distinct unordered pairs with the same sum yield distinct power sums. For shifted slices h≠ 0, we establish a Modular Divisibility Obstruction (MDO): any solution requires h to be divisible by a specific squarefree modulus Mk = Πp-1 k-1 p. This condition creates a strong divisibility filter; for example, if k=13, the obstruction eliminates 99.96\% of all possible shifts. We combine this arithmetic constraint with a geometric exclusion zone principle and a global overlap bound, showing that the slice size must satisfy \S, S+h\ |h|. Finally, we prove an asymptotic dominance bound k \S, S+h\ 2, implying that for any fixed slice, solutions cannot exist for sufficiently large k.

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