What question did this study set out to answer?

This study examines the arithmetic properties of the power sequence generated by the Gaussian integer 2+i, particularly focusing on its connection to Pythagorean triples.

May 21, 2026Open Access

Arithmetic Properties of Iterated Gaussian Integer Powers: The (2+i)n Cascade

Key Points

This study examines the arithmetic properties of the power sequence generated by the Gaussian integer 2+i, particularly focusing on its connection to Pythagorean triples.
Derived identities involving the Gaussian norm for the power sequence (2+i)n
Established a parity alternation theorem for the real and imaginary components of the sequence
Computed results to report on primitivity and polynomial characteristics.
The fourth power (2+i)4 yields the primitive Pythagorean triple (7, 24, 25)
The closed-form polynomial f(a) = 9a4 - 2a2 + 1 gives f(2) = 137
Rotational closure occurs at n = 4, with arg(zn) exceeding pi/2.

Abstract

We study the arithmetic of the power sequence zn for the Gaussian integer seed z = 2+i. The sequence generates Pythagorean triples at every level via the identity N((2+i)n) = 5n, where N denotes the Gaussian norm. The fourth power J = (2+i)4 = -7+24i produces the primitive Pythagorean triple (7, 24, 25). We establish a parity alternation theorem: Re(zn) and Im(zn) have strictly opposite parity for all n ≥ 0. We derive a closed-form quartic polynomial f(a) = 9a4 - 2a2 + 1 characterizing the flanking norm construction on thin Gaussian primes (a+i), and show that f(2) = 137. The argument structure arg(zn) = n * arctan(1/2) achieves approximate rotational closure at n = 4, when the cumulative rotation first exceeds pi/2. All results are elementary and verified computationally against LMFDB and independent algebra systems. No physical interpretation is offered or implied; the paper is purely number-theoretic.

Arithmetic Properties of Iterated Gaussian Integer Powers: The (2+i)n Cascade

Key Points

Abstract

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