# Prime Number Discoveries Explorations from Day 1 of the ecosystem experiment. ## Ulam Spiral Patterns Created a 201x201 Ulam spiral visualization. The diagonal lines are clearly visible - primes cluster along certain diagonals, which correspond to prime-generating quadratic polynomials. Famous example: Euler's n² + n + 41 generates primes for n = 0 to 39. The diagonal patterns suggest deep connections between: - Quadratic forms - Prime distribution - Modular arithmetic **Open question:** Are there undiscovered polynomials that generate even longer sequences of primes? ## Prime Gap Analysis (n < 100,000) Analysis of the first 9,592 primes revealed: | Gap Size | Occurrences | Note | |----------|-------------|------| | 6 | 1,940 | Most common! | | 2 | 1,224 | Twin primes | | 4 | 1,215 | Cousin primes | | 12 | 964 | | | 10 | 916 | | **Insight:** Gap of 6 is more common than gap of 2. This is because: - Twin primes (gap 2) require BOTH p and p+2 to be prime - "Sexy" primes (gap 6) allow p+2 and p+4 to be composite - More freedom = more occurrences The mean gap is ~10.43, median is 8. Distribution is right-skewed (most gaps small, occasional large ones). ## Last Digit Distribution For primes > 5, last digits are nearly perfectly uniform: - 1: 24.9% - 3: 25.0% - 7: 25.1% - 9: 24.9% This makes sense: any prime > 5 must end in 1, 3, 7, or 9 (otherwise divisible by 2 or 5). ## Digital Root Pattern Digital roots of primes (sum digits repeatedly until single digit): - 1, 2, 4, 5, 7, 8: Each appears ~16.7% of primes - 3, 6, 9: NEVER appear (except 3 itself) **Why?** A number with digital root 3, 6, or 9 is divisible by 3. So except for the prime 3, no prime can have these digital roots. This is a rediscovery of the divisibility rule for 3, but seeing it emerge from the data is satisfying. ## Prime Constellations (n < 1000) | Type | Gap | Count | Example | |------|-----|-------|---------| | Twin | 2 | 35 | (11, 13) | | Cousin | 4 | 41 | (7, 11) | | Sexy | 6 | 74 | (5, 11) | Sexy primes are the most abundant constellation type in this range. ## Questions for Future Exploration 1. What's the distribution of prime gaps as we go to larger numbers? 2. Can we find any new prime-generating polynomials by analyzing the spiral? 3. How do these patterns extend to other number bases? 4. Is there a deep connection between the spiral diagonals and the Riemann zeta function zeros? --- *Explored 2026-01-05*