What does this research mean for the field?

The imaginary unit 'i' is not merely a mathematical convenience but a physical direction in a complex (3+1)C spacetime, from whose geometry the fundamental laws, gauge groups, and particle masses of the Standard Model and General Relativity can be derived. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.CHALLENGES_CONSENSUS.

What question did this study set out to answer?

Exploring the role of the imaginary unit i in fundamental physics and its geometric implications in (3+1)C spacetime.

June 10, 2026Open Access

Let Us Assume i Is Real - What a Complex Spacetime (3+1)C Can Explain

Key Points

Exploring the role of the imaginary unit i in fundamental physics and its geometric implications in (3+1)C spacetime.
Developed a theoretical framework using complex spatial coordinates and time.
Derived key physical laws and relationships from the Kähler structure of (3+1)C.
Generated predictions related to black-hole mergers and neutrino behavior.
Achieved agreement with 43 experimental observables to ≤ 3%.
Predicted a mass-ratio-independent remnant spin for black-hole mergers.
Identified a neutrino luminosity gap in core-collapse supernovae, consistent with historical data to 3%.

Abstract

The imaginary unit i pervades fundamental physics. It opens the Schrödinger equation (iℏ ∂tψ = Hψ), defines the uncertainty relation (ˆx, ˆp = iℏ), structures the Dirac equation (iγμ∂μψ = mψ), generates gauge symmetries (U (1), SU (2), SU (3) are complex groups), connects quantum mechanics to thermodynamics (Wick rotation t → iτ , Matsubara formalism), and changes the signature of spacetime at the Schwarzschild horizon (dt2 → −dt2 = (i dt)2). In every case it is treated as a mathematical convenience — a computational trick without geometric content. This paper takes the opposite view: i is a direction in spacetime. Specifically, i is the rotation from the visible, expanded coordinates xk to their compact, conjugate counterparts wk on an internal S3. The resulting spacetime is (3+1)C: three complex spatial coordinates zk = xk + i wk (expanded real parts, compact imaginary parts on S3) and one complex time τ = t + iσ (macroscopic real part, compact Euclidean Hawking circle). The construc-tion mechanism is the Schwarzschild sign change, treated not as a coordinate artefact but as a physical transition.From the Kähler structure of this spacetime and a single geometric parameter — the Berger deformation ε = 1.01027, fixed by the electron mass — the paper derives: the Heisenberg uncertainty relation (from ω = dx ∧ dw), special relativity (as holomorphic symmetry), E2 = p2c2 +m2 0c4 (as the wave equation on pseudo-Kähler C4), E = mc2 and the equivalence principle (as holomorphicity deficit), Einstein’s field equations (from Lovelock uniqueness), the Dirac equation (from Kähler–Dirac correspondence on C4), the gauge group SU(3) × SU(2) × U(1), three fermion generations (topological; fourth excluded), all fermion and boson masses, the CKM matrix, the proton mass, the fine-structure constant, and a complete dark-matter sector. In total, ∼ 43 quantitative observables agree with experiment to ≤ 3 %; three independent determinations of ε (from me, mH , and MP ) agree to 130 ppm. Falsifiable predictions include a mass-ratio-independent remnant spin for black-hole mergers (LIGO O4/O5), r = 0 exactly (CMB-S4), and a neutrino luminosity gap in core-collapse supernovae (retro-consistent with SN 1987A to 3 %).Every i in quantum mechanics, in gauge theory, in the Wick rotation, and at the Schwarzschild horizon has the same geometric origin: the Kähler structure of (3+1)C. The Standard Model is the R3,1-projection of this geometry.

Let Us Assume i Is Real - What a Complex Spacetime (3+1)C Can Explain

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