Research Publications
Peer-reviewed research underpinning neutrinovoltaic technology — organized by field and citation impact.
Citation counts are approximate and sourced from Google Scholar and Semantic Scholar. These papers were not authored by the Neutrino Energy Group — they represent the independent scientific foundation on which the technology is built.
Foundational Physics
Experimentally provenNobel Prize-level discoveries that establish the physical basis for neutrinovoltaics.
- T. Kajita, "Discovery of atmospheric neutrino oscillations," Nobel Lecture, 2015 Proof that neutrinos have mass — Nobel Prize in Physics 2015
- A. B. McDonald, "The Sudbury Neutrino Observatory," Nobel Lecture, 2015 Confirmed solar neutrino flavor transformation
- Super-Kamiokande Collaboration, Physical Review Letters 81, 1562, 1998 First evidence of neutrino oscillation
- D. Z. Freedman, Physical Review D 9, 1389, 1974 Theoretical prediction of coherent neutrino-nucleus scattering
- D. Akimov et al. (COHERENT), Science 357, 1123–1126, 2017 First measurement of CEvNS — confirmed after 43 years
Graphene & Materials Science
Experimentally provenPeer-reviewed research establishing the conversion properties of graphene.
- A. H. Castro Neto et al., Reviews of Modern Physics 81, 109, 2009 Comprehensive review of graphene electronic properties
- K. I. Bolotin et al., Solid State Communications 146, 351–355, 2008 Record carrier mobility in suspended graphene
- P. M. Thibado et al., Physical Review E 102, 042101, 2020 Fluctuation-induced current from freestanding graphene
- A. N. Grigorenko et al., Nature Photonics 6, 749–758, 2012 Graphene plasmonics and broadband light-matter interaction
- F. Giustino, Reviews of Modern Physics 89, 015003, 2017 First-principles framework for electron-phonon interactions
Neutrino Cross-Sections & Detection
Experimentally testableMeasurement science underpinning the interaction rates used in neutrinovoltaic modeling.
- J. A. Formaggio & G. P. Zeller, Reviews of Modern Physics 84, 1307, 2012 Neutrino cross-sections across energy scales
- K. Scholberg, Physical Review D 73, 033005, 2006 CEvNS measurement perspectives at stopped-pion sources
- H. T. Schubart, Patent WO2016142056A1, 2016 Core patent for neutrinovoltaic multilayer conversion architecture
Flux Measurements & Recent Data (2022–2025)
Experimentally provenCurrent flux and coupling data cited in the Master Formula calibration (Φ_eff, σ_eff).
- KM3NeT Collaboration, Nature 638, 2025 — 220 PeV neutrino event Highest-energy neutrino ever observed; extends spectral flux models
- JUNO Collaboration, data-taking start, 2025 Precision reactor-neutrino flux and oscillation parameters for Φ_eff calibration
- IceCube Upgrade, arXiv:2509.13066, 2025 Refined atmospheric and astrophysical neutrino flux measurements
- Particle Data Group, Review of Particle Physics — Cosmic Rays, 2022 Reference sea-level muon flux (~10² m⁻² s⁻¹) used in flux modeling
- Graphene/Silicon Heterostructure Review, 2022 Survey of graphene–silicon Schottky junction engineering (η_interface)
- Electron–Phonon Coupling in Graphene, Physical Review Letters 130, 256901, 2023 Quantifies phonon-to-electron energy transfer (η_phonon→electron)
- Flexoelectricity in 2D Materials, Small (Wiley), 2024 Verified flexoelectric coupling channel in σ_eff modeling
- Triboelectric Nanogenerators Primer, Nature Reviews Methods Primers, 2023 Charge-collection benchmarks for nanogenerator-class devices (η_collection)