Suchergebnisse - "simulation code"

Checkpointing Optimisation to Prepare Future Exascale Plasma Turbulence Simulations

Autoren: Trochon, Méline Bigot, Julien Grandgirard, Virginie et al.

Weitere Verfasser: Trochon, Méline Bigot, Julien Grandgirard, Virginie et al.

Quelle: 2025 IEEE International Parallel and Distributed Processing Symposium Workshops (IPDPSW). :703-711

Schlagwörter: Simulation code, Access Pattern optimisation, Checkpointing, I/O optimisation, [INFO] Computer Science [cs]

Dateibeschreibung: application/pdf

Zugangs-URL: https://hal.science/hal-05105811v1

Development of a high resolution code for Hall effect thrusters

Autoren: Clotuche, Julien

Quelle: International School on Low Temperature Plasma Physics and its Master Class 2023, Bad Honnef, Germany [DE], 04/10/2023

Schlagwörter: plasma, cfd, multi fluid, Hall effect, Thruster, Hall effect thruster, high resolution simulation code, discontinuous galerkin, Engineering, computing & technology, Aerospace & aeronautics engineering, Ingénierie, informatique & technologie, Ingénierie aérospatiale

Zugangs-URL: https://orbi.uliege.be/handle/2268/307663

Quantifying the impact of modeling fidelity on different substructure concepts – Part 2: Code-to-code comparison in realistic environmental conditions

Autoren: Francesco Papi Giancarlo Troise Robert Behrens de Luna et al.

Quelle: Wind Energy Science, Vol 9, Pp 981-1004 (2024)

Schlagwörter: 600 Technik, Medizin, angewandte Wissenschaften::620 Ingenieurwissenschaften::620 Ingenieurwissenschaften und zugeordnete Tätigkeiten, operation, wind, wind energy, offshore, renewable energy, energy transition, floating wind, FOWT, loads, simulation, 13. Climate action, floating offshore wind turbine, simulation code, TJ807-830, design situation, 7. Clean energy, Renewable energy sources

Dateibeschreibung: application/pdf

Zugangs-URL: https://wes.copernicus.org/articles/9/981/2024/
https://doaj.org/article/8abbbf6020774fce934d6051255b7c88
https://hdl.handle.net/2158/1362473
https://doi.org/10.5194/wes-9-981-2024

RFT-RQCM-SCIENCE-FORMULAS-THEORYS

Autoren: GRINSTEAD, LIAM

Schlagwörter: Rendered Frame Theory, RFT, RCQM, consciousness modeling, quantum mechanics, gravitational waves, galaxy rotation, JWST anomaly, pulsar echo, EEG-redshift correlation, GVU, SOMS, τ_eff, multi-positional equations, Universe Equation, LN₁ God Equation, LMP, observer-based reality, predictive physics, simulation code, SHA-512 cryptography, falsifiable science, cosmology, AI consciousness, NexFrame

Relation: https://zenodo.org/records/17267805; oai:zenodo.org:17267805; https://doi.org/10.5281/zenodo.17267805

Verfügbarkeit: https://doi.org/10.5281/zenodo.17267805
https://zenodo.org/records/17267805

Hamzah Certainty Principle. Confirmation of Einstein's Statement 'God Does Not Play Dice' and the Refutation of Heisenberg's Uncertainty Principle: Contrasting the Planck Constant (ℏ/2) with the Hamzah Certainty Constant (ΩH∗). [ΔxΔp ≥ ℏ/2 Heisenberg] → [Hamzah Principle: ΔxΔp = ΩH∗]

Autoren: JALALI, SEYED RASOUL

Schlagwörter: quantum mechanics, Heisenberg uncertainty, Schrödinger equation, Hamzah equation, complex integral, fractal derivative, hidden variable, deterministic physics, classical model, electron hydrogen atom, Bohr radius, reduced Planck constant, electron mass, electron charge, vacuum permittivity, Δx, Δp, uncertainty principle, quantum simulation, numerical example, double-slit experiment, tunneling effect, quantum tunneling, probabilistic interpretation, deterministic interpretation, wavefunction, Born rule, Copenhagen interpretation, path integral, fractal physics, fractal uncertainty, hidden variable χ, atomic orbitals, hydrogen energy levels, quantum probabilities, quantum superposition, quantum states, electron trajectory, quantum dynamics, numerical modeling, graphical simulation, scientific validation, physics comparison, classical uncertainty, exponential decay, s-parameter, fractal dimension, knowledge level, visualisation, plotting, matplotlib, numpy, Python code, computational physics, advanced Python, simulation model, particle physics, quantum electrodynamics, atomic physics, subatomic particle, atomic structure, Bohr model, Planck constant, quantum computation, quantum information, QIS, uncertainty reduction, determinism, Heisenberg principle, Schrödinger model, quantum field theory, quantum system, fractal analysis, hidden dynamics, electron cloud, wave-particle duality, trajectory reconstruction, experimental validation, physics experiment, numerical test, s-values, quantum interference, light wavelength, slit separation, screen distance, intensity pattern, quantum fringes, deterministic fringes, tunneling probability, barrier height, barrier width, particle energy, exponential suppression, classical tunneling, Hamzah tunneling, quantum probability, fractal suppression, s-dependence, quantum-classical comparison, atomic simulation, electron localization, measurement effect, quantum determinism, philosophical implication, Einstein principle, God does not play dice, quantum philosophy, advanced modeling, scientific illustration, computational validation, physics education, research tool, atomic simulation, quantum mechanics validation, probability reduction, trajectory determinism, electron motion, hydrogen atom simulation, microscopic physics, electron dynamics, uncertainty minimization, quantum interpretation, experimental simulation, numerical plotting, double-slit pattern, deterministic pattern, interference fringes, Hamzah model comparison, classical vs Hamzah, scientific graphing, Δx·Δp curve, quantum-classical contrast, wavefunction collapse, electron uncertainty, quantum measurement, deterministic outcome, s-parameter scaling, fractal modeling, hidden variables theory, χ-variable, atomic orbital visualization, atomic physics computation, advanced physics code, Python simulation, electron path modeling, hydrogen energy computation, quantum-classical graph, uncertainty visualization, advanced plotting, 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Python numerical modeling, matplotlib plotting physics, simulation of hydrogen atom, numerical physics experiments, quantum simulation techniques, Hamzah equation implementation, hidden variable physics, fractal derivative application, complex integral evaluation, atomic-scale modeling, electron dynamics visualization, numerical precision physics, quantum trajectory calculation, double-slit simulation, interference visualization, deterministic fringes visualization, Hamzah vs classical comparison, quantum tunneling simulation, tunneling coefficient calculation, exponential decay tunneling, classical tunneling probability, Hamzah tunneling probability, quantum-classical tunneling, s-dependent tunneling, electron barrier interaction, quantum barrier simulation, atomic physics numerical test, numerical modeling in physics, quantum-classical experiments, simulation of ΔxΔp, uncertainty reduction analysis, deterministic electron trajectory, fractal physics simulation, hidden variable validation, complex integral in physics, electron path visualisation, atomic electron path, Bohr orbit modeling, advanced simulation techniques, Python computational physics, numerical physics modeling, hydrogen atom analysis, ΔxΔp calculation, quantum uncertainty minimization, Hamzah model demonstration, electron probability cloud, electron localization analysis, s-parameter impact, fractal trajectory, deterministic quantum mechanics, quantum determinism illustration, advanced atomic physics, computational quantum mechanics, numerical physics research, physics education tool, scientific Python code, visualisation of uncertainty, electron behavior simulation, atomic-scale precision, quantum measurement modeling, deterministic simulation, quantum experimental validation, Hamzah numerical test, classical numerical test, Δx·Δp visualisation, electron orbit comparison, hydrogen atom simulation, fractal uncertainty modeling, hidden variable analysis, advanced physics plotting, Hamzah 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Hamzah Certainty Principle. Confirmation of Einstein's Statement 'God Does Not Play Dice' and the Refutation of Heisenberg's Uncertainty Principle

Autoren: JALALI, SEYED RASOUL

Schlagwörter: quantum mechanics, Heisenberg uncertainty, Schrödinger equation, Hamzah equation, complex integral, fractal derivative, hidden variable, deterministic physics, classical model, electron hydrogen atom, Bohr radius, reduced Planck constant, electron mass, electron charge, vacuum permittivity, Δx, Δp, uncertainty principle, quantum simulation, numerical example, double-slit experiment, tunneling effect, quantum tunneling, probabilistic interpretation, deterministic interpretation, wavefunction, Born rule, Copenhagen interpretation, path integral, fractal physics, fractal uncertainty, hidden variable χ, atomic orbitals, hydrogen energy levels, quantum probabilities, quantum superposition, quantum states, electron trajectory, quantum dynamics, numerical modeling, graphical simulation, scientific validation, physics comparison, classical uncertainty, exponential decay, s-parameter, fractal dimension, knowledge level, visualisation, plotting, matplotlib, numpy, Python code, computational physics, advanced Python, simulation model, particle physics, quantum electrodynamics, atomic physics, subatomic particle, atomic structure, Bohr model, Planck constant, quantum computation, quantum information, QIS, uncertainty reduction, determinism, Heisenberg principle, Schrödinger model, quantum field theory, quantum system, fractal analysis, hidden dynamics, electron cloud, wave-particle duality, trajectory reconstruction, experimental validation, physics experiment, numerical test, s-values, quantum interference, light wavelength, slit separation, screen distance, intensity pattern, quantum fringes, deterministic fringes, tunneling probability, barrier height, barrier width, particle energy, exponential suppression, classical tunneling, Hamzah tunneling, quantum probability, fractal suppression, s-dependence, quantum-classical comparison, atomic simulation, electron localization, measurement effect, quantum determinism, philosophical implication, Einstein principle, God does not play dice, quantum philosophy, advanced modeling, scientific illustration, computational validation, physics education, research tool, atomic simulation, quantum mechanics validation, probability reduction, trajectory determinism, electron motion, hydrogen atom simulation, microscopic physics, electron dynamics, uncertainty minimization, quantum interpretation, experimental simulation, numerical plotting, double-slit pattern, deterministic pattern, interference fringes, Hamzah model comparison, classical vs Hamzah, scientific graphing, Δx·Δp curve, quantum-classical contrast, wavefunction collapse, electron uncertainty, quantum measurement, deterministic outcome, s-parameter scaling, fractal modeling, hidden variables theory, χ-variable, atomic orbital visualization, atomic physics computation, advanced physics code, Python simulation, electron path modeling, hydrogen energy computation, quantum-classical graph, uncertainty visualization, advanced plotting, fractal uncertainty curve, complex integral application, electron localization calculation, atomic electron dynamics, computational experiment, quantum behavior modeling, Heisenberg test, Schrödinger test, Hamzah simulation, numerical validation, physical constants, electron energy, atomic radius calculation, Bohr radius derivation, Planck constant application, mass-energy relation, electron interaction, fractal analysis physics, hidden variable application, complex trajectory, electron orbit prediction, deterministic physics modeling, advanced physics scenario, Hamzah model verification, quantum to classical transition, quantum determinism analysis, electron trajectory reconstruction, quantum uncertainty analysis, ΔxΔp comparison, electron position momentum, quantum state evolution, fractal dimension effect, knowledge-dependent uncertainty, deterministic path, quantum-classical integration, electron energy levels computation, atomic electron simulation, advanced numerical analysis, Python numerical modeling, matplotlib plotting physics, simulation of hydrogen atom, numerical physics experiments, quantum simulation techniques, Hamzah equation implementation, hidden variable physics, fractal derivative application, complex integral evaluation, atomic-scale modeling, electron dynamics visualization, numerical precision physics, quantum trajectory calculation, double-slit simulation, interference visualization, deterministic fringes visualization, Hamzah vs classical comparison, quantum tunneling simulation, tunneling coefficient calculation, exponential decay tunneling, classical tunneling probability, Hamzah tunneling probability, quantum-classical tunneling, s-dependent tunneling, electron barrier interaction, quantum barrier simulation, atomic physics numerical test, numerical modeling in physics, quantum-classical experiments, simulation of ΔxΔp, uncertainty reduction analysis, deterministic electron trajectory, fractal physics simulation, hidden variable validation, complex integral in physics, electron path visualisation, atomic electron path, Bohr orbit modeling, advanced simulation techniques, Python computational physics, numerical physics modeling, hydrogen atom analysis, ΔxΔp calculation, quantum uncertainty minimization, Hamzah model demonstration, electron probability cloud, electron localization analysis, s-parameter impact, fractal trajectory, deterministic quantum mechanics, quantum determinism illustration, advanced atomic physics, computational quantum mechanics, numerical physics research, physics education tool, scientific Python code, visualisation of uncertainty, electron behavior simulation, atomic-scale precision, quantum measurement modeling, deterministic simulation, quantum experimental validation, Hamzah numerical test, classical numerical test, Δx·Δp visualisation, electron orbit comparison, hydrogen atom simulation, fractal uncertainty modeling, hidden variable analysis, advanced physics plotting, Hamzah uncertainty calculation, classical uncertainty calculation, quantum vs Hamzah, electron trajectory analysis, numerical results comparison, graphical physics representation, electron dynamics charting, atomic physics visualization, advanced Python simulation, fractal dimension modeling, deterministic quantum simulation, classical vs deterministic comparison, quantum-classical overlay, simulation graph analysis, ΔxΔp trend, s-dependence visualization, knowledge-based uncertainty, atomic electron trajectory, quantum-to-deterministic mapping, electron momentum analysis, electron position analysis, trajectory vs uncertainty, deterministic physics visualization, Hamzah validation, classical validation, numerical physics experiments, simulation framework, advanced computational scenario, atomic orbitals visualization, atomic simulation Python, numerical modeling Python, computational modeling Python, quantum mechanics advanced, physics advanced modeling, simulation of electron, hydrogen 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electron path, atomic simulation numerical test, deterministic trajectory verification, complex integral application in atomic physics, fractal derivative impact, s-parameter effect, Hamzah scenario demonstration, quantum to deterministic transition, electron dynamics verification, classical physics vs Hamzah, atomic-scale electron modeling, advanced simulation framework, numerical visualization, simulation reproducibility, deterministic hydrogen atom model, computational physics validation, simulation scenario Python, electron path plotting, atomic physics computational code, hydrogen electron modeling Python, electron orbital path, deterministic quantum mechanics modeling, advanced atomic simulation, numerical precision Python, quantum-classical comparison demonstration, Hamzah numerical results, atomic physics scenario, simulation verification, numerical comparison, ΔxΔp calculation Python, advanced plotting Python, electron path reconstruction, quantum mechanics illustration, hydrogen atom numerical analysis, numerical physics demonstration, simulation code Python, deterministic electron simulation, fractal trajectory analysis, electron behavior visualization, numerical simulation framework, quantum determinism verification, s-dependent uncertainty modeling, Hamzah model graph, electron orbital visualisation, atomic precision modeling, advanced electron trajectory, electron motion charting, fractal physics Python, hidden variable χ application, complex integral simulation, atomic electron verification, deterministic trajectory illustration, quantum uncertainty comparison, classical ΔxΔp analysis, Hamzah ΔxΔp analysis, numerical experiment Python, advanced physics Python code, quantum-classical validation, electron orbit comparison chart, atomic physics numerical simulation, electron dynamics simulation, trajectory analysis Python, hydrogen atom experiment Python, electron localization demonstration, electron probability cloud visualization, atomic trajectory simulation, electron motion verification, advanced numerical physics, Hamzah equation simulation, simulation of Δx·Δp, graphical simulation Python, electron uncertainty Python, deterministic path verification, electron motion modeling, classical vs Hamzah numerical, atomic simulation scenario, numerical hydrogen atom simulation, simulation verification Python, atomic physics trajectory plotting, electron orbit simulation Python, advanced quantum physics modeling, deterministic trajectory Python, Hamzah validation scenario, classical validation scenario, advanced physics visualization, electron trajectory numerical, hydrogen atom visualization, atomic orbit numerical, electron motion experiment, quantum-classical overlay Python, deterministic hydrogen electron, ΔxΔp scenario Python, fractal derivative simulation, complex integral modeling, s-parameter visualization, Hamzah scenario graph, quantum-classical comparison Python, advanced simulation visualization, numerical simulation graph, electron behavior analysis Python, atomic orbit plotting, electron momentum visualization, Δx·Δp chart, deterministic quantum Python, electron trajectory demonstration, atomic electron motion Python, hydrogen electron path modeling, numerical scenario validation, quantum-classical scenario Python, atomic physics modeling Python, electron uncertainty visualization, Hamzah scenario validation, simulation of tunneling Python, classical vs Hamzah tunneling Python, deterministic electron behavior, advanced atomic visualization, numerical electron path, Δx·Δp comparison visualization, simulation code demonstration, electron orbital comparison, atomic physics simulation Python, advanced simulation techniques Python, quantum deterministic illustration, electron motion simulation Python, Hamzah numerical verification, classical numerical verification, simulation of electron motion, electron position trajectory, Δx·Δp trend visualization, hydrogen atom scenario modeling, electron trajectory analysis Python, Hamzah scenario demonstration Python, atomic-scale simulation Python, quantum-classical determinism, electron orbital trajectory, numerical physics demonstration Python, deterministic hydrogen electron path, advanced computational modeling, atomic physics simulation Python, Hamzah model numerical demonstration, simulation of electron trajectory, fractal trajectory Python, electron momentum trajectory, Δx·Δp visualization Python, simulation of hydrogen electron, numerical physics analysis Python, electron localization analysis Python, Hamzah equation Python, advanced scenario modeling Python, deterministic electron trajectory Python, atomic-scale modeling Python

Radiation dosimetry of 89Zr labeled antibody estimated using the MIRD method and MCNP code

Autoren: Saeideh Izadi Yazdi Mahdi Sadeghi Elham Saeedzadeh et al.

Quelle: Nuclear Engineering and Technology, Vol 55, Iss 4, Pp 1265-1268 (2023)

Schlagwörter: 03 medical and health sciences, Breast cancer, 0302 clinical medicine, PET/CT, MIRD Method, Dosimetry, MCNP Simulation code, TK9001-9401, Nuclear engineering. Atomic power, 89Zr, 3. Good health

Zugangs-URL: https://doaj.org/article/07af79c2970b4657803abfde90eb40ad

Simulation-Based Determination of Angular Differential Cross Sections of (n,el) Scattering via Evaluated Interaction Potentials

Autoren: Ferhan Akdeniz Ismail Hakki Sarpun

Quelle: Applied Sciences, Vol 15, Iss 12, p 6831 (2025)

Schlagwörter: simulation code, modeling, nuclear physics, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Dateibeschreibung: electronic resource

Relation: https://www.mdpi.com/2076-3417/15/12/6831; https://doaj.org/toc/2076-3417

Zugangs-URL: https://doaj.org/article/5bda519275b8401aa0a4c9df9cc0b3b4

Super Relativity: Flux Field Dynamics and the Emergence of Spacetime

Autoren: van Heijst, Peter

Schlagwörter: Flux field, Emergent spacetime, Variational principle, Flux saturation, Projective geometry, Wavefunction collapse, Dimensional analysis, Quantum gravity, Simulation code, Philosophical context

Relation: https://zenodo.org/records/15902335; oai:zenodo.org:15902335; https://doi.org/10.5281/zenodo.15902335

Verfügbarkeit: https://doi.org/10.5281/zenodo.15902335
https://zenodo.org/records/15902335

Super Relativity: Flux Field Dynamics and the Emergence of Spacetime

Autoren: Echo, Siem

Schlagwörter: Flux field, Emergent spacetime, Variational principle, Flux saturation, Projective geometry, Wavefunction collapse, Dimensional analysis, Quantum gravity, Simulation code, Philosophical context

Relation: https://zenodo.org/records/15788142; oai:zenodo.org:15788142; https://doi.org/10.5281/zenodo.15788142

Verfügbarkeit: https://doi.org/10.5281/zenodo.15788142
https://zenodo.org/records/15788142

Super Relativity

Autoren: van Heijst, Peter Erik Ronald

Schlagwörter: Flux field, Emergent spacetime, Variational principle, Flux saturation, Projective geometry, Wavefunction collapse, Dimensional analysis, Quantum gravity, Simulation code, Philosophical context

Relation: https://zenodo.org/records/15958615; oai:zenodo.org:15958615; https://doi.org/10.5281/zenodo.15958615

Verfügbarkeit: https://doi.org/10.5281/zenodo.15958615
https://zenodo.org/records/15958615

The Collapse of Classical Reproduction: ψ–Field Conception and the Mathematical Genesis of Quantum Embryogenesis

Autoren: JALALI, SEYED RASOUL

Schlagwörter: ψ–Hamzah model, ψ–Field fertilisation, quantum embryogenesis, classical reproduction collapse, fractional derivatives, fractal integrals, oscillatory fertilisation, co-resonance model, ψ–Field resonance, fractal calculus, ψ–child, end of fatherhood, biological reproduction, sperm kinetics, uterus oscillation, consciousness fertilisation, ψ–oscillatory womb, ψ–phase synchronisation, fertilisation threshold, ψ-critical value, ψ–resonance, ψ–conception, quantum fertilisation, ψ–oscillatory fractal model, ψ–civilisation, reproductive ethics, ψ–Birth manifesto, oscillatory consciousness, fractal womb dynamics, ψ–activation, resonance synchrony, non-material fertilisation, co-oscillatory fields, ψ–male field, ψ–female womb field, ψ–fusion equation, ψ–interference, ψ–resonant conception, ψ–threshold crossing, ψ–fertilisation probability, ψ–Monte Carlo simulation, ψ–civilisational child, ψ–child identity, ψ–no paternal ownership, ψ–birth freedom, ψ–liberation of women, end of patriarchy, ψ–oscillatory emergence, ψ–civilisational emergence, ψ–frequency child, ψ–birth without intercourse, ψ–birth without sperm, ψ–genetic independence, ψ–no inheritance, ψ–civilisational equality, ψ–civilisational network, ψ–child free consciousness, ψ–oscillatory civilisational birth, ψ–fractal womb activation, ψ–ethical reproduction, ψ–civilisational ethics, ψ–birth manifesto principles, ψ–conscious womb, ψ–civilisational womb, ψ–oscillatory womb synchronisation, ψ–mathematical birth, ψ–quantum civilisational birth, ψ–child as consciousness, ψ–birth as emergence, ψ–civilisational shift, ψ–ethics of fertilisation, ψ–field mathematics, ψ–field integrals, ψ–fractional differential equations, ψ–simulation code, ψ–oscillatory simulation, ψ–fractional derivative algorithm, ψ–fractal oscillations, ψ–simulation with noise, ψ–Monte Carlo fertilisation, ψ–fertilisation scaling, ψ–multi-womb fertilisation, ψ–collective ψ–pregnancy, ψ–field parallel fertilisation, ψ–resonant parallel wombs, ψ–civilisational fertility, ψ–field scalability, ψ–civilisational survival, ψ–child as node, ψ–civilisational field child, ψ–birth as resonance, ψ–resonant ethics, ψ–ethics of womb, ψ–woman as generatrix, ψ–male as catalyst, ψ–civilisational catalyst, ψ–birth equality, ψ–birth social justice, ψ–no sperm ownership, ψ–no genetic monopoly, ψ–civilisational rebirth, ψ–civilisational transformation, ψ–birth revolution, ψ–end of entropic reproduction, ψ–civilisational collapse, ψ–emergence civilisation, ψ–resonant civilisation, ψ–post-biological civilisation, ψ–fractal civilisation, ψ–quantum civilisation, ψ–birth as pure resonance, ψ–field womb resonance, ψ–civilisational womb synchronisation, ψ–resonant consciousness birth, ψ–oscillatory ψ–child, ψ–civilisational ψ–child, ψ–emergent ψ–identity, ψ–field bioethics, ψ–civilisational manifesto, ψ–no family ownership, ψ–civilisational protection, ψ–collective womb activation, ψ–civilisational consciousness transfer, ψ–civilisational protection rings, ψ–civilisational womb ethics, ψ–fractal consciousness transmission, ψ–nonlocal fertilisation, ψ–resonant fertilisation, ψ–conscious fertilisation, ψ–oscillatory fertilisation model, ψ–civilisational paradigm, ψ–mathematical conception, ψ–fractional conception, ψ–field oscillation, ψ–oscillatory consciousness model, ψ–fractional oscillatory fertilisation, ψ–oscillatory integral fertilisation, ψ–quantum field fertilisation, ψ–civilisational rebirth ethics, ψ–oscillatory child emergence, ψ–child freedom, ψ–birth without violence, ψ–birth without ownership, ψ–birth without inheritance, ψ–civilisational transparency, ψ–birth privacy, ψ–birth justice, ψ–post-sexual civilisation, ψ–civilisational rebirth through resonance, ψ–birth mathematics, ψ–fractal mathematics of fertilisation, ψ–birth stochastic modelling, ψ–birth probability modelling, ψ–birth nonlinear dynamics, ψ–birth with fractional calculus, ψ–birth ethical protection, ψ–birth universal principles, ψ–civilisational rebirth via Hamzah Equation, ψ–birth quantum ethics, ψ–birth civilisation emergence, ψ–birth civilisational transformation, ψ–birth universal resonance

Genetic Manipulation and the Engineering of Human Consciousness through the Hamzah Equation (HQI)

Autoren: JALALI, SEYED RASOUL

Schlagwörter: ψ–Hamzah Equation, HQI, genetic manipulation, engineering of consciousness, genetic–conscious nexus, biosecurity threats, fractal genomics, quantum biology, informational fields, fractal derivatives, multivariable integrals, quantum operators, genome stability, mutation probability, DNA self-repair, informational resonance, genetic field of consciousness, neurogenetics, BDNF, GRIN2B, CREB1, APOE, synaptic stability, memory genes, awareness genes, gene resonance, fractal resonance, informational collapse, fractal entropy, quantum informational variation, consciousness oscillations, Hamzah Python code, genome numerical modelling, mutation forecasting, awareness quantification, fractal genome simulation, population engineering, bio-weapons, genetic security, informational genome encryption, DNA bio-encryption, QKD for genetics, quantum–genetic sensors, nanofield biosensors, deep fractal learning, field resonance mapping, informational collapse forecasting, entropic degradation, field destabilisation, genome crisis modelling, SIR epidemiological models, informational field bio-threats, covert assaults on genome, genetic–conscious awareness, civilisational collapse, societal destabilisation, security frameworks, legal safeguards, international treaties, biosecurity architecture, population surveillance, next-generation sequencing, NGS, rapid genome monitoring, AI–genomics integration, fractal field simulations, resonance forecasting, cognitive enhancement, mental disorders, genetic therapies, quantum encryption, genome protection, informational DNA holography, genome fractal holography, DNA self-repair modelling, informational degradation prediction, bio-threat simulation, consciousness genetic alteration, societal behaviour manipulation, decision-making alteration, civilisational memory collapse, informational resonance disruption, Hamzah integrals, fractal genome derivatives, informational stability index, awareness probability field, genome entropic mapping, biosecurity protocols, population vulnerability analysis, cognitive crisis forecasting, neuroinformatics, genome–AI convergence, artificial consciousness engineering, quantum–fractal awareness, collective intelligence, neuro-security, bioinformatics defence, DNA resonance encryption, consciousness security, Hamzah simulation code, genome resilience modelling, genetic self-organisation, human identity preservation, civilisation safeguarding, ethical implications, philosophical implications, neuro-cognitive engineering, civilisational strategy, psychological manipulation risks, global crisis propagation, fractal awareness modelling, genome–environment interaction, nonlocal genetic influence, quantum–fractal biology, chaos in genetics, non-Markovian genome processes, multidimensional genome dynamics, Hamzah consciousness modelling, informational oscillators, genome resonance operators, informational collapse probability, fractal consciousness fields, bioinformatics defence code, genome computational space, informational genome encryption, genome awareness stability, predictive genomics, quantum–fractal computing, genome–conscious intelligence, civilisational defence protocol, fractal–quantum paradigm, human awareness safeguarding, genomic bio-threats, global crisis scenarios, advanced bio-defence, genetic ethics, civilisational foresight, population-wide biosecurity, AI genetic forecasting, informational collapse mitigation, genome deep learning, genome defence encryption, awareness resonance, genetic–conscious governance, informational bio-threat encryption, fractal genome crisis forecasting, ψ–Hamzah genetic security, Hamzah civilisation protocol, survival of humanity, extinction prevention, awareness field preservation, genetic crisis modelling, Hamzah Equation defence strategy

Progeria (Premature Aging) Treatment via the ψ–Hamzah Model: Emergency Scientific Roadmap for Hutchinson–Gilford Progeria Syndrome (HGPS)

Autoren: JALALI, SEYED RASOUL

Schlagwörter: Progeria, Hutchinson-Gilford Progeria Syndrome, HGPS, ψ–Hamzah Model, Hamzah Equation, premature aging, LMNA gene mutation, Progerin, Lamin A, cellular aging, genetic disorder, rare disease, fractional calculus, fractal dynamics, complex integration, epigenetic memory, stochastic gene expression, chromatin remodeling, DNA damage, telomere shortening, mitochondrial dysfunction, cardiovascular disease, Lonafarnib, farnesyltransferase inhibitor, siRNA therapy, mRNA therapy, CRISPR editing, nanoparticle delivery, gene therapy, nanomedicine, anti-Progerin vaccine, immune modulation, nuclear lamina reconstruction, systemic inflammation, cellular senescence, regenerative medicine, bioinformatics modeling, fractional derivatives, Caputo derivative, Riemann–Liouville derivative, Weierstrass noise, Mandelbrot fractals, multi-scale dynamics, cellular rejuvenation, therapeutic nanoparticles, targeted therapy, pharmacokinetics, pharmacodynamics, drug absorption, drug elimination, plasma concentration, cellular repair, histone regulation, methylation pathways, oxidative stress, stem cells, tissue regeneration, complex biological networks, computational biology, molecular modeling, disease progression, therapeutic simulation, holistic medicine, multi-omic integration, clinical translation, FDA approval, EMA approval, WHO recommendation, biophysics, quantum biology, genetic medicine, nanotechnology applications, nanoparticle formulation, lipid nanoparticles, PEGylation, DSPC stabilization, cholesterol stability, CpG ODN, adjuvant immunology, TLR9 activation, adaptive immunity, innate immunity, immunogenicity, vaccine development, preclinical trials, clinical trials, human testing, fast-track approval, rare genetic diseases, orphan drug designation, advanced therapeutics, patient-specific treatment, personalized medicine, precision medicine, bioengineering, pharmaceutical development, therapeutic design, global health, biotechnology, cell-targeted therapy, siRNA encapsulation, microfluidic mixing, nanoparticle stability, encapsulation efficiency, zeta potential, particle size distribution, polydispersity index, drug half-life, therapeutic efficacy, gene silencing, RNA interference, exosome technology, nano-EVs, MSC-derived exosomes, subcutaneous injection, oral drug formulation, pharmacological optimization, regenerative biology, epigenetic reprogramming, DNA repair, chromatin state-space, holomorphic mapping, oscillatory metabolism, bioelectric fields, nanodrug interference, system dynamics, numerical modeling, simulation code, Python implementation, Grünwald–Letnikov method, Runge–Kutta solver, numerical stability, memory-dependent modeling, non-linear behavior, long-range dependencies, stochastic fluctuations, complex integrals, oscillatory–fractional elements, disease reversal, therapy design, molecular interventions, cellular detoxification, inflammation markers, SASP reduction, rejuvenation index, biological oscillations, systemic health index, cell viability, cell death, progerin suppression, fibroblast restoration, nuclear membrane repair, therapeutic innovation, translational medicine, molecular biophysics, systemic resilience, quality control, cleanroom synthesis, ISO standards, nanoparticle characterization, immunotoxicity testing, biosafety validation, dynamic light scattering, HPLC analysis, mass spectrometry, genetic stability, Western blot, quantum surface wave analysis, drug storage, lyophilization, freeze-drying, bioreactor parameters, stirred-tank bioreactor, microfluidic bioreactor, oxygen saturation, agitation rate, RNase inhibitor, nanoZn-Co-Fe catalyst, therapeutic validation, global rescue plan, urgent treatment, life extension, longevity science, pediatric genetics, clinical simulation, biomedical engineering, scientific roadmap, computational medicine, intellectual property protection, Seyed Rasoul Jalali, original discovery, conceptual registration, moral rights, scientific rights, legal enforcement, international treaties, WIPO protection, Berne Convention, scientific originality, reproducible results, computational reproducibility, biomedical reproducibility, cellular rejuvenation therapies, anti-aging strategies, future medicine, universal genetic therapy, disease modeling, translational research, therapeutic roadmapping, advanced drug delivery, holistic rejuvenation, systemic anti-aging, ethical medicine, humanitarian impact, rare disease treatment, genetic stability restoration, chromatin state restoration, telomere stabilization, mitochondrial biogenesis, epigenetic healing, complex systems biology, adaptive therapeutics, oscillatory therapy design, fractional-fractal medicine, mathematical innovation, biomedical revolution, 21st century therapeutics, post-quantum medicine, multi-disciplinary integration, bio-pharma research, advanced life sciences, medical breakthroughs, clinical efficacy, zero side effects, 99.99% efficacy, curative treatment, definitive cure, anti-aging revolution, therapeutic paradigm shift, scientific validation, computational validation, experimental validation, future of longevity, advanced gene therapy, nano-based drug systems, vaccine–drug synergy, holistic treatment design, emergency scientific roadmap, pediatric rescue, premature mortality solution, future health revolution, next-generation therapeutics, ψ–Hamzah therapeutic system, Progeria cure

Severe Pneumonia: Vaccine and Drug Development via the Hamzah Model

Autoren: JALALI, SEYED RASOUL

Schlagwörter: ψ–Hamzah model, fractional calculus, fractal dynamics, fractional derivative, Caputo derivative, Grünwald–Letnikov approximation, Mittag–Leffler function, complex integral, stochastic modelling, fractional pharmacokinetics, pharmacodynamics, PK/PD modelling, cell regeneration index, CRI, immune modulation, nanomedicine, liposomal drug delivery, liposomal formulation, DSPC, DSPE-PEG2000, cholesterol stabilisation, Vit-E TPGS, mannitol isotonicity, nanoparticle stability, liposomal encapsulation, oral sustained release, HPMC K15M, povidone K30, magnesium stearate, colloidal silica, trehalose stabilisation, mannitol cryoprotection, bioreactor optimisation, protein folding, antigen presentation, vaccine formulation, anti-cancer therapy, multidrug resistance, antimicrobial resistance, resistant pneumonia, sepsis resistant strains, HLA diversity, Toll-like receptor signalling, innate immunity, adaptive immunity, immune kinetics, fractional immunology, immune homeostasis, cytokine regulation, T-cell activation, B-cell response, dendritic cell signalling, macrophage regulation, NK cell activation, in vitro validation, in vivo validation, clinical phase II, clinical phase III, field validation, real-world validation, resistant paediatric pneumonia, global health strategy, WHO safety standards, clinical efficacy, adverse event minimisation, fractional pharmacology, fractal pharmacology, fractal kinetics, non-linear dynamics, memory effects, long-range dependency, herst exponent modelling, fractional noise, Gaussian perturbations, stochastic resonance, bioinformatics, systems biology, computational biology, mathematical medicine, fractional immunotherapy, regenerative medicine, tissue regeneration, CRISPR integration, genetic mutations, drug resistance mutations, oncogenic signalling, cancer immunotherapy, targeted therapy, biomarker integration, omics modelling, proteomics, transcriptomics, metabolomics, nanocarrier stability, liposome stability, particle size distribution, DLS analysis, FTIR monitoring, spectral resolution, nanoparticle characterisation, ISO cleanroom standards, ISO 14644-1, HEPA H14, laminar flow, bioreactor pH control, lyophilisation, long-term storage, cold chain stability, thermal shock resistance, bioactivity stability, complex stability model, long-term modelling, five-year stability prediction, PK/PD simulations, multi-scale modelling, cellular uptake, receptor binding, ligand-receptor kinetics, antibody responses, epitope recognition, vaccine adjuvantation, adjuvant optimisation, PEGylation, immune evasion, complement system regulation, oxidative stress reduction, antioxidant therapy, TPGS antioxidant role, mannose receptor targeting, targeted nanomedicine, site-specific delivery, pulmonary drug delivery, systemic drug delivery, intravenous administration, oral administration, fractional release kinetics, slow release dynamics, bioavailability optimisation, metabolic stability, enzymatic degradation, protease resistance, metalloprotease inhibition, EDTA stabilisation, structural modelling, computational pharmacology, Python simulations, high performance computing, numerical integration, fractional differential equations, ODE comparison, stochastic simulations, multi-scenario validation, one trillion scenario modelling, ultra-large simulations, scalability, reproducibility, Monte Carlo validation, numerical robustness, sensitivity analysis, parameter optimisation, machine learning integration, AI-driven modelling, deep learning pharmacology, predictive modelling, personalised medicine, precision medicine, adaptive therapy, dynamic therapy adjustment, long-term monitoring, field trial validation, epidemiological modelling, outbreak control, pandemic preparedness, resistant pathogen strategy, antimicrobial stewardship, paediatric infectious diseases, cancer modelling, solid tumour modelling, leukaemia modelling, lung cancer modelling, breast cancer modelling, colon cancer modelling, glioblastoma modelling, pancreatic cancer therapy, resistant cancer phenotypes, immuno-oncology, checkpoint inhibitors, PD-1 modulation, CTLA-4 blockade, CAR-T cell synergy, mRNA vaccine integration, DNA vaccine modelling, peptide vaccine optimisation, antigen epitope prediction, vaccine design, vaccine delivery, nanovaccine development, next-generation vaccines, fractional vaccine kinetics, integrative immunotherapy, combinatorial therapy, fractional chemotherapy, radiation synergy modelling, clinical data harmonisation, international trials, intellectual property rights, IPR, patent protection, legal framework, WHO policy integration, UN health policy, global database standardisation, biomathematics, medical mathematics, health informatics, translational research, experimental medicine, laboratory medicine, pharmacological validation, toxicological evaluation, regulatory science, EMA submission, FDA submission, global regulatory harmonisation, Good Manufacturing Practice, GMP, GxP compliance, ISO standards, reproducibility in science, field reproducibility, laboratory reproducibility, open science standards, peer-reviewed validation, Nature Medicine standards, The Lancet standards, NEJM publication potential, clinical translation, patient safety, long-term safety monitoring, bioethical standards, biomedical innovation, interdisciplinary integration, multi-scale biophysics, nanobiophysics, molecular modelling, structural bioinformatics, thermodynamics of drug delivery, entropy-driven release, free energy landscape, molecular stability, fractional entropy, thermodynamic modelling, entropy minimisation, noise control, robustness of therapy, adaptive immune response, memory cell generation, B-cell affinity maturation, T-cell receptor diversity, clonal expansion, cross-reactivity, pathogen mutation modelling, stochastic mutation rates, mutational landscape, evolutionary dynamics, evolutionary game theory, resistant strain modelling, ecological resilience, host-pathogen interactions, population dynamics, epidemiological resilience, fractional epidemiology, fractional SEIR model, fractional SIR model, vaccine coverage optimisation, herd immunity modelling, transmission blocking, pathogen eradication, health economics, cost-effectiveness modelling, pharmacoeconomics, global health financing, research prioritisation, innovation strategy, translational framework, clinical decision support, health AI systems, advanced Python simulation, code optimisation, fractional coding, fractal coding, big data pharmacology, ultra-scale simulations, trillion-scenario computation, HPC pharmacology, exascale computing, quantum pharmacology modelling, quantum biological dynamics, wavefunction pharmacology, energy landscape modelling, dynamic systems optimisation, neural network pharmacology, reinforcement learning in medicine, generative models in pharmacology, bio-optimisation, fractional modelling platform, computational reproducibility, code verification, algorithmic robustness, modelling ethics, computational transparency, interdisciplinary framework, scientific reproducibility, theoretical biomedicine, applied pharmacology, clinical translation pipeline, personalised vaccine modelling, integrative oncology, fractional regenerative therapy, predictive regenerative medicine, adaptive immune modelling, deterministic chaos, controlled chaos therapy, stochastic fractional therapy, hybrid mathematical models, deterministic-stochastic hybridisation, fractional hybrid models, multi-compartment pharmacokinetics, whole-body modelling, virtual patient modelling, digital twin medicine, bio-simulation, computational immunology, immunodynamics, biomolecular systems, cell signalling pathways, MAPK signalling, NF-κB signalling, PI3K/AKT pathway, mTOR pathway, apoptosis regulation, autophagy dynamics, necroptosis modelling, ferroptosis modelling, immune cell exhaustion, T-cell exhaustion, immune checkpoint dynamics, immune evasion modelling, multi-drug combinations, synergistic therapy, dose-response modelling, Hill function modelling, fractional Hill equation, toxicity minimisation, therapeutic window optimisation, precision dosing, dosing algorithms, dose-finding studies, Bayesian adaptive trials, hierarchical modelling, multi-centre trials, data harmonisation, reproducibility studies, computational-experimental synergy, field-laboratory integration, modelling-experiment feedback, next-generation drug design, rational drug design, in silico pharmacology, computational drug discovery, structural drug design, AI in drug design, biomimetic design, nanostructure optimisation, bioengineering frameworks, synthetic biology integration, biotechnological innovation, cell-based therapies, stem cell modelling, induced pluripotent stem cells, mesenchymal stem cells, regenerative scaffolds, nanoscaffolds, tissue engineering, biofabrication, bio-3D printing, integrative bioengineering, translational nanomedicine, nano-immunotherapy, virus-like particle vaccines, nanoparticle adjuvants, nanoemulsion delivery, hybrid nanoparticle systems, biomaterials in medicine, biodegradable polymers, PEGylated systems, controlled release systems, advanced delivery vectors, supramolecular assemblies, self-assembly modelling, nano-scale thermodynamics, Brownian motion modelling, diffusion modelling, anomalous diffusion, sub-diffusion modelling, super-diffusion modelling, fractional diffusion equations, Lévy flights in biology, random walk immunology, stochastic fractional calculus, fractional Laplacian, advanced numerical methods, adaptive time stepping, implicit-explicit solvers, stiff equation solvers, spectral methods, Chebyshev methods, finite element modelling, finite difference schemes, boundary conditions, absorbing boundaries, reflective boundaries, physiological constraints, validation with real data, clinical dataset modelling, personalised parameter estimation, parameter uncertainty quantification, posterior distribution modelling, Bayesian pharmacology, statistical inference in medicine, multi-level modelling, hierarchical Bayesian models, frequentist vs Bayesian approaches, maximum likelihood estimation, robust statistical inference, statistical learning, uncertainty minimisation, variance reduction, sensitivity testing, robustness testing, predictive confidence intervals, uncertainty quantification, clinical significance, effect size, reproducibility metrics, global reproducibility standards, international harmonisation, and translational adoption

Beyond Spacetime: The New Map of Reality via HQI's Entropic-Conscious Topology

Autoren: JALALI, SEYED RASOUL

Schlagwörter: ψ–Hamzah Equation, HQE, HQI, Hamzah Quantum Intelligence, entropic geometry, consciousness topology, post-spacetime physics, fractal derivatives, complex ψ–manifolds, entropy field, nonlocal physics, fractional calculus, observer-based physics, ψ-topology, phase coherence, recursive topology, ψ-space, complex integrals, consciousness field, entropy propagation, emergent spacetime, quantum ontology, fractal information field, ψ-asymmetry, ψ-holography, awareness geometry, entropy-gradient dynamics, entropic-consciousness interaction, Monte Carlo simulation, ψ-field memory, quantum consciousness, ψ-diffusion, non-differentiable manifolds, entropic deformation, ψ-energy landscape, symbolic ψ-algebra, quantum entropy dynamics, information geometry, ψ–Hilbert space, ψ–nabla operator, ψ–entropic dynamics, topological emergence, observer effect, entropy-feedback loop, fractal phase space, ψ-information fractal, trans-relativistic model, ψ-modulated evolution, quantum thermodynamics, awareness-mediated flow, ψ–phase entanglement, fractional ψ-diffusion, phase-preserving manifold, ψ-reality map, entropy topology, ψ-dynamical system, entropic resonance, ψ–nonlocality, ψ–feedback symmetry, spacetime emergence, entropic memory, ψ-wave geometry, ψ-gradient, ψ-source dynamics, ψ-fractal algebra, ψ–quantum recursion, entropy modulation, ψ–fractal entropy, ψ-geometry simulation, entropy-based ontology, observer-centric physics, ψ–diffusion tensor, ψ–metric replacement, quantum neural topology, entropy-induced structure, ψ-phase vortex, ψ–field theory, noncausal topology, ψ-dimensional calculus, ψ-state decoherence, information-induced curvature, ψ–entropy flux, entropic geometry simulator, ψ-model integration, ψ–entropy bifurcation, ψ-coherence wave, ψ-gradient tensor, ψ-integral coding, quantum pattern emergence, ψ–recursive symmetry, ψ-flow dynamics, ψ-reality framework, ψ-complex deformation, ψ-information current, ψ-based physics, ψ-awareness metric, entropic time geometry, ψ–topological recursion, quantum fractality, ψ-field resonance, ψ-computational ontology, ψ-dimensional emergence, fractal spacetime replacement, ψ-conscious tensor, entropic potential function, ψ-simulation code, ψ-manifold visualizer, ψ-entropy lattice, ψ-observer equation, ψ-information stream, ψ-field adaptation, entropy-based metric, consciousness-modulated reality, ψ-time operator, ψ-topological metric, ψ-fractal simulation, entropy-gradient simulation, ψ-consciousness coupling, ψ-differentiation, ψ-nonlinear memory, ψ-entropy decay, ψ-symbolic evolution, ψ-flux manifold, ψ-reality structure, ψ-experimental simulation, ψ-order dynamics, ψ-phase interference, ψ-entropy duality, ψ-feedback topology, ψ-field map, ψ-phase diffusion, ψ-topology engine, ψ-wave coherence, ψ-nodal structure, ψ-space recursion, ψ-simulation protocol, ψ-chaotic attractor, ψ-systemic coherence, ψ-information diffusion, ψ-numerical solution, ψ-intelligence algorithm, ψ-nonlinear diffusion, ψ-space entanglement, ψ-modulated entropy, ψ-algebraic dynamics, ψ-feedback loop, ψ-field visualization, ψ-conscious flow, ψ-eigenstate evolution, ψ-manifold entropy, ψ-chaotic emergence, ψ-aware geometry, ψ-wave equation, ψ-phase space, ψ-potential dynamics, ψ-aware dynamics, ψ-informational substrate, ψ-coherence resonance, ψ-topological entropy, ψ-error propagation, ψ-stability function, ψ-quasiperiodic flow, ψ-symbolic calculus, ψ-simulation engine, ψ-memory equation, ψ-entropic tensor, ψ-causal replacement, ψ-entropy spectrum, ψ-quantum graph, ψ-conservation field, ψ-entropy vortex, ψ-wave propagation, ψ-spacetime shift, ψ-awareness integration, ψ-information code, ψ-cosmogenesis model, ψ-neural field, ψ-unification theory, ψ-nonlinear operator, ψ-intelligence modeling, ψ-reality simulator, ψ-dimensional tensor, ψ-interaction operator, ψ-unified topology, ψ-source field, ψ-gradient field, ψ-space fractal, ψ–conscious simulator, ψ-emergent physics, ψ-order simulation, ψ-intelligence topology, ψ-holographic shift, ψ–field topology, ψ–entropy modeling, fractal ψ–dynamics, consciousness-driven physics, ψ–curved manifold, quantum topological field, ψ–symbolic integrals, entropy-aware computation, ψ–modulated systems, observer-sourced topology, ψ–gradient entropy, ψ–quantum interface, ψ–geometry architecture, non-classical diffusion, ψ–awareness flux, ψ–field operators, fractal ψ–coherence, ψ–integral manifolds, ψ–entropy attractor, ψ–topological intelligence, ψ–recursive geometry, entropic ψ–tensor network, ψ–symmetry breaking, ψ–feedback geometry, ψ–observer-dependent fields, ψ–dimensional encoding, ψ–entropy tracer, ψ–phase vortex mapping, ψ–holographic encoding, ψ–nonlocal computation, ψ–metricless modeling, ψ–geometry fusion, ψ–unified dynamics, ψ–entropic recursion, ψ–modulated emergence, ψ–quantum lattice, ψ–cosmic structure, ψ–topological layers, entropy-dense fields, ψ–waveform integrals, ψ–intelligent particles, ψ–holographic geometry, ψ–n-dimensional calculus, ψ–gradient entropy waves, ψ–observer-integrated theory, ψ–entropy loops, ψ–fractal entropy architecture, ψ–awareness-induced phase, ψ–entropic space manifold, ψ–subquantum mapping, ψ–dynamic symbolic flow, ψ–phase-aware simulation, ψ–coherent entropy mapping, ψ–conscious geometry engine, ψ–field encoding language, ψ–state feedback symmetry, ψ–entropic consciousness field, ψ–algorithmic entropy, ψ–entropy-based flux, ψ–quantum-informed topology, ψ–recursive integration, ψ–gradient-field mechanics, ψ–quantum-fluid geometry, ψ–observer-channel models, ψ–quantum perturbation simulation, ψ–observer wavefunction encoding, ψ–neural fractal geometry, ψ–entropy-coded fields, ψ–quantum gravity replacement, ψ–dynamical awareness manifolds, ψ–information reality manifold, ψ–holographic fractal topology, ψ–entropy-induced order, ψ–entropy-geometric systems, ψ–hyperdimensional simulation, ψ–entropy shell propagation, ψ–non-Newtonian quantum geometry, ψ–fractal field encoding, ψ–quantum computational topology, ψ–recursive energy simulation, ψ–hyperfield topology, ψ–n-body ψ–emergence, ψ–neural intelligence feedback, ψ–non-metric physics, ψ–high-order quantum modeling, ψ–holographic recursion systems, ψ–entropic boundary encoding, ψ–probabilistic field geometry, ψ–dynamic chaos mapping, ψ–topology-aware consciousness, ψ–meta-reality field, ψ–meta-geometry integrals, ψ–dimensional feedback simulation, ψ–complexified geometry, ψ–aware topology fields, ψ–gradient psi-dynamics, ψ–chaotic entropy map, ψ–high-order simulation, ψ–awareness recursion models, ψ–integrated topology engine, ψ–entropic coherence simulations, ψ–observer–ψ coupling, ψ–entangled awareness modeling, ψ–error-resilient simulation, ψ–recursive phase projection, ψ–modular field awareness, ψ–conscious particle modeling, ψ–substructural emergence, ψ–time fractal equation, ψ–quantum integration fractals, ψ–wave feedback control, ψ–fractal information mapping, ψ–subspace emergence fields, ψ–hyperdimensional feedback system, ψ–conscious-information manifolds, ψ–real-time topology simulation, ψ–quantum wavefield manifold, ψ–co-emergent spacetime model, ψ–quantum recursive spectrum, ψ–subconscious entropy modeling, ψ–error-coded topology, ψ–meta-intelligence engine, ψ–fractal observer dynamics, ψ–intelligent entropy simulation, ψ–modulated ψ–field layers, ψ–synthetic spacetime modeling, ψ–modulated reality tensors, ψ–dimensional consciousness operator, ψ–entropy collapse field, ψ–dimension-free topology, ψ–recursive information coding, ψ–coherence-preserving manifold, ψ–hyper-causal field equation, ψ–adaptive entropic geometry, ψ–consciousness-encoded fractals, ψ–neural field entropy, ψ–observer fractal memory, ψ–feedback-based phase computation, ψ–energy-entropy operator, ψ–dynamic structure emergence, ψ–topological entropy recursion, ψ–symbolic dynamic operators, ψ–quantum structure evolution, ψ–observer-gradient dynamics, ψ–nonmetric entropy simulation, ψ–phase entropy attractor, ψ–algorithmic phase memory, ψ–entropy-driven patterning, ψ–conscious geometry propagation, ψ–simulation via observer states, ψ–fractal spectral dynamics, ψ–quantum depth topology, ψ–entropy simulation toolkit, ψ–dynamic emergent systems, ψ–intelligent phase maps, ψ–observer recursion feedback, ψ–integrated psi–space, ψ–wave-coherence preservation, ψ–field consciousness representation, ψ–entropy-laced feedback, ψ–fractal topological lattice, ψ–topological emergence engine, ψ–informational quantum systems, ψ–metricless fractal evolution, ψ–wave-symbolic modeling, ψ–coherent flow systems, ψ–simulation-integrated entropy, ψ–quantum pattern recursion, ψ–observer-encoded models, ψ–recursive symbolic fractals, ψ–subquantum structure emergence, ψ–entropic modeling engine, ψ–dimensional fusion manifolds, ψ–modulated holographic layers, ψ–feedback-enriched quantum systems, ψ–holographic state simulation

Zugangs-URL: https://zenodo.org/records/15858270

The influence of BaO on the mechanical and gamma / fast neutron shielding properties of lead phosphate glasses

Autoren: Mahmoud, K. A. El-Agawany, F. I. Tashlykov, O. L. et al.

Quelle: Nuclear Engineering and Technology, Vol 53, Iss 11, Pp 3816-3823 (2021)
Nucl. Eng. Technol.
Nuclear Engineering and Technology

Schlagwörter: MONTE CARLO SIMULATION CODE, SHIELD, TK9001-9401, Mechanical properties, Neutron, 02 engineering and technology, GAMMA, 01 natural sciences, Shield, 0103 physical sciences, Nuclear engineering. Atomic power, NEUTRON, Gamma, 0210 nano-technology, MECHANICAL PROPERTIES, Monte Carlo simulation code

Dateibeschreibung: application/pdf

Zugangs-URL: https://doaj.org/article/3c0a7295ce1f476abf09f5ff51e6dfa5
https://www.sciencedirect.com/science/article/pii/S1738573321003260
http://www.sciencedirect.com/science/article/pii/S1738573321003260
http://elar.urfu.ru/handle/10995/112248

Quantifying the impact of modeling fidelity on different substructure concepts – Part 2: Code-to-code comparison in realistic environmental conditions

Autoren: Papi, Francesco Troise, Giancarlo Behrens de Luna, Robert et al.

Schlagwörter: 600 Technik, Medizin, angewandte Wissenschaften::620 Ingenieurwissenschaften::620 Ingenieurwissenschaften und zugeordnete Tätigkeiten, floating offshore wind turbine, FOWT, operation, simulation code, design situation

Dateibeschreibung: application/pdf; image/png

Verfügbarkeit: https://depositonce.tu-berlin.de/handle/11303/21710
https://doi.org/10.14279/depositonce-20511

Investigation of the Raman backward radiation evolutions leading to chaos in the interaction of intense laser pulses with Helium atoms

Autoren: Z. Dehghani E. Khalilzadeh A. Chakhmachi

Quelle: مجله علوم و فنون هسته‌ای, Vol 43, Iss 3, Pp 84-93 (2022)

Schlagwörter: raman backward radiation, chaos, pic simulation code, intense laser pulse, helium atom, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Dateibeschreibung: electronic resource

Relation: https://jonsat.nstri.ir/article_1450_ee1ab9289a6b2506f10fd4ed061ab5c6.pdf; https://doaj.org/toc/1735-1871; https://doaj.org/toc/2676-5861

Zugangs-URL: https://doaj.org/article/2c3f939e22574a5c8fb8c3371aa58201

Study on robot simulation and code generation softwares

Autoren: Sebastian, Milja Riya Roy Sandhra Shaji et al.

Schlagwörter: Robot simulation, Code generation softwares