Here we apply GETT to the major anomalies, paradoxes, unexplained mysteries and phenomena of the universe as they appear in the news.
"Solving Science" is a video blog series,
cataloguing the impact of a density dependent scalar physics issues as they arise in the press.
3I/ATLAS Anomalies
OIbservation of our intergalactic visitor suggest unusual behaviour. GETT explains why...
01
Early Massive Structure
JWST shows unexplained supermassive evolved structure of galaxies far too early in the timeline. GETT explains how and why this is possible.
02
Red Supergiant Anomalies
The largest circumstellar gas and dust bubbles ever observed around DFK52 are explained with GETT density threshold dynamics
03
"Dark Stars"
Far too early, too bright, too large, "Dark Stars" are a physics-defying mystery, until GETT density dependent mechanism offer explanation
04
The Hubble Tension
Standing at an 8.31% delta in the measurement of the expansion of the universe, GETT resolves to only a 0.43% and determines the rate is 70.49 km/s +/- 0.43.
05
Gravitational Waves
There's an issue: spacetime is geometry: maths. So how can it support and propagate Gravitational Waves of energy that impact the GW detectors? GETT shifts to Expanse Tension Ripples (ETRs) - real waves in a real field.
06
The Hourglass Planetary Nebulae
Extraordinary symmetry, tight equatorial waist, unusual dimness, concentric rings, shells and nodes, and the off-centred white dwarf. Basically, the Hourgalss Nebula MyCn18 is a mystery unexplained by science - but GETT has a proposal to resolve...
07
Little Red Dots (LRDs)
James Webb Space Telescope has uncovered one of the strangest phenomena in the early universe: tiny, compact objects that shine as faint red dots about a billion years after the Big Bang. These “Little Red Dots” (LRDs)
appear suddenly, are seen in large numbers, and then just as quickly vanish from view.
08
Time for a new model of the universe
The Dark Energy Spectroscopic Instrument (DESI) released results that shake the very foundations of modern cosmology: the
expansion is not accelerating as strongly as expected, but "dark energy" is weakening over time – a discovery that threatens to destabilise the entire "constant" ΛCDM
framework. Awkward! GETT resolves...
09
"Glitchy" Neutron Stars
You’ll see how every known variety of neutron star — from faint “zombie” remnants to hyper-magnetars and black-hole precursors — fits perfectly onto a single physical spectrum governed by density and coupling of GETT.
The high-density threshold switch of GETT triggers the coupling of compact object mass to the expanding scalar field. "Glitchiness" ensues...
10
The Schwarzchild Radius (Event Horizon)
Karl Schwarzschild, a German physicist and astronomer, calculated the critical distance from a mass where light can no longer escape — the boundary we now call the event horizon of a black hole. But that's maths. Here, the Schwarzschild radius is re-derived from first physical principles of QFT, using GETT.
11
Globular Clusters have no Dark Matter!
I love this! An old problem solvers technique: Go to where the problem ISN'T!
Globular clusters, despite being gravitationally bound systems, do not display any
"dark matter". They behave “normally.” which is very odd. That contrast is the key.
They are the smoking gun for density dependence of GETT...
12
The Amaterasu Particle
A single subatomic particle, nicknamed the Amaterasu Particle, struck Earth’s atmosphere with a staggering 240 exa-electron volts of
energy. That’s millions of times more powerful than anything humanity can generate in a particle accelerator — even beyond what’s theoretically allowed by known physics. However, permitted and explained by GETT...
13
The Double-Slit Experiment Paradox
For >224 years has been the most striking demonstration of quantum weirdness: single particles, fired one at a time, somehow
produce an interference pattern as if they travelled through both slits simultaneously.
Then, GETT adds an all-pervading scalar field to propagate the wave. Particles are Particles. Quantum Mechanics is in shock. Watch video 14A and then the animation in video 14B.
14
The Early Universe
Microseconds in Years
The early universe is widely believed to have completed its most profound physical transformations in fractions of a second. GETT has two things to contribute: (i). EWSB triggers the orthogonal emergence of gravity, interia, and proper time. (ii). Proper time dilation with mass density.
There you go - all the time you ever need!
15
Why does 𝐸=𝑚𝑐^2 work?
Einstein’s mass–energy equivalence has been one of the most successful equations in science, but WHY does it work?
GETT explains that the mass term is a
composite of three resistances to the scalar field, and then the speed of light is applied only as a proxy for the underlying invariant causal reconfiguration rate of the underlying Holland field.
16
Dark matter onset in our Milky Way galaxy
We present a new empirical analysis of
vertical stellar motions in the Milky Way, using ~6 million stars from ESA Gaia DR3. No theory, just data analysis. The transition occurs at log₁₀ρ ≈ −21.6 kg m⁻³. Statistical confidence exceeds 99.99%. The onset aligns with a
specific baryonic volume density threshold as GETT predicted.
17
Feynman's Glass Reflection Paradox
In 1986 Feynman raised a his famous paradox: Photons of light appears to just "know" the rear bulk material properties when reflecting from the front surface, with no accepted
physical explanation for why the reflected ray intensity exhibits sensitivity to bulk material properties. The GETT material density
dependent scalar field with tension gradients resolves...
18
GRAVITY'S CAUSE!
Physical not Geometry
Aristotle, Galileo, Hooke, Newton, Einstein... what we have today is calculus and geometry. We know what it does (within out limited density domain environment), however, we have never understood WHY? Gravity emerges from a density-driven net flow imbalance in the Holland Field (Φ): it is the restoring force of mass resisting expansion in a scalar field.
19
CERN ALICE & ATLAS
Pb-Pb Collisions
Instead of Lead-Lead particle collisions simply flying apart, the data show event-wide, isotropic acceleration — as if the medium itself is driving expansion. GETT proposes that under extreme density, mass–energy can modulate the expansion response of the medium itself, producing acceleration without adding energy and without violating conservation laws.
20
The 44 Paradoxes of Water: Water is Wierd
The 44 documented water anomalies across thermodynamic, structural, interfacial, and electromagnetic domains. Rather than treating these effects as isolated curiosities, GETT evaluates whether their clustering reflects a deeper organising principle. This highly cooperative medium may amplify this background Φ-conditioning as high "expressivity".
21
Coming Soon: A 99% Dark Matter galaxy
This is going to be a fun one, since Dark Matter does not exist.
A huge challenge: can GETT explain
observations of a galaxy that appears to
be made of 99% dark matter....?!
Working on this next highly ambitious Solving Science No. 22
Teaser Alert: Of course it can!
22