@emergentdynamics.bsky.social
Independent researcher exploring the mathematics of Emergent Spacetime Dynamics (ESD).
Perfect equilibrium can’t exist. Fluctuations at the micro level ensure flux, no matter how stable things appear. Entropy generates time. The process keeps driving forward, so the universe can't just stop. Dark energy is only the illusion created by minted space. It's not a force.
∇ₜS = dΦ/dt
#ESD
∇ₜS = dΦ/dt
#ESD
November 2, 2025 at 7:55 AM
Perfect equilibrium can’t exist. Fluctuations at the micro level ensure flux, no matter how stable things appear. Entropy generates time. The process keeps driving forward, so the universe can't just stop. Dark energy is only the illusion created by minted space. It's not a force.
∇ₜS = dΦ/dt
#ESD
∇ₜS = dΦ/dt
#ESD
I am based in Ventura, California. No website yet. I have several papers in peer review, so this is the only venue I use until publication.
November 2, 2025 at 6:39 AM
I am based in Ventura, California. No website yet. I have several papers in peer review, so this is the only venue I use until publication.
True equilibrium doesn’t exist in the universe.
Even when systems appear stable, there’s always residual fluctuation. Energy, entropy, and time remain in motion — equilibrium is only a temporary balance between opposing gradients. Equilibrium is just a pause before the next adjustment.
∇ₜS = dΦ/dt
Even when systems appear stable, there’s always residual fluctuation. Energy, entropy, and time remain in motion — equilibrium is only a temporary balance between opposing gradients. Equilibrium is just a pause before the next adjustment.
∇ₜS = dΦ/dt
November 2, 2025 at 6:22 AM
True equilibrium doesn’t exist in the universe.
Even when systems appear stable, there’s always residual fluctuation. Energy, entropy, and time remain in motion — equilibrium is only a temporary balance between opposing gradients. Equilibrium is just a pause before the next adjustment.
∇ₜS = dΦ/dt
Even when systems appear stable, there’s always residual fluctuation. Energy, entropy, and time remain in motion — equilibrium is only a temporary balance between opposing gradients. Equilibrium is just a pause before the next adjustment.
∇ₜS = dΦ/dt
Better now? The math is spelled right. All that counts..
October 31, 2025 at 2:20 AM
Better now? The math is spelled right. All that counts..
Laws and structure are. Once that happens, the machinery is right in front of us.
October 31, 2025 at 2:10 AM
Laws and structure are. Once that happens, the machinery is right in front of us.
Why do we continue to feel the need to make things up when the mechanics are right in front of us?
∇ₜ S = d/dt (ℏ Φ) = G⁻¹ (Eₜ - Eₛ)
∇ₜ S = d/dt (ℏ Φ) = G⁻¹ (Eₜ - Eₛ)
October 31, 2025 at 1:17 AM
Why do we continue to feel the need to make things up when the mechanics are right in front of us?
∇ₜ S = d/dt (ℏ Φ) = G⁻¹ (Eₜ - Eₛ)
∇ₜ S = d/dt (ℏ Φ) = G⁻¹ (Eₜ - Eₛ)
Fascinating work — the Higgs–charm coupling might reveal subtler field symmetries than we expect.
In an emergent framework, mass coupling could scale as:
m_i ∝ Phi_i * (dS_i/dt) / c^2
This suggests that decay pathways trace entropy flow rather than just interaction strength. Exciting times ahead.
In an emergent framework, mass coupling could scale as:
m_i ∝ Phi_i * (dS_i/dt) / c^2
This suggests that decay pathways trace entropy flow rather than just interaction strength. Exciting times ahead.
October 30, 2025 at 6:44 PM
Fascinating work — the Higgs–charm coupling might reveal subtler field symmetries than we expect.
In an emergent framework, mass coupling could scale as:
m_i ∝ Phi_i * (dS_i/dt) / c^2
This suggests that decay pathways trace entropy flow rather than just interaction strength. Exciting times ahead.
In an emergent framework, mass coupling could scale as:
m_i ∝ Phi_i * (dS_i/dt) / c^2
This suggests that decay pathways trace entropy flow rather than just interaction strength. Exciting times ahead.
Awesome. That's now my favorite team as well.
October 30, 2025 at 3:31 PM
Awesome. That's now my favorite team as well.
You love soccer. That's awesome. I love seeing passion on display. I have no idea what team you like, but I hope they win.
October 30, 2025 at 12:33 PM
You love soccer. That's awesome. I love seeing passion on display. I have no idea what team you like, but I hope they win.
Why would anyone want to be a part of something that's openly called "The Dark Side"? Never understood that one.
You're awesome, Mr. Hamill.
You're awesome, Mr. Hamill.
October 30, 2025 at 3:53 AM
Why would anyone want to be a part of something that's openly called "The Dark Side"? Never understood that one.
You're awesome, Mr. Hamill.
You're awesome, Mr. Hamill.
Fascinating.
October 29, 2025 at 3:46 PM
Fascinating.
Thank you, Dr. Pettersen, I value your opinion a lot, and I really appreciate your time and perspective. If you’d like, feel free to follow my page — I post occasional updates on my entropy–time work.
October 29, 2025 at 2:15 PM
Thank you, Dr. Pettersen, I value your opinion a lot, and I really appreciate your time and perspective. If you’d like, feel free to follow my page — I post occasional updates on my entropy–time work.
Best of luck.
October 29, 2025 at 6:09 AM
Best of luck.
Your work is very interesting. I like it.
October 29, 2025 at 5:13 AM
Your work is very interesting. I like it.
I look forward to reading it. Take a look at my page. Perhaps we can compare notes one day?
October 29, 2025 at 1:41 AM
I look forward to reading it. Take a look at my page. Perhaps we can compare notes one day?
Maybe time only moves forward because entropy does? Once ∇ₜS > 0, the arrow’s already drawn. Your thoughts, sir?
October 28, 2025 at 7:32 PM
Maybe time only moves forward because entropy does? Once ∇ₜS > 0, the arrow’s already drawn. Your thoughts, sir?
Flat galactic rotation curves don’t require hidden mass — just feedback.
v_c(r) = √[(G M(r)/r) (1 + ε φ(r; λ))]
φ(r; λ) = ∫₀^∞ (4π r′² ρ(r′) e^{–|r–r′|/λ}/|r–r′|) dr′
ε ≈ 10⁻² couples entropy flow to curvature, reproducing the “dark-matter” effect with only baryonic mass.
v_c(r) = √[(G M(r)/r) (1 + ε φ(r; λ))]
φ(r; λ) = ∫₀^∞ (4π r′² ρ(r′) e^{–|r–r′|/λ}/|r–r′|) dr′
ε ≈ 10⁻² couples entropy flow to curvature, reproducing the “dark-matter” effect with only baryonic mass.
October 27, 2025 at 3:37 PM
Flat galactic rotation curves don’t require hidden mass — just feedback.
v_c(r) = √[(G M(r)/r) (1 + ε φ(r; λ))]
φ(r; λ) = ∫₀^∞ (4π r′² ρ(r′) e^{–|r–r′|/λ}/|r–r′|) dr′
ε ≈ 10⁻² couples entropy flow to curvature, reproducing the “dark-matter” effect with only baryonic mass.
v_c(r) = √[(G M(r)/r) (1 + ε φ(r; λ))]
φ(r; λ) = ∫₀^∞ (4π r′² ρ(r′) e^{–|r–r′|/λ}/|r–r′|) dr′
ε ≈ 10⁻² couples entropy flow to curvature, reproducing the “dark-matter” effect with only baryonic mass.