Quotes & Sayings


We, and creation itself, actualize the possibilities of the God who sustains the world, towards becoming in the world in a fuller, more deeper way. - R.E. Slater

There is urgency in coming to see the world as a web of interrelated processes of which we are integral parts, so that all of our choices and actions have [consequential effects upon] the world around us. - Process Metaphysician Alfred North Whitehead

Kurt Gödel's Incompleteness Theorem says (i) all closed systems are unprovable within themselves and, that (ii) all open systems are rightly understood as incomplete. - R.E. Slater

The most true thing about you is what God has said to you in Christ, "You are My Beloved." - Tripp Fuller

The God among us is the God who refuses to be God without us, so great is God's Love. - Tripp Fuller

According to some Christian outlooks we were made for another world. Perhaps, rather, we were made for this world to recreate, reclaim, redeem, and renew unto God's future aspiration by the power of His Spirit. - R.E. Slater

Our eschatological ethos is to love. To stand with those who are oppressed. To stand against those who are oppressing. It is that simple. Love is our only calling and Christian Hope. - R.E. Slater

Secularization theory has been massively falsified. We don't live in an age of secularity. We live in an age of explosive, pervasive religiosity... an age of religious pluralism. - Peter L. Berger

Exploring the edge of life and faith in a post-everything world. - Todd Littleton

I don't need another reason to believe, your love is all around for me to see. – Anon

Thou art our need; and in giving us more of thyself thou givest us all. - Khalil Gibran, Prayer XXIII

Be careful what you pretend to be. You become what you pretend to be. - Kurt Vonnegut

Religious beliefs, far from being primary, are often shaped and adjusted by our social goals. - Jim Forest

We become who we are by what we believe and can justify. - R.E. Slater

People, even more than things, need to be restored, renewed, revived, reclaimed, and redeemed; never throw out anyone. – Anon

Certainly, God's love has made fools of us all. - R.E. Slater

An apocalyptic Christian faith doesn't wait for Jesus to come, but for Jesus to become in our midst. - R.E. Slater

Christian belief in God begins with the cross and resurrection of Jesus, not with rational apologetics. - Eberhard Jüngel, Jürgen Moltmann

Our knowledge of God is through the 'I-Thou' encounter, not in finding God at the end of a syllogism or argument. There is a grave danger in any Christian treatment of God as an object. The God of Jesus Christ and Scripture is irreducibly subject and never made as an object, a force, a power, or a principle that can be manipulated. - Emil Brunner

“Ehyeh Asher Ehyeh” means "I will be that who I have yet to become." - God (Ex 3.14) or, conversely, “I AM who I AM Becoming.”

Our job is to love others without stopping to inquire whether or not they are worthy. - Thomas Merton

The church is God's world-changing social experiment of bringing unlikes and differents to the Eucharist/Communion table to share life with one another as a new kind of family. When this happens, we show to the world what love, justice, peace, reconciliation, and life together is designed by God to be. The church is God's show-and-tell for the world to see how God wants us to live as a blended, global, polypluralistic family united with one will, by one Lord, and baptized by one Spirit. – Anon

The cross that is planted at the heart of the history of the world cannot be uprooted. - Jacques Ellul

The Unity in whose loving presence the universe unfolds is inside each person as a call to welcome the stranger, protect animals and the earth, respect the dignity of each person, think new thoughts, and help bring about ecological civilizations. - John Cobb & Farhan A. Shah

If you board the wrong train it is of no use running along the corridors of the train in the other direction. - Dietrich Bonhoeffer

God's justice is restorative rather than punitive; His discipline is merciful rather than punishing; His power is made perfect in weakness; and His grace is sufficient for all. – Anon

Our little [biblical] systems have their day; they have their day and cease to be. They are but broken lights of Thee, and Thou, O God art more than they. - Alfred Lord Tennyson

We can’t control God; God is uncontrollable. God can’t control us; God’s love is uncontrolling! - Thomas Jay Oord

Life in perspective but always in process... as we are relational beings in process to one another, so life events are in process in relation to each event... as God is to Self, is to world, is to us... like Father, like sons and daughters, like events... life in process yet always in perspective. - R.E. Slater

To promote societal transition to sustainable ways of living and a global society founded on a shared ethical framework which includes respect and care for the community of life, ecological integrity, universal human rights, respect for diversity, economic justice, democracy, and a culture of peace. - The Earth Charter Mission Statement

Christian humanism is the belief that human freedom, individual conscience, and unencumbered rational inquiry are compatible with the practice of Christianity or even intrinsic in its doctrine. It represents a philosophical union of Christian faith and classical humanist principles. - Scott Postma

It is never wise to have a self-appointed religious institution determine a nation's moral code. The opportunities for moral compromise and failure are high; the moral codes and creeds assuredly racist, discriminatory, or subjectively and religiously defined; and the pronouncement of inhumanitarian political objectives quite predictable. - R.E. Slater

God's love must both center and define the Christian faith and all religious or human faiths seeking human and ecological balance in worlds of subtraction, harm, tragedy, and evil. - R.E. Slater

In Whitehead’s process ontology, we can think of the experiential ground of reality as an eternal pulse whereby what is objectively public in one moment becomes subjectively prehended in the next, and whereby the subject that emerges from its feelings then perishes into public expression as an object (or “superject”) aiming for novelty. There is a rhythm of Being between object and subject, not an ontological division. This rhythm powers the creative growth of the universe from one occasion of experience to the next. This is the Whiteheadian mantra: “The many become one and are increased by one.” - Matthew Segall

Without Love there is no Truth. And True Truth is always Loving. There is no dichotomy between these terms but only seamless integration. This is the premier centering focus of a Processual Theology of Love. - R.E. Slater

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Note: Generally I do not respond to commentary. I may read the comments but wish to reserve my time to write (or write off the comments I read). Instead, I'd like to see our community help one another and in the helping encourage and exhort each of us towards Christian love in Christ Jesus our Lord and Savior. - re slater

Showing posts sorted by relevance for query weak anthropic principle. Sort by date Show all posts
Showing posts sorted by relevance for query weak anthropic principle. Sort by date Show all posts

Thursday, September 14, 2023

R.E. Slater Shorts - Process Philosophy leans towards the Weak Anthropic Principle



R.E. Slater Shorts

Process Philosophy leans towards the 
Weak Anthropic Principle


I've mentioned this before here when looking at quantum physics but it seems to me that Whitehead's process philosophy of organism must lean towards the Weak Many-Worlds Anthropic Principle rather than the Strong Deterministic Anthropic Principle. Whether you are for or against it please use the comment section to lend us your reasoning.

Occasionally I use the word pancessual universe when referring to all the processual relations working together in the cosmos... which also may be redundant way of saying process universe which in itself intends this very same sentiment; likewise, I may use the phrase "a pancessual process universe" as a way to emphasize the obvious conjectures within process-based metaphysics.

Here are a few observations:


The Fine Structure Constant is one the strangest numbers in all of physics. It’s the job of physicists to worry about numbers, but there’s one number that physicists have stressed about more than any other. That number is 0.00729735256 - approximately 1/137. This is the fine structure constant, and it appears everywhere in our equations of quantum physics, and we’re still trying to figure out why.

 

PART 1

From Big Think's constant of 42 to nature's inimitable constant of 1/137 we may correlate the existential pun of "The Hitchhiker's Guide to the Galaxy" to the real life anthropological question when prehensively interjecting the existence of all things to this relational fine-structure constant of 1/137.

More simply, "Without the constant 1/137 we, with everything else, are not."
"..Its name is the fine-structure constant, and it's a measure of the strength of the interaction between charged particles and the electromagnetic force. The current estimate of the fine-structure constant is 0.007 297 352 5693, with an uncertainty of 11 on the last two digits [= 1/137]."

Personally, I favor the weak argument over the strong anthropic principle giving us the possibility for all possibilities.... Meaning that:

i) life must be based on chaotic randomness... and in our case, one which could allow 'the principle of negentropy' to become a reality in its own right, thus giving us a universe which produces life (WAP)...

versus

ii) structural superdeterminancy leaving us with a closed future and fundamentally predictive outcomes (SAP). Which is yet another reason why we live in a processual universe and not a deterministic one.

...Thus and thus, yet another warrant for process-based panentheistic Christianity and not a theistic-based neo-Platonic faith .

"In cosmology, the anthropic principle refers to any philosophic consideration of the structure of the universe, the values of the constants of nature, or the laws of nature, which have a bearing upon the existence of life."

PART 2

When referring to the Anthropic Principle, whether weak or strong, one is unconscious imply that is exceptional, and exceptionally notated in the cosmic journals of the universe....

But this is NOT what processual teleology would imply.

Why?

Because, it would mean that humans are unlike every other living creature or organism. Which is not the case either evolutionarily nor in our case, per processual theology.

What then are You Saying?

Simply, humanity is birthed from the same stuff in the universe as everything else is.... Which is another way of saying that humanity is a CONSEQUENCE or EVENTUALITY of the cosmos rather than a foreign substance to it.

Thus and thus humanity is of the same DNA as the very universe itself within which we came to be and exist.

Which further implies for Christian process theology that God so ordered the substance which was already there that God gave this substance infinite possibilities of its own evolutionary structure that it might build an extremely complex multidimensional singular universe to multiuniverses.

Humanity then is NOT a foreign product anathema to the universe's processual complex self or cosmological being.

PART 3

The "Anthropic Principle" per se seems to state that the Universe only exists for us  - and not for itself nor its parts. That it's ultimate destination or fulfillment is only (or supremely) found in humanity.

However, only our sheer hubris would call such a theorem ANTHRO...

We should then immediately rename the anthropic principle the cosmic principle or some such nomenclature!

We should call the anthropic principal by another name. One which is unrelated to it's referred outcome by us as a human outcome.

Further, perhaps more neutral names could speak to cosmology's teleolgical process which character was seen as birthing life from any-and-all mediating sources.

That is, by the universe's very nature it is oriented to birth life in some evolutionary form. And possibly in every form... and is not simply a "human" principle so named in man's prideful estimate of himself.

R.E. Slater
September 42 (Ha!), 2023


Additional References



* * * * * * *


BELOW FOLLOWS THREE ARTICLES RELATED
TO THE ANTHROPIC PRINCIPLE

  • the Fine-Structure Constant

  • Known Cosmological Constants

  • How the Anthropic Principle Became the Most Abused idea in Science


* * * * * * *



Life as we know it would not exist without 
this highly unusual number

by Paul Sutter published March 24, 2022


The fine-structure constant is a seemingly random number with no units or dimensions, which has cropped up in so many places in physics, and seems to control one of the most fundamental interactions in the universe.

The fine-structure constant is a seemingly random number with no units or dimensions, which has cropped up in many places in physics, and seems to control one of the most fundamental interactions in the universe. (Image credit: Wikimedia)

Paul M. Sutter is an astrophysicist at SUNY Stony Brook and the Flatiron Institute, host of "Ask a Spaceman" and "Space Radio," and author of "How to Die in Space."

A seemingly harmless, random number with no units or dimensions has cropped up in so many places in physics and seems to control one of the most fundamental interactions in the universe.

Its name is the fine-structure constant, and it's a measure of the strength of the interaction between charged particles and the electromagnetic force. The current estimate of the fine-structure constant is 0.007 297 352 5693, with an uncertainty of 11 on the last two digits. The number is easier to remember by its inverse, approximately 1/137.

If it had any other value, life as we know it would be impossible. And yet we have no idea where it comes from.




A fine discovery

Atoms have a curious property: They can emit or absorb radiation of very specific wavelengths, called spectral lines. Those wavelengths are so specific because of quantum mechanics. An electron orbiting around a nucleus in an atom can't have just any energy; it's restricted to specific energy levels.

When electrons change levels, they can emit or absorb radiation, but that radiation will have exactly the energy difference between those two levels, and nothing else — hence the specific wavelengths and the spectral lines.

But in the early 20th century, physicists began to notice that some spectral lines were split, or had a "fine structure" (and now you can see where I'm going with this). Instead of just a single line, there were sometimes two very narrowly separated lines.

The full explanation for the "fine structure" of the spectral line rests in quantum field theory, a marriage of quantum mechanics and special relativity. And one of the first people to take a crack at understanding this was physicist Arnold Sommerfeld. He found that to develop the physics to explain the splitting of spectral lines, he had to introduce a new constant into his equations — a fine-structure constant.


The introduction of a constant wasn't all that new or exciting at the time. After all, physics equations throughout history have involved random constants that express the strengths of various relationships. Isaac Newton's formula for universal gravitation had a constant, called G, that represents the fundamental strength of the gravitational interaction. The speed of light, c, tells us about the relationship between electric and magnetic fields. The spring constant, k, tells us how stiff a particular spring is. And so on.

But there was something different in Sommerfeld's little constant: It didn't have units. There are no dimensions or unit system that the value of the number depends on. The other constants in physics aren't like this. The actual value of the speed of light, for example, doesn't really matter, because that number depends on other numbers. Your choice of units (meters per second, miles per hour or leagues per fortnight?) and the definitions of those units (exactly how long is a "meter" going to be?) matter; if you change any of those, the value of the constant changes along with it.

But that's not true for the fine-structure constant. You can have whatever unit system you want and whatever method of organizing the universe as you wish, and that number will be precisely the same.

If you were to meet an alien from a distant star system, you'd have a pretty hard time communicating the value of the speed of light. Once you nailed down how we express our numbers, you would then have to define things like meters and seconds.

But the fine structure constant? You could just spit it out, and they would understand it (as long as they count numbers the same way as we do).

The limit of knowledge

Sommerfeld originally didn't put much thought into the constant, but as our understanding of the quantum world grew, the fine-structure constant started appearing in more and more places. It seemed to crop up anytime charged particles interacted with light. In time, we came to recognize it as the fundamental measure for the strength of how charged particles interact with electromagnetic radiation.

Change that number, change the universe. If the fine-structure constant had a different value, then atoms would have different sizes, chemistry would completely change and nuclear reactions would be altered. Life as we know it would be outright impossible if the fine-structure constant had even a slightly different value.

So why does it have the value it does? Remember, that value itself is important and might even have meaning, because it exists outside any unit system we have. It simply … is.

In the early 20th century, it was thought that the constant had a value of precisely 1/137. What was so important about 137? Why that number? Why not literally any other number? Some physicists even went so far as to attempt numerology to explain the constant's origins; for example, famed astronomer Sir Arthur Eddington "calculated" that the universe had 137 * 2^256 protons in it, so "of course" 1/137 was also special.

Today, we have no explanation for the origins of this constant. Indeed, we have no theoretical explanation for its existence at all. We simply measure it in experiments and then plug the measured value into our equations to make other predictions.

Someday, a theory of everything — a complete and unified theory of physics — might explain the existence of the fine-structure constant and other constants like it. Unfortunately, we don't have a theory of everything, so we're stuck shrugging our shoulders.

But at least we know what to write on our greeting cards to the aliens.


* * * * * * *


STARTS WITH A BANG — AUGUST 18, 2023

Ask Ethan:
How many constants define our Universe?


Some constants, like the speed of light, exist with no underlying
explanation. How many "fundamental constants" does our Universe require?


In the right, the gauge bosons, which mediate the three fundamental quantum forces of our Universe, are illustrated. There is only one photon to mediate the electromagnetic force, there are three bosons mediating the weak force, and eight mediating the strong force. This suggests that the Standard Model is a combination of three groups: U(1), SU(2), and SU(3), whose interactions and particles combine to make up everything known in existence. With gravity thrown into the mix, there are a total of 26 fundamental constants required to explain our Universe, with four big questions still awaiting explanation. | Credit: Daniel Domingues/CERN


KEY TAKEAWAYS

  • Some aspects of our Universe, like the strength of gravity's pull, the speed of light, and the mass of an electron, don't have any underlying explanation for why they have the values they do.

  • For each aspect like this, a fundamental constant is required to "lock in" the specific value that we observe these properties take on in our Universe.

  • All told, we need 26 fundamental constants to explain the known Universe: the Standard Model plus gravity. But even with that, some mysteries still remain unsolved.


Although it’s taken centuries of science for us to get there, we’ve finally learned, at an elementary level, what it is that makes up our Universe. The known particles of the Standard Model comprise all of the normal matter that we know of, and there are four fundamental interactions that they experience: the strong and weak nuclear forces, the electromagnetic force, and the force of gravity. When we place those particles down atop the fabric of spacetime, the fabric distorts and evolves according to the energy of those particles and the laws of Einstein’s General Relativity, while the quantum fields they generate permeate all of space.

But how strong are those interactions, and what are the elementary properties of each of those known particles? Our rules and equations, as powerful as they are, don’t tell us all of the information we require to know those answers. We need an additional parameter to answer many of those questions: a parameter that we must simply measure to know what it is. Each such parameter translates to a needed fundamental constant in order to completely describe our Universe. But how many fundamental constants does that equate to, today? That’s what Patreon supporter Steve Guderian wants to know, asking:

“What is the definition of a [fundamental] physical constant, and how many are there now?”

It’s a challenging question without a definitive answer, because even the best description we can give of the Universe is both incomplete and also may not be the most simple. Here’s what you should think about.


This chart of particles and interactions details how the particles of the Standard Model interact according to the three fundamental forces that Quantum Field Theory describes. When gravity is added into the mix, we obtain the observable Universe that we see, with the laws, parameters, and constants that we know of governing it. However, many of the parameters that nature obeys cannot be predicted by theory, they must be measured to be known, and those are “constants” that our Universe requires, to the best of our knowledge.Credit: Contemporary Physics Education Project/DOE/SNF/LBNL

Think about any particle at all, and how it might interact with another. One of the simplest fundamental particles is an electron: the lightest charged, point-like particle. If it encounters another electron, it’s going to interact with it in a variety of ways, and by exploring its possible interactions, we can understand the notion of where you need a “fundamental constant” to explain some of those properties. Electrons, for example, have a fundamental charge associated with them, e, and a fundamental mass, m.

  • These electrons will gravitationally attract one another proportional to the strength of the gravitational force between them, which is governed by the universal gravitational constant: G.
  • These electrons will also repel one another electromagnetically, inversely proportional to the strength of the permittivity of free space, ε.

There are other constants that play a major role in how these particles behave as well. If you want to know how fast an electron moves through spacetime, it has a fundamental limit: the speed of light, c. If you force a quantum interaction to occur, say, between an electron and a photon, you’ll encounter the fundamental constant associated with quantum transitions: Planck’s constant, ħ. There are weak nuclear interactions that the electron can take part in, such as nuclear electron capture, that require an additional constant to explain their interaction strength. And although the electron doesn’t engage in them, there’s also the possibility of a strong nuclear action between a different set of particles: the quarks and gluons.

The decays of the positively and negatively charged pions, shown here, occur in two stages. First, the quark/antiquark combination exchanges a W boson, producing a muon (or antimuon) and a mu-neutrino (or antineutrino), and then the muon (or antimuon) decays through a W-boson again, producing a neutrino, an antineutrino, and either an electron or positron at the end. This is the key step in making the neutrinos for a neutrino beamline, and also in the cosmic ray production of muons, assuming the muons survive for long enough to reach the surface. The weak, strong, electromagnetic, and gravitational interactions are the only ones we know of at present.Credit: E. Siegel


However, all of these constants have units attached to them: they can be measured in units like Coulombs, kilograms, meters-per-second, or other quantifiable physical quantities. These units are arbitrary, and an artifact of how, as humans, we measure and interpret them.

When physicists talk about truly fundamental constants, they recognize that there’s no inherent importance to ideas like “the length of a meter” or the “time interval of a second” or “the mass of a kilogram” or any other value. We could work in any units we liked, and the laws of physics would behave exactly the same. In fact, we can frame everything we’d ever want to know about the Universe without defining a fundamental unit of “mass” or “time” or “distance” at all. We could describe the laws of nature, entirely, by using solely constants that are dimensionless.

Dimensionless is a simple concept: it means a constant that’s just a pure number, without meters, kilograms, seconds or any other “dimensions” in them. If we go that route to describe the Universe, and get the fundamental laws and initial conditions correct, we should naturally get out all the measurable properties we can imagine. This includes things like particle masses, interaction strengths, cosmic speed limits, and even the fundamental properties of spacetime. We would simply define their properties in terms of those dimensionless constants.

Today, Feynman diagrams are used in calculating every fundamental interaction spanning the weak and electromagnetic forces, including in high-energy and low-temperature/condensed conditions. Including higher-order “loop” diagrams leads to more refined, more accurate approximations of the true value to quantities in our Universe. However, the strong interactions cannot be computed in this fashion, and must either be subject to non-perturbative computer calculations (Lattice QCD) or require experimental inputs (the R-ratio method) in order to account for their contributions.Credit: V. S. de Carvalho and H. Freire, Nucl. Phys. B, 2013


You might wonder, then, how you could describe things like a “mass” or an “electric charge” with a dimensionless constant. The answer lies in the structure of our theories of matter and how it behaves: the theories of our four fundamental interactions. Those interactions, also known as the fundamental forces, are:
  • the strong nuclear force,
  • the weak nuclear force,
  • the electromagnetic force, and
  • the gravitational force,
all of which can be recast in either quantum field theoretic (i.e., particles and their quantum interactions) or General Relativistic (i.e., the curvature of spacetime) formats.

You might look at the particles of the Standard Model and think,
“Oh geez, look at their electric charges. Some have a charge that’s the electron’s charge (like the electron, muon, tau, and W- boson), some have a charge that’s ⅓ of the electron’s charge (the down, strange, and bottom quarks), some have a charge that’s -⅔ of the electron’s charge (the up, charm, and top quarks), and others are neutral. And then, on top of that, the antiparticles all have the opposite charge of the ‘particle version.'”
But that doesn’t mean each one needs their own constant; the structure of the Standard Model (and specifically, of the electromagnetic force within the Standard Model) gives you the charges of each particle in terms of one another. As long as you have the structure of the Standard Model, just one constant — the electromagnetic coupling of particles within the Standard Model — is sufficient to describe the electric charges of every known particle.


The particles and antiparticles of the Standard Model are predicted to exist as a consequence of the laws of physics. Although we depict quarks, antiquarks and gluons as having colors or anticolors, this is only an analogy. The actual science is even more fascinating. None of the particles or antiparticles are allowed to be the dark matter our Universe needs.Credit: E. Siegel/Beyond the Galaxy


Unfortunately, the Standard Model — even the Standard Model plus General Relativity — doesn’t allow us to simplify every descriptive parameter in this fashion. “Mass” is a notoriously difficult one: one where we don’t have a mechanism to interrelate the various particle masses to one another. The Standard Model can’t do it; each massive particle needs its own unique (Yukawa) coupling to the Higgs, and that unique coupling is what enables particles to get a non-zero rest mass. Even in String Theory, a purported way to construct a “theory of everything” that successfully describes every particle, force, and interaction in the framework of one overarching theory, can’t do that; Yukawa couplings simply get replaced by “vacuum expectation values,” which again are not derivable. One must measure these parameters in order to understand them.

With that said, here is a breakdown of how many dimensionless constants are needed to describe the Universe to the best of our understanding, including:
  • what those constants give us,
  • what possibilities there are to reduce the number of constants to get the same amount of information out, and
  • what puzzles remain unanswered within our present framework, even given those constants.
It’s a sobering reminder of both how far we’ve come, as well as how far we still need to go, in order to have a full comprehension of all that’s in the Universe.


The running of the three fundamental coupling constants (electromagnetic, weak, and strong) with energy, in the Standard Model (left) and with a new set of supersymmetric particles (right) included. The fact that the three lines almost meet is a suggestion that they might meet if new particles or interactions are found beyond the Standard Model, but the running of these constants is perfectly within expectations of the Standard Model alone. Importantly, cross-sections change as a function of energy, and the early Universe was very high in energy in ways that have not been replicated since the hot Big Bang.Credit: W.-M. Yao et al. (Particle Data Group), J. Phys. (2006)


1.) The fine-structure constant (α), or the strength of the electromagnetic interaction. In terms of some of the physical constants we’re more familiar with, this is a ratio of the elementary charge (of, say, an electron) squared to Planck’s constant and the speed of light. That combination of constants, together, gives us a dimensionless number that’s calculable today! At the energies currently present in our Universe, this number comes out to ≈ 1/137.036, although the strength of this interaction increases as the energy of the interacting particles rise. In combination with a few of the other constants, this allows us to derive the electric charge of each elementary particle, as well as their particle couplings to the photon.

2.) The strong coupling constant, which defines the strength of the force that holds individual baryons (like protons and neutrons) together, as well as the residual force that allows them to bind together in complex combinations of atomic nuclei. Although the way the strong force works is very different from the electromagnetic force or gravity — getting very weak as two (color-charged) particles get arbitrarily close together but stronger as they move apart — the strength of this interaction can still be parametrized by a single coupling constant. This constant of our Universe, too, like the electromagnetic one, changes strength with energy.

The rest masses of the fundamental particles in the Universe determine when and under what conditions they can be created, and also describe how they will curve spacetime in General Relativity. The properties of particles, fields, and spacetime are all required to describe the Universe we inhabit, but the actual values of these masses are not determined by the Standard Model itself; they must be measured to be revealed.Credit: Universe-review

3.) through 17.) The 15 couplings to the Higgs of the 15 Standard Model particles with non-zero rest masses. Each of the six quarks (up, down, strange, charm, bottom, and top), all six of the leptons (including the charged electron, muon, and tau plus the three neutral neutrinos), the W-boson, the Z-boson, and the Higgs boson, all have a positive, non-zero rest mass to them. For each of these particles, a coupling — including, for the Higgs, a self-coupling — is required to account for the values of mass that each of the massive Standard Model particles possess.

It’s great on one hand, because we don’t need a separate constant to account for the strength of gravitation; it gets rolled into this coupling.

But it’s also disappointing. Many have hoped that there would be a relationship we could find between the various particle masses. One such attempt, the Koide formula, looked like a promising avenue in the 1980s, but the hoped-for relations turned out only to be approximate. In detail, the predictions of the formula fell apart.

Similarly, colliding electrons with positrons at a specific energy — half the rest-mass energy of the Z-boson apiece — will create a Z-boson. Colliding an electron at that same energy with a positron at rest will make a muon-antimuon pair at rest, a curious coincidence. Only, this too is just approximately true; the actual muon-antimuon energy required is about 3% less than the energy needed to make a Z-boson. These tiny differences are important, and indicate that we do not know how to arrive at particle masses without a separate fundamental constant for each such massive particle.


Although gluons are normally visualized as springs, it’s important to recognize that they carry color charges with them: a color-anticolor combination, capable of changing the colors of the quarks and antiquarks that emit-or-absorb them. The electrostatic repulsion and the attractive strong nuclear force, in tandem, are what give the proton its size, and the properties of quark mixing are required to explain the suite of free and composite particles in our Universe.Credit: APS/Alan Stonebraker

18.) through 21.) Quark mixing parameters. There are six types of massive quark, and two pairs of three — up-charm-top and down-strange-bottom — all have the same quantum numbers as one another: same spin, same color charge, same electric charge, same weak hypercharge and weak isospin, etc. The only differences they have are their different masses, and the different “generation number” that they fall into.

The fact that they have the same quantum numbers allow them to mix together, and a set of four parameters, parameters from what’s known as the CKM mixing matrix (after three physicists, Cabibbo, Kobayashi, and Maskawa) are required to describe specifically how they mix, enabling them to oscillate into one another.

This is a vital process essential to the weak interaction, and it shows up in measuring how:
  • more massive quarks decay into less massive ones,
  • how CP-violation occurs in the weak interactions,
  • and how radioactive decay works in general.
The six quarks, all together, require three mixing angles and one CP-violating complex phase to describe, and those four parameters are an additional four fundamental, dimensionless constants that we cannot derive, but must be measured experimentally.


This diagram displays the structure of the standard model (in a way that displays the key relationships and patterns more completely, and less misleadingly, than in the more familiar image based on a 4×4 square of particles). In particular, this diagram depicts all of the particles in the Standard Model (including their letter names, masses, spins, handedness, charges, and interactions with the gauge bosons: i.e., with the strong and electroweak forces). It also depicts the role of the Higgs boson, and the structure of electroweak symmetry breaking, indicating how the Higgs vacuum expectation value breaks electroweak symmetry and how the properties of the remaining particles change as a consequence. Neutrino masses remain unexplained.Credit: Latham Boyle and Mardus/Wikimedia Commons


22.) through 25.) The neutrino mixing parameters. Similar to the quark sector, there are four parameters that detail how neutrinos mix with one another, given that the three types of neutrino species all have the same quantum number. Although physicists initially hoped that neutrinos would be massless and not require additional constants (they’re now part of the 15, not 12, constants needed to describe the masses of Standard Model particles), nature had other plans. The solar neutrino problem — where only a third of the neutrinos emitted by the Sun were arriving here on Earth — was one of the 20th century’s biggest conundrums.

It was only solved when we realized that neutrinos:
  • had very small but non-zero masses,
  • mixed together, and
  • oscillated from one type into another.
The quark mixing is described by three angles and one CP-violating complex phase, and the neutrino mixing is described in the same way, with this specific PMNS matrix having a different name after the four physicists who discovered and developed it (Pontecorvo–Maki–Nakagawa–Sakata matrix) and with values that are completely independent of the quark mixing parameters. While all four parameters have been experimentally determined for the quarks, the neutrino mixing angles have now been measured, but the CP-violating phase for the neutrinos has still only been extremely poorly determined as of 2023.


The far distant fates of the Universe offer a number of possibilities, but if dark energy is truly a constant, as the data indicates, it will continue to follow the red curve, leading to the long-term scenario frequently described on Starts With A Bang: of the eventual heat death of the Universe. If dark energy evolves with time, a Big Rip or a Big Crunch are still admissible, but we don’t have any evidence indicating that this evolution is anything more than idle speculation. If dark energy isn’t a constant, more than 1 parameter will be required to describe it.Credit: NASA/CXC/M. Weiss


26.) The cosmological constant. The fact that we live in a dark-energy rich Universe requires at least one additional fundamental parameter over and above the ones we’ve listed already, and the simplest parameter is a constant: Einstein’s cosmological constant. This was not expected to be there, but it must be accounted for, and there’s no way to do that without adding an additional parameter within our current understanding of physics.

Even with this, there are still at least four additional puzzles that may yet mandate we add even more fundamental constants to fully explain. These include:
  1. The problem of the matter-antimatter asymmetry, also known as baryogenesis. Why is our Universe predominantly made up of matter and not antimatter, when the interactions we know of always conserve the number of baryons (versus antibaryons) and leptons (versus antileptons)? This likely requires new physics, and possibly new constants, to explain.
  2. The problem of cosmic inflation, or the phase of the Universe that preceded and set up the hot Big Bang. How did inflation occur, and what properties did it have in order to enable our Universe to emerge as it has? Likely at least one, and potentially more, new parameters will be needed.
  3. The problem of dark matter. Is it made of a particle? If so, what are that particle’s properties and couplings? If it’s made of more than one type of particle (or field), there is likely going to be more than one new fundamental constant required to describe them.
  4. The problem of why there’s only CP-violation in the weak interactions, and not the strong ones. We have a principle in physics — the totalitarian principle — that states, “Anything not forbidden is compulsory.” In the Standard Model, nothing forbids CP-violation in either the weak or strong nuclear interactions, but we only observe it in the weak interactions. If it shows up in the strong interactions, we need an additional parameter to describe it; if it doesn’t, we likely need an additional parameter to restrict it.


Changing particles for antiparticles and reflecting them in a mirror simultaneously represents CP symmetry. If the anti-mirror decays are different from the normal decays, CP is violated. Time reversal symmetry, known as T, must also be violated if CP is violated. Nobody knows why CP violation, which is fully allowed to occur in both the strong and weak interactions in the Standard Model, only appears experimentally in the weak interactions.Credit: E. Siegel/Beyond the Galaxy

If you give a physicist the laws of physics, the initial conditions of the Universe, and the aforementioned 26 constants, they can successfully simulate and calculate predictions for any aspect of the Universe you like, to the limits of the probabilistic nature of outcomes. The exceptions are few but important: we still can’t explain why there’s more matter than antimatter in the Universe, how the hot Big Bang was set up by cosmic inflation, why dark matter exists or what its properties are, and why there is no CP-violation in the strong interactions. It’s an incredibly successful set of discoveries that we’ve made, but our understanding of the cosmos remains incomplete.

What will the future hold? Will a future, better theory wind up reducing the number of fundamental constants we need, like the Koide formula dreams of doing? Or will we wind up discovering more phenomena (like massive neutrinos, dark matter, and dark energy) that require us to add still greater numbers of parameters to our Universe?

The question is one we cannot answer today, but one that’s important to continue to ask. After all, we have our own ideas about what “elegant” and “beautiful” are when it comes to physics, but whether the Universe is fundamentally simple or complex is something that physics cannot answer today. It takes 26 constants to describe the Universe as we know it presently, but even that large number of free parameters, or fundamental constants, cannot fully explain all there is.

Send in your Ask Ethan questions to startswithabang at gmail dot com!


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How The Anthropic Principle Became The Most Abused Idea In Science

by Ethan Siegel, Senior Contributor
Starts With A Bang, Contributor Group

Jan 26, 2017


That the Universe exists and that we are here to...


The Universe has the fundamental laws that we observe it to have. Also, we exist, and are made of the things we’re made of, obeying those same fundamental laws. And therefore, we can construct two very simple statements that would be very difficult to argue against:

  1. We must be prepared to take account of the fact that our location in the Universe is necessarily privileged to the extent of being compatible with our existence as observers.
  2. The Universe (and hence the fundamental parameters on which it depends) must be as to admit the creation of observers within it at some stage.
These two statements, spoken first by physicist Brandon Carter in 1973, are known, respectively, as the Weak Anthropic Principle and the Strong Anthropic Principle. They simply note that we exist within this Universe, which has the fundamental parameters, constants and laws that it has. And our existence is proof enough that the Universe allows for creatures like us to come into existence within it.

A young star cluster in a star forming region,...


These simple, self-evident facts actually carry a lot of weight. It tells us that our Universe does exist with such properties that an intelligent observer could possibly have evolved within it. This stands starkly in contrast to properties that are incompatible with intelligent life, which cannot describe our Universe, on the grounds that no one would ever exist to observe it. That we are here to observe the Universe — that we actively engage in the act of observing — implies that the Universe is wired in such a way to admit our existence. This is the essence of the Anthropic Principle.


The Milky Way as seen at La Silla Observatory,...


It enables us to make a number of legitimate, scientific statements and predictions about the Universe as well. The fact that we are observers made of carbon tells us that the Universe must have created carbon in some fashion, and led Fred Hoyle to predict that an excited state of the carbon-12 nucleus must exist at a particular energy so that three helium-4 nuclei could fuse into carbon-12 in the interior of stars. Five years later, the discovery of both the theoretical Hoyle State and the mechanism for forming it — the triple-alpha process — was discovered and confirmed by nuclear physicist Willie Fowler, leading to an understanding of how the heavy elements in the Universe were built up in stars throughout the Universe’s history.

The prediction of the Hoyle State and the...


Calculating what the value of our Universe’s vacuum energy — the energy inherent to empty space itself — should be from quantum field theory gives an absurd value that’s far too high. The energy of empty space determines how quickly the Universe’s expansion rate grows (or its contraction rate grows, if it’s negative); if it were too high, we never could have formed life, planets, stars or even molecules and atoms themselves. Given that the Universe arose with galaxies, stars, planets and human beings on it, the value of the Universe’s vacuum energy, Steven Weinberg calculated in 1987, must be no higher than 10^-118 times the number our naïve calculations give us. When we discovered dark energy in 1998, we actually measured that number for the first time, and concluded it was 10^-120 times the naïve prediction. The anthropic principle guided us where our calculational power had failed.


Vizualization of a quantum field theory...


Yet the original two surprisingly simple statements, the Weak and Strong Anthropic Principles, have been misinterpreted so thoroughly that now they’re routinely used to justify illogical, non-scientific statements. People claim that the anthropic principle supports a multiverse; that the anthropic principle provides evidence for the string landscape; that the anthropic principle requires we have a large gas giant to protect us from asteroids; that the anthropic principle explains why we’re located at the distance we are from the galactic center. In other words, people use the anthropic principle to argue that the Universe must be exactly as it is because we exist the way we do. And that’s not only untrue, it’s not even what the anthropic principle says.

Our Universe, from the hot Big Bang until the...


The anthropic principle simply says that we, observers, exist. And that we exist in this Universe, and therefore the Universe exists in a way that it allows observers to come into existence. If you set up the laws of physics so that the existence of observers is impossible, what you’ve set up clearly doesn’t describe our Universe. The evidence for our existence means the Universe allows our existence, but it doesn’t mean the Universe must have unfolded exactly this way. It doesn’t mean our existence is mandatory. And it doesn’t mean the Universe must have given rise to us exactly as we are. In other words, you cannot say “the Universe must be the way it is because we’re here.” That’s not anthropics at all; that’s a logical fallacy. So how did we wind up here?

The string landscape might be an interesting idea,...


In 1986, John Barrow and Frank Tipler wrote an influential book, The Anthropic Cosmological Principle, where they redefined the principles. They stated:

  1. The observed values of all physical and cosmological quantities are not equally probably but they take on values restricted by the requirement that there exists sites where carbon-based life can evolve and by the requirement that the Universe be old enough for it to have already done so.
  2. The Universe must have those properties which allow life to develop within it at some stage in history.

The existence of complex, carbon-based molecules...


So instead of “our existence as observers means that the laws of the Universe must be such that the existence of observers is possible,” we get “the Universe must allow carbon-based, intelligent life and that Universes were life doesn’t develop within it are disallowed.” Barrow and Tipler go further, and offer alternative interpretations, including:

  • The Universe, as it exists, was designed with the goal of generating and sustaining observers.
  • Observers are necessary to bring the Universe into being.
  • An ensemble of Universes with different fundamental laws and constants are necessary for our Universe to exist.

If that last one sounds a lot like a bad interpretation of the multiverse, it’s because all of Barrow and Tipler’s scenarios are based on bad interpretations of a self-evident principle!

Why is gravitation some 40 orders of magnitude...


It’s true that we do exist in this Universe, and that the laws of nature are what they are. By looking at what unknowns might be constrained by the fact of our existence, we can learn something about our Universe. In that sense, the anthropic principle has scientific value! But if you start speculating about what the relationship between humanity, observers or other post hoc ergo propter hoc arguments, you are missing out on your opportunity to actually understand the Universe. Don’t fall for bad anthropic arguments; the fact that we’re here can’t tell us why the Universe is this way and not any other. But if you want to better predict the parameters in the Universe we actually have, the fact that we exist can guide you to a solution you might not have arrived at by any other means.

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Thanks to Geraint Lewis and Luke Barnes for bringing to light much of this information in their thought-provoking book, A Fortunate Universe, now available worldwide..


I am a Ph.D. astrophysicist, author, and science communicator, who professes physics and astronomy at various colleges. I have won numerous awards for science writing since 2008 for my blog, Starts With A Bang, including the award for best science blog by the Institute of Physics. My two books, Treknology: The Science of Star Trek from Tricorders to Warp Drive, Beyond the Galaxy: How humanity looked beyond our Milky Way and discovered the entire Universe, are available for purchase at Amazon. Follow me on Twitter @startswithabang


Monday, November 22, 2021

How a Process-Based Universe Works: Is It "Free to Create" or "Divinely Determined"?




How a Process-Based Universe Works:
Is It "Free to Create" or "Divinely Determined"?

by R.E. Slater

A Process-based Creation always strives for Life

A little while ago I had mentioned once again how a process-based creation always strives for life. Process thought makes this abundantly clear when speaking to the life-giving God as the First Order of Processes from whom all subtending cosmic processes proceed. A Creator-God who endowed His image into a static creation (creatio continua) - or, for those Platonists amongst us insisting on a creation which comes from nothing (creation ex nihilo) - a process-breathed event upon creation which propels life from life once it is so endowed.

Consequently when one comes to Darwinian evolution which states that life births life is simply retelling the Process Christian that evolution is following "the same rules of the game" as Whitehead proposed years later after Darwin in the early 20th century: Life from life to life again and again and again in innumerably marvelous ways.

We live in a Life-birthing Cosmos

Hence, I've provided yet another article "marveling" at how this "finely-tuned universe" can be so amazing.... That we live in a life-birthing cosmos which continually recreates itself to meet up to its divine image breathed into the very fabric of its process-becoming cosmic structure. Regardless the obstacle, regardless the difficulty, "life" by some quantum force, or energy, or biological response will find a way to regenerate itself.

Now to the mechanisms which are causing this physicists and biologists will someday learn more. But whenever I read of the universe "fine-tuning" itself I think of its internal cosmic structures which bring this into play. If the cosmos goes one direction, then another life-giving path will result. If it goes this way, then another way will result. And as amazing as it is to look at the fullness of the cosmos and wonder at its "finely-tuned" symmetry, it also tells to us the story that it is the way that it is because its is driven to be this way by the divine God's very Being having been placed into the depths of the cosmos' DNA.


Two things - God & Potential

GOD

One, we do not need classic theism's divine determinism dogmas of an all-controlling God who is giving moment-by-moment direction, whether large or small (a difference of degrees vs the action itself). The very fact that God placed His Image into creation (whether static or nothing) was enough to allow creation it's own freewill path.

This is the substance of process thought. That we live in a divine creation filled with the ability to birth life processes again and again which God neither needs to guide or direct but who, Himself, has given to the multiverse His very essence. Wherever life is becoming, God is there. Life's presence is where God's presence is found. In fact, it would be quite correct to say that God lies always in the leading edges of the future. Though God does not know the future, it is unnecessary for God to know it. God IS the future. Or better, God is the future's FUTURE!

Hence, creation is fully freewilled because it has been endowed by God's own freewill and thus moves and has it's being-ness in the very essence of God's Being-ness. And since God's Essence, or Being, is always in the PROCESS of Becoming, so will we see and experience the same in a processual-becoming of ourselves, the world, and the cosmos as a whole.

To say God inhabits His creation IMMANANTLY is to say that the Process God of all life-bestowing Essence "flows" with creation's energy flows striving towards a greater becoming than it held when originally set in motion by its God. And yet, this God is greater than the very substance and flow of His creation.

And so, a process theologian therefore teaches panentheism but not pantheism nor classic theism. A panentheistic world does not require a controlling, determining God dogma.  Nor does it need to identify God as the world but a God whose "flow" is captured within the world's very DNA. That this kind of God has released creation to be all that it can be against all the obstacles which it's own freewill can, and will, present to itself.


POTENTIAL

Secondly, I have always errored to the side of the weak anthropic principle over the strong. Over the years I have discussed WAP v SAP many times. Here are few references which may be followed up here and here and here and here. My apologies on this last link but somewhere in my earlier "indeterminancy" posts lies a more embedded discussion; if someone locates it please post in the comments below. Thx).

Two observations

Observation 1

Weak Anthropic Principle (WAP) - If the universe was not able to produce us, we wouldn't be here and we wouldn't know it existed.

Strong Anthropic Principle (SAP) - The universe exists the way it is for our benefit. Observers are the point of the universe. No us, no universe.

Summary - I prefer to think of them as the reasonable and the egotistical versions of the Anthropic principle. Basically the weak version is a common sense statement and the strong is baseless speculation. - Google Anon

Observation 2

...Those are the weak/strong versions of Tipler and company-- the more standard original distinction by Carter (I got most of this from Wiki) is simply that the Weak AP says that "given the fundamental parameters we observe, we have to live in a place and time that is conducive to life." Thus the WAP is only relevant to resolving "fine tuning" problems in regard to why we are here now, as opposed to somewhere else later. Given the cosmological principle that all places are more or less the same, the "fine tuning" that is resolved is purely temporal-- why we are here after 13.7 billion years and not 1 year or 1 decillion years.

The Strong AP goes on to look at the fundamental physical parameters themselves, and asserts that they also have to be fine tuned such that we (human being) could come along at some point in space and time. So it talks about why if you monkey even just a little with the dimensionless ratios of the universe, you seem to dramatically alter the resulting likelihood for generating life. [ <-- process theology does not take this line of thought; it states that regardless of how you tinker, the results will always produce cosmic "life" in other ways. So, not one way to life, but an infinite array or life-creating paths. - re slater]

The reason the SAP is more speculative is that it is not clear what you are comparing-- you can compare life as it might develop in different places and times, and might scientifically find evidence for such life, but life in other hypothetical universes would seem to be a nonscientific issue. So the SAP is not really considered testable science, it's more philosophy, whereas the WAP is on a more solid footing in regard to the general requirements of a scientific explanation.

Personally, I don't think the SAP gives us any understanding of why the parameters are what they are, beyond the obvious point that given the laws we have found, the parameters would have to be within certain ranges or we couldn't be here. That doesn't qualify as "understanding" in my book. The idea that this does not require "fine tuning" on the grounds that there can be many other universes with other parameters that are not fine tuned, but we had to show up here, seems a fruitless and untestable claim. For example, how would one attribute a "probability" to a "universe"? Should we allow the laws to be anything [more or less] in these hypothetical universes, or assert the laws have to be the same only with different parameters?


And with that let's go to today's scientific article and try to fit it's contents into our above Christian observations.

Peace,

R.E. Slater
November 22, 2021







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Our Universe Is Finely Tuned For Life, And There's an Explanation For Why That Is So


MIKE MCRAE      22 NOVEMBER 2021

Physically speaking, our Universe seems uncannily perfect. It stands to reason that if it wasn't, life as we know it – and planets, atoms, everything else really – wouldn't exist.

Now, three physicists from the US, France, and Korea have put forward a new explanation for why life, the Universe, and everything in it has had such a prime opportunity to exist at all.

For some reason, the amount of energy – or more precisely, the mass it equates – and the Universe's accelerating expansion are so neatly balanced, there's been ample opportunity for a few interesting things to unfold over the past 13 billion years or so.

A few magnitudes either way, and the overwhelming gravity would have glued the expansion of spacetime together better than a mouthful of taffy... or been so weak, the rapidly expanding Universe would have left little of interest in its wake.   

Such an apparent near-perfect balance might be a consequence of something called fine-tuning, a process in physics where the features of a system necessarily match or cancel out with such precision. If it didn't, the system just wouldn't look the way it does.

For example, our Universe happens to be neutrally charged. For some reason,  there happens to be a near-identical number of protons to cancel out each electron's charge; add a few more electrons and it would be negative, forcing clumps of matter to push itself apart. 

On the other hand, it could be a consequence of what's referred to as 'naturalness'. The Moon's near-perfect occlusion of the Sun during a solar eclipse, for example, isn't ordained by hard laws of astronomy. The size of the Moon, the Sun, and our perspective of both don't need any further explanations to make sense.

Physicists generally don't like appealing to vague coincidences when they observe the Universe. If two features of a system seem incredibly well matched, there's a strong desire to dig through the rulebook for a deeper explanation.

For electrons and protons, the solution could come with explanations of why there's an imbalance of matter over antimatter.

In the case of the Universe's incredible reflection of energy and expansion, there's no shortage of clever and creative ideas to chew on. Most tend to fall into two categories, however.

One centers on something called the anthropic principle, which says only a universe capable of generating thinking brains like ours can ask philosophical questions such as 'why am I here?'

This might imply there are other universes, though. Maybe an infinite number, most either collapsing the moment they're born or exploding in puffs of endless boredom. Ours just happens to be one of the good ones! Although fun to think about, without any way of establishing the existence of multiverses it isn't a proposition that could bear scientific fruit.

As for the second category, there is the possibility that we're missing some crucial piece of the physics puzzle, such as new fields or symmetries that could fail under specific conditions.

The fact that the resting mass of the Higgs boson – the particle representing a field that gives many fundamental particles their mass – turned out to be unexpectedly light might suggest there's a gap in our understanding of forces and particles.

It itself is the result of another fine-tuning conundrum, being the result of strangely-exact cancellations of other physics. For example, there seems to be some sort of mysterious fine-tuning between the mass of a Higgs boson and the cosmological constant – the density of energy in the vacuum of space.

This latest suggestion mashes together the idea of unknown physics behind the Higgs boson's shockingly itty-bitty mass with a kind of quantum multiverse effect, one that this time could feasibly be tested.

Their model puts the Higgs particle at the center of the fine-tuning explanation. By coupling the boson with other particles in such a way that its low mass would effectively 'trigger' events in physics we observe, it provides a link between forces and mass.

From there, the authors show how weakly interacting variables in a field might affect different kinds of empty space, specifically patches of nothingness with varying degrees of expansion. This potentially demonstrates the link between Higgs bosons and the cosmological constant.

It's a multiverse in a way, given the triggers occurring in different patches of infinite expanding space could plausibly give rise to a seemingly well balanced Universe like ours.

Their math suggests these triggers would be limited to a few possibilities, and even has room for explanations of dark matter. Better still, it also predicts the existence of multiple Higgs particles of varying masses, all smaller than the one we've already observed. That gives the hypothesis something that can be tested, at least.

Until then, it'll remain one of many neat ideas that could one day explain the eerily well-matched tug-of-war that has permitted a complex cosmos to unfold. A place we've come to love as our Universe.

This research was published in Physical Review D.