The Higgs Boson and the Big Bang

by Jake Hebert, Ph.D.
From Institute for Creation Research

Scientists from Europe’s CERN research center presented evidence on July 4, 2012, for a particle that is likely the Higgs boson, the last remaining elementary particle predicted by the Standard Model of particle physics.1 Does this discovery have relevance for the creation-evolution controversy?

Particles can generally be classified into two categories, according to the quantum mechanical rules that they obey: fermions and bosons. The Higgs particle is called a boson because it falls into the second category.

Evidence for the Higgs boson was obtained from data collected at CERN’s Large Hadron Collider near Geneva, Switzerland, as well as at Fermilab’s Tevatron collider in the United States. Although the Higgs boson has been nicknamed the “God particle,” it is widely agreed that the name is more for publicity than accuracy, and many physicists do not like it. “I detest the name ‘God particle’. I am not particularly religious, but I find the term an ‘in your face’ affront to those who [are],” wrote physicist Vivek Sharma, a leader of the Higgs search. “I do experimental physics not GOD.”2

In order to understand the importance of the Higgs boson, it is necessary to review some modern physics. Quantum mechanics is a theory that successfully describes the behavior of matter and energy at subatomic and atomic scales, and quantum field theory is an extension of quantum mechanics. A field is a quantity that has a value at each point in space. Some fields are characterized by numbers at each point in space and are called scalar fields. A temperature field, for instance, would assign a temperature to each point in space and could, for instance, be used to show how the temperature within a room varies with location. Vector fields have both numbers and directions associated with each point in space; an example of a vector field would be the electric field surrounding a charged object.3

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There is a tendency to intuitively think of particles as being like little round marbles. In modern physics, however, the reality is more complicated. Roughly speaking, quantum field theory views particles as “ripples” in the fields.4

Researchers think that one of these fields—a scalar field called the Higgs field—gives particles mass through their interaction with this field. Particles that interact strongly with the Higgs field have more mass, and vice versa. The Higgs boson, in turn, can be thought of as the smallest possible ripple in the Higgs field.5

The Standard Model is the theory that describes the relationships between elementary particles and three of the four fundamental forces (it does not include gravity). Prior to July 2012, physicists had confirmed the existence for all the elementary particles of the Standard Model except one—the Higgs boson.

There is no doubt that this discovery, if confirmed, is a triumph for the Standard Model.

Some are claiming that this discovery is a blow to Christianity. The Higgs boson is “another nail in the coffin of religion,” said one Cambridge University professor.6 However, noted theoretical physicist and professing atheist Stephen Hawking lost one hundred dollars betting that the Higgs boson would not be found, as he had apparently hoped that a more “elegant” mechanism would be found that could explain how particles have mass.7

Although quantum field theories are not directly related to the creation-evolution controversy, the Higgs field is sometimes discussed within the context of Big Bang cosmology. Shortly after the supposed Big Bang, proponents speculate that as the very high temperatures in the early universe decreased, a change in the Higgs field occurred, so that it was able to interact with particles in such a way as to give them mass. (The theoretical change in the Higgs field at high temperatures is somewhat similar to the way a magnet can lose its magnetism if heated above a high temperature.)8

But, presumably, particles would have mass as a result of their interaction with the Higgs field in either a creation or an evolution scenario, provided that temperatures are sufficiently low. Why would a theoretical change in the Higgs field at extremely high temperatures necessarily imply that such high temperatures were actually present in the early universe? Moreover, a major media outlet acknowledged the lack of direct evidence for this hypothetical high-temperature transition in the Higgs field, despite the general pro-evolution bias of the popular press.9

Physicist and popular author Michio Kaku wrote:

In quantum physics, it was a Higgs-like particle that sparked the cosmic explosion [the Big Bang]. In other words, everything we see around us, including galaxies, stars, planets and us, owes its existence to the Higgs boson.10

Kaku’s statement is ambiguous because it is not clear whether he is claiming that the Higgs boson itself or another still-hypothetical Higgs-like particle would have been the cause of the Big Bang. He is apparently alluding to the fact that Big Bang cosmologists speculate that a Higgs-like scalar field, the inflaton, could have caused inflation—a phenomenon needed in order to solve serious (if not fatal) problems in the original Big Bang model.

The inflaton is still hypothetical, but Big Bang cosmologists are convinced that, given the chaotic conditions they believe prevailed in the early universe, inflation-driving scalar fields would have been present in at least some regions of space. In older inflation models, inflation occurred shortly after the Big Bang and lasted for a very brief time. Theorists have since concluded, however, that when quantum mechanical fluctuations are taken into account, inflation in different regions of space would end at different times. The result is that a bubble or pocket of space that has stopped inflating will be surrounded by a region of space that is still expanding at a much faster rate. Because the still-inflating region is expanding much more rapidly than the pocket, the pocket becomes an island “universe” in a “sea” of still-inflating space.

This process is thought to continue indefinitely, so that infinitely many of these island universes are formed, and our universe is only one. Moreover, this process never ends—once inflation starts, it continues forever in the bulk of space. In such a view, it is only our universe that supposedly began 13.7 billion years ago. Hence, the idea that our universe is just one of infinitely many universes in a great multiverse is a direct consequence of modern inflationary theory. . . .

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