The goal of this blog is to create a long list of facts that are important, not trivia, and that are known to be true yet are either disputed by large segments of the public or highly surprising or misunderstood by many.
Super fact 73 : The second law of thermodynamics, or the fact that entropy is always increasing in an isolated system does not contradict evolution. Life is not a closed system. The environment is providing energy, the sun is providing energy, geological forces are providing energy, etc.
Does physical laws such as the second law of thermodynamics disprove evolution? This is a trilobite fossil. Shutter Stock Photo ID: 1323000239 by Alizada Studios
A lot of people have never heard of the second law of thermodynamics, or entropy and are unaware of the claim that the second law of thermodynamics contradicts evolution. So how can debunking this claim be surprising, and a super fact? The reason is that this is a popular claim among creationists and according to this Gallup poll 40% of Americans believe in creationism. The fact that this popular but false claim is rooted in a very basic misunderstanding of the second law of thermodynamics and what entropy is makes it super fact.
In the past I’ve read many creationist books that make the claim that the second law of thermodynamics contradicts evolution. One of them was Scientific Creationism (1985) by Henry M. Morris (the father of modern creation science), where he stated that the second law of thermodynamics says that everything tends towards disorder, making evolutionary development (ordering) impossible. The Death of Evolution: Restoring Faith and Wonder in a World of Doubt by Jim Nelson Black, another book I read, and which I gave a one star review on Amazon, makes the same claim. I’ve also come across a lot of people making this claim.
The people who make the claim that the Second Law of Thermodynamics contradict evolution typically do not understand the second law of thermodynamics and do not know what entropy is. Despite that fact they see it as a powerful argument against evolution. I’ve even seen it used against highly respected physics professors who “believe in”, well accept the reality of evolution, by people who had no understanding of the second law of thermodynamics. At one point I even believed the claim myself. Then I studied physics, and well, oops, I was forced to admit that I had been bamboozled.
The Second Law of Thermodynamics
The Second Law of Thermodynamics states that the total entropy (disorder) of an isolated system always increases over time. This means that natural processes tend to move from order to disorder (within the isolated system). It should be noted that disorder is a popular but imperfect metaphor for entropy. Entropy is not the same thing as what people think of as disorder. In physics entropy refers to the logarithm of the number of microstates compatible with the system’s measurable macroscopic state. As molecules randomly arrange themselves into new macroscopic states, the number of possible microstates will increase.
It also means that heat will spontaneously flow from hotter to colder objects, but never the reverse. Another thing it means is that mechanical energy can be converted to thermal energy, but never the reverse. It turns out that those seemingly different statements are physically identical.
Second law of thermodynamics. S corresponds to entropy. Shutter Stock Vector ID: 2342031619 by Sasha701
It is very possible that the entropy of an organism is lower compared to a blob corresponding to all its molecules randomly distributed within a blob. However, that organism did not evolve in isolation inside a hermetically enclosed box without any energy from the outside. Life and evolution operate in an environment full of energy coming from the sun, the Earth, winds, oceans, geological forces, radiation, etc. Evolution does not take place in an isolated system.
It is also important to understand that within an isolated system, pockets of lower entropy can form if they are offset by increased entropy elsewhere within the system. That’s what the word “total” in total entropy means. Crystal formation is an example of creating local pockets of lower entropy (less “disorder”) within a system, but this is always accompanied by a greater increase in entropy in the surroundings. The Universe is an isolated system so the entropy within the Universe should always increase, but again the local pockets of lower entropy that evolution may create are accompanied by a greater increase of entropy elsewhere.
Atoms in a crystal. The crystal represents a pocket of lower entropy. As this pocket of lower entropy forms there is equal of greater increase in entropy in the surroundings. What is true for the crystal is true for the molecules in living beings. Neither the formation of crystals nor the evolution of life contradicts the second law of thermodynamics. Asset id: 689181712 by BK_graphic.
Below is a YouTube video explaining how the second law of thermodynamics does not contradict evolution.
Entropy – Arrow of time
An interesting aspect of the second law of thermodynamics is that it makes entropy serve as an arrow of time. In general, the fundamental laws of physics are time reversible. The equations work the same forwards and backward in time. The equations for gravity, electromagnetism, and the strong nuclear force work the same regardless of time’s direction. An example is if you filmed a planet orbiting a star and played it backward, it would still follow the laws of motion the same way.
Throw a bunch of billiard balls on the floor and film them bouncing and hitting each other and the walls. If you then run the film backwards and forwards it would be far from obvious which is forward and which is backwards, except for the fact that the balls will slow down due to friction. However, balls slowing down due to friction is mechanical energy turning into heat, which is an example of the second law of thermodynamics. The fundamental laws of physics are time reversible, but the second law of thermodynamics is a notable exception. Entropy always increases in an isolated system (like the Universe). By measuring entropy, you can distinguish the past from the future, giving time a direction
I recently read a very interesting book on the history of our Planet Earth, Becoming Earth: How Our Planet Came to Life by Ferris Jabr. Life of various forms, microbes, fungi, plants, animals, etc., has had a large impact on climate, earth’s crust, the composition of the atmosphere, the oceans, and still do. This fact filled book is about this four and half billion history. Below is my review of the but first something about the book formats.
Becoming Earth Book Formats
Becoming Earth: How Our Planet Came to Life by Ferris Jabr comes in four formats. I bought the hardback format.
Hardcover – Publisher : Random House (June 25, 2024), ISBN-10 : 0593133978, ISBN-13 : 978-0593133972, 304 pages, item weight : 2.31 pounds: 6.3 x 1.1 x 9.55 inches, it costs $16.68 on US Amazon. Click here to order it from Amazon.com.
Paperback – Publisher : Random House Trade Paperbacks (April 1, 2025), ISBN-10 : 0593133994, ISBN-13 : 978-0593133996, 320 pages, item weight : 4.8 ounces, dimensions : 5.15 x 0.75 x 7.97 inches, it costs $ 13.57 on US Amazon. Click here to order it from Amazon.com.
Kindle – Publisher : Random House (June 25, 2024), ASIN : B0CJTLBCDX, ISBN-13 : 978-0593133989, 423 pages, it costs $5.99 on US Amazon. Click here to order it from Amazon.com.
Audio– Publisher : Random House Audio (June 25, 2024), Listening Length : 9 hours and 27 minutes, ASIN : B0CKM3P33F, it costs $0.99 on US Amazon with membership. Click here to order it from Amazon.com.
Front cover of Becoming Earth: How Our Planet Came to Life by Ferris Jabr. Click on the image to go to the Amazon page for the hardcover version of the book.
Amazon’s Description of Becoming Earth
NEW YORK TIMES BESTSELLER • A vivid account of a major shift in how we understand Earth, from an exceptionally talented new voice. Earth is not simply an inanimate planet on which life evolved, but rather a planet that came to life.
“Glorious . . . full of achingly beautiful passages, mind-bending conceptual twists, and wonderful characters. Jabr reveals how Earth has been profoundly, miraculously shaped by life.”—Ed Yong, Pulitzer Prize winner and bestselling author of An Immense World
FINALIST FOR THE LOS ANGELES TIMES BOOK PRIZE • FINALIST FOR THE OREGON BOOK AWARD • AN AMERICAN LIBRARY ASSOCIATION NOTABLE BOOK OF THE YEAR
A BEST BOOK OF THE YEAR: Smithsonian, Chicago Public Library, Booklist, Scientific American, Nature
A BEST BOOK OF THE SUMMER: The Atlantic and NPR’s Science Friday
One of humanity’s oldest beliefs is that our world is alive. Though once ridiculed by some scientists, the idea of Earth as a vast interconnected living system has gained acceptance in recent decades. We, and all living things, are more than inhabitants of Earth—we are Earth, an outgrowth of its structure and an engine of its evolution. Life and its environment have coevolved for billions of years, transforming a lump of orbiting rock into a cosmic oasis—a planet that breathes, metabolizes, and regulates its climate.
Acclaimed science writer Ferris Jabr reveals a radical new vision of Earth where lush forests spew water, pollen, and bacteria to summon rain; giant animals engineer the very landscapes they roam; microbes chew rock to shape continents; and microscopic plankton, some as glittering as carved jewels, remake the air and sea.
Humans are one of the most extreme examples of life transforming Earth. Through fossil fuel consumption, agriculture, and pollution, we have altered more layers of the planet in less time than any other species, pushing Earth into a crisis. But we are also uniquely able to understand and protect the planet’s wondrous ecology and self-stabilizing processes. Jabr introduces us to a diverse cast of fascinating people who have devoted themselves to this vital work.
Becoming Earth is an exhilarating journey through the hidden workings of our planetary symphony—its players, its instruments, and the music of life that emerges—and an invitation to reexamine our place in it. How well we play our part will determine what kind of Earth our descendants inherit for millennia to come.
This book gives us a brief overview of the natural history of Earth, emphasizing that not only is life impacted by geological forces, but life is influencing and even creating the composition of the atmosphere, impacting climate and even affecting geological forces. The author explains how microbes, plants, and animals transformed the planet. He is explaining how humans are transforming planet Earth and its climate through fossil fuel consumption, agriculture, and pollution. He is noting that we have altered more layers of the planet in less time than any other species, pushing Earth into a crisis. The author promotes the idea that Earth itself is a living organism (Gaia hypothesis). I am not sure if I entirely buy that idea, but he makes a good case for it.
The book covers a lot of history. Earth is four and half billion years old and a lot has happened. As a result, there are no deep dives into topics. However, the book is filled with hundreds of interesting facts and information, which makes the book a page turner to anyone with a curious mind. One major example of this is that about three billion years ago Cyanobacteria evolved a new type of photosynthesis that used sunlight, water, and carbon dioxide to create energy, while releasing oxygen as a waste product. This transformed the atmosphere and enabled complex life by allowing aerobic respiration to evolve. This invention turned the sky blue, gave us the protective ozone layer, but also caused climate change (snowball Earth) resulting in massive extinctions.
However, there is much more. Another example is that microbes helped transform Earth’s crust. During the first half billion years of Earth’s history, Earth was a water world save for volcanic islands. Trees communicate and assist each other via fungi (Mycorrhizas). Phytoplankton produces 50% of all oxygen, the invention of the Haber-Bosch process more than doubled the world’s crop harvest, there once was 30-60 million Bison roaming the plains, humans now emit 60 to 120 times more carbon dioxide each year than all the world’s volcanoes.
As I mentioned there are hundreds more interesting facts. He also presents a lot of facts and information regarding the destruction of the environment, which may not sit well with everyone. However, I think it is important information. The book includes a large number of references for further reading.
The book is well written and well organized and included fun personal anecdotes. It was easy and entertaining reading and like I said, it is a page turner to people with a curious mind. I loved this book and I highly recommend it.
Back cover of Becoming Earth: How Our Planet Came to Life by Ferris Jabr. Click on the image to go to the Amazon page for the paperback version of the book.
Super fact 72 : About three billion years ago Cyanobacteria evolved a new type of photosynthesis that used sunlight, water, and carbon dioxide to create energy, while releasing oxygen as a waste product. This transformed the atmosphere and enabled complex life by allowing aerobic respiration to evolve. This invention turned the sky blue, gave us the protective ozone layer, but also caused climate change resulting in massive extinctions.
An example of a Cyanobacteria. From Wikipedia. Luke Thompson from Chisholm Lab and Nikki Watson from Whitehead, MIT, CC0, via Wikimedia Commons
Cyanobacteria, also known as blue-green algae, are bacteria capable of oxygenic photosynthesis. Between 3.4 and 2.5 billion years ago they developed a new and very effective form of photosynthesis, which took advantage of highly abundant resources, using sunlight, water, and carbon dioxide turning it into sugar and releasing oxygen as byproduct. This is referred to as the Great Oxidation Event. You can read more about this event here, here, here, here, here, or in the book Becoming Earth by Ferris Jabr.
The atmosphere prior to the Great Oxidation Event was primarily composed of volcanic gases including nitrogen, carbon dioxide, water vapor, methane and ammonia, but almost no free oxygen. The Great Oxidation Event changed all this, but it likely took at least 200 million years.
Cyanobacteria vector illustration. Biological blue green algae diagram with carboxysome, thylakoid and phycobilisome parts location inside cell. Asset id: 1687712761 by VectorMine
A Microbial Great Extinction and Snowball Earth
Oxygen was a toxic gas to many early microbes forcing them to adapt or perish. In addition, the change in the atmospheres composition changed the climate, resulting in a severe global cooling referred to as Snowball Earth. This caused a great extinction, perhaps the most severe extinction in Earth’s history. It is not included among the five mass extinction events in Earth’s history because it happened very early in Earth’s history when only primitive microbial life existed and fossil evidence from that time is nearly non-existent. The definition of a mass extinction event is that at least 75% of the world’s species are lost during a short period of time – geologically speaking. This period is not clearly defined but often defined to be two million years. It is very difficult to determine whether the great extinction following the Great Oxidation Event qualifies as a mass extinction event. To read about mass extinctions click here.
Proterozoic era in the history of the Earth. Snowball earth. Global glaciation of the Earth. Asset id: 2010272753 by Elena Kelman
The Ozone Layer and the Blue Sky
Oxygen is also responsible for formation of the ozone layer in the atmosphere. The UV radiation from the sun split oxygen molecules, which consist of two oxygen atoms, into two separate atoms of oxygen, which then reacted with another oxygen molecule to generate ozone, and oxygen molecule consisting of three oxygen atoms. Ozone acts as a natural sunscreen to prevent harmful UV radiation from reaching the earth. Therefore, oxygen not only enables land dwelling complex multicell organisms to exist by allowing aerobic respiration to evolve, but also by protecting life from too much UV radiation.
As mentioned above, the atmosphere prior to the Great Oxidation Event was primarily composed of volcanic gases and almost no free oxygen. The color of the sky was likely orange, brown. As oxygen replaced the existing gases the sky slowly turned blue. Oxygen molecules along with Nitrogen molecules scatter blue light from the sun through a process called Rayleigh scattering, making the sky appear blue.
Cyanobacteria and The Great Oxygenation Event
It should be noted that there were other geological and biological processes that were responsible for this permanent shift in the Earth’s system, including changes in the composition of volcanic emissions and chemical reactions that allowed atmospheric hydrogen to escape to space, leaving behind an excess of oxygen molecules. However, whatever the exact mix of mechanisms, cyanobacteria were undoubtedly a critical source of accumulating oxygen. It is possible that tectonic activity altered the cycling and distribution of phosphorus and other nutrients essential for cyanobacteria. To read more see the book Becoming Earth by Ferris Jabr.
Super fact 69 : Polar nights happen in the regions north of the Arctic Circle and south of the Antarctic Circle. Together the two polar regions cover an area double as large as the United States, and it includes a population of millions of people. During a polar night the sun does not rise for days, or months, up to six months. The polar nights are special, not just for the daytime darkness, but for the spectacular aurora borealis, the starlit skies, the extremely clear air, and the fact that people often lose track of time during polar nights.
It should be noted that even though the sun never rises during the polar night it may not be totally dark during the entire polar night. Part of the time you may get some light in the middle of the day, what is called polar twilight (nautical twilight or astronomical twilight). Nautical twilight tends to be bluish as shown in the photo below.
When our kids were young, we visited the Ice Hotel in Jukkasjärvi in northern Sweden. We went in March, during the American spring break, which was not during the polar night, so we did not experience it then. The polar night in Jukkasjärvi will begin December 5, 2025, or December 10, 2025, depending on how you count, and end at the beginning of January. However, the Ice Hotel was a fun way to experience a polar region. When I did my Swedish army service I spent the winter in the forest around that area, and even further north, and I experienced the Polar Night firsthand,
The lobby of the ice hotel. Our kids are sitting around a table of ice. A chandelier of ice is hanging above the table. The light is from fiber optics, so the ice won’t melt.
During my army service we stayed in tents in the forest far away from villages and cities and we often did not use any lights. The result was that it was incredibly dark most of the time. It was so dark that I could not see my own hand if I held it right in front of my face. The upside was that the sky was filled with thousands of stars on a clear night. It is estimated that you can see between 2,500 to 5,000, even 10,000, stars in the sky with the naked eye if you have good vision and it is completely dark. You could also see the Milky Way Galaxy very clearly and easily, as well as the Andromeda Galaxy, meteors, comets, satellites, not to mention the most spectacular aurora borealis that you can see anywhere on earth. That certainly beats the 14 stars and 3 planets that you can see with the naked eye on a clear night here in Dallas, Texas, where I live now.
Milky way sky on dark background, and a lot of stars. Asset id: 2524020369 by MR.PRAWET THADTHIAM
On one occasion I was standing guard outside the camp. We were pretending that we were at war with the Soviet Union. It was minus 40 degrees, and they forgot about me. I stood there alone in the darkness and the extreme cold for more than three hours. This was considered dangerous. The rule was no more than one hour out in the cold at a time. Once they discovered that I had been there for more than three hours they came to get me, and they apologized profusely. They were happy that I was not hurt. However, I did not mind, because my night sky view was spectacular. The night sky was so spectacular, it was to die for.
If it is cloudy and you are far from any civilization it may be pitch black in the afternoon. Even if it is not cloudy but the moon is not out it will be pitch black later in the afternoon. In addition, the air is very clear during the polar night, because the cold sunless Arctic air often contains almost no moisture and the visibility stretches for 100 miles. If you want to remain unseen in this situation it is very important to understand that even the tiniest light will be very visible, far away. Our platoon did an experiment. Someone lit a cigarette about one mile away and we could very easily see the bright cigarette even through the forest. The lesson was, No Cigarettes, and No lights!
Aurora Borealis are often spectacular in the polar regions, especially during the polar night. Asset id: 2499746583 by HappyVibeArt
I consider this a super fact because the polar night is a surprising phenomenon to those who do not know much about the arctic and my claims above are true and important since the polar regions are large and under threat from climate change / global warming. The polar regions and thereby the polar night also cover an area that is not small, and four million people live there.
The Arctic Circle, at roughly 66.5° north, is a commonly-accepted boundary of the Arctic waters and lands. CIA World Fact Book, Public domain, via Wikimedia Commons.
The Midnight Sun
I can add that in the summer (northern hemisphere) you have the opposite phenomenon with the midnight sun. Just like the polar night can cause people to lose track of time so can the midnight sun. When we visited northern Sweden with our niece Jessica for my brother’s wedding, we had what is called midnight sun. Jessica was nine years old at the time. A couple of hours after we had gone to sleep Jessica woke me up “wake up Thomas, it is time to go out and play”. I protested, no it is not, it is one a clock at night and we are going to sleep. Jessica protested, she said, “No the sun is up, it is morning it is time to play”.
So, I said “Jessica, let me explain something to you. This is northern Sweden in June and here the sun is up in the middle of the night, and we are not going outside to play in the middle of the night.” After that my wife went out to play with Jessica, but I refused to go out and play at one o clock at night.
Ice Hotel Photos
Finally, I just wanted to include a few of my photos from the Ice Hotel, just for fun.
Our son David with one of the kick sleds called “spark”.This is a photo of the ice instruments standing on the ice stage.We are going on a dogsled tour. The ice theater is in the background, and you can see part of the ice hotel on the right.You can see ten dogs and the sled with us on top of it. On the left is a kåta, a movable Sami structure (indigenous arctic Scandinavian people). It is like a Tipi.
The Greatest Intellectual Achievement of the human race is arguably the Standard Model of Elementary Particles. The Standard Model consists of Special Relativity, Quantum Physics, Noether’s theorem and gauge theories, Quantum Electrodynamics, Quantum Chromodynamics, and a framework for all elementary particles, and more. It is a towering achievement of physics that was created by thousands of geniuses over a period of several decades. It is the theory of almost everything.
Despite that fact it is not getting a lot of respect. Everyone is just trying to find something wrong with it. The reason is that as soon as it was created people realized that something was wrong with it. It could not be reconciled with General Relativity. Something was missing. So, finding out what is wrong with it or what is missing has been a top priority for physics for several decades. The book “The Theory of Almost Everything” by Robert Oerter is a very interesting book covering the standard model, its components, its history, and what could be missing. It contains a few formulas but other than that it is mostly readable to laymen.
Book Formats for The Theory of Almost Everything
The Theory of Almost Everything: The Standard Model, the Unsung Triumph of Modern Physics by Robert Oerter comes in three formats. I bought the hardback format.
Hardcover – Pi Press (July 22, 2005), ISBN-10 : 0132366789, ISBN-13 : 978-0132366786, 336 pages, item weight : 1.2 pounds, dimensions : 6.37 x 1.11 x 9.3 inches, it costs $35.08 on US Amazon. Click here to order it from Amazon.com.
Paperback – Penguin Publishing Group (September 26, 2006), ISBN-10 : 0452287863, ISBN-13 : 978-0452287860, 336 pages, item weight : 10.8 ounces, dimensions : 5.51 x 0.81 x 8.34 inches, it costs $16.99 on US Amazon. Click here to order it from Amazon.com.
Kindle – Publisher : Plume (September 26, 2006), ASIN : B002LLCHV6, ISBN-13 : 978-1101126745, 348 pages, it costs $6.99 on US Amazon. Click here to order it from Amazon.com.
Front cover of The Theory of Almost Everything: The Standard Model, the Unsung Triumph of Modern Physics by Robert Oerter. Click on the image to go to the Amazon page for the hardcover version of the book.
Amazon’s Description of The Theory of Almost Everything
There are two scientific theories that, taken together, explain the entire universe. The first, which describes the force of gravity, is widely known: Einstein’s General Theory of Relativity. But the theory that explains everything else—the Standard Model of Elementary Particles—is virtually unknown among the general public.
In The Theory of Almost Everything, Robert Oerter shows how what were once thought to be separate forces of nature were combined into a single theory by some of the most brilliant minds of the twentieth century. Rich with accessible analogies and lucid prose, The Theory of Almost Everything celebrates a heretofore unsung achievement in human knowledge—and reveals the sublime structure that underlies the world as we know it.
Below is my full length giant review of The Theory of Almost Everything. Unless you are really interested, I suggest you read the somewhat shorter Amazon version by clicking the link above.
An introduction to the greatest intellectual achievement of the Human Race
The public has to a large extent missed the greatest scientific revolution in the history of the human race because mainstream media has largely ignored this breakthrough, despite the fact that the Nobel Prize committee has been raining Nobel Prizes over it. In the 1970’s a theory that explained, at the deepest level, nearly all of the phenomena that rule our daily lives came into existence. The theory called “The Standard Model of Elementary Particles” is a set of “Relativistic Quantum Field Theories” that explains how elementary particles behave, which elementary particles there are, and why they have the properties they have, for example, isospin, spin, charge, color charge, flavor, even mass, or mass relations in many cases.
The theory explains how all of the fundamental forces in nature work except gravity. The theory describes how the elementary particles interact; decay, how long they are expected to exist, and how they combine into other subatomic particles. The theory uses only 18 adjustable parameters to accomplish all of this.
Close up illustration of atomic particle for nuclear energy imagery. From iStock photos.
In the extension the theory thus explains how nucleons and atoms are formed and what properties the atoms will have, and how molecules will form and what properties molecules will have, their chemical reactions, and what elasticity, electric conductivity, heat conductivity, color, hardness, texture, etc. any material will possess. In the extension it explains why mass and matter exist, how the sun and the stars work, and the theory is therefore the ultimate basis of all other science. It also provides a formula, or an equation of almost everything.
Best of all it has been thoroughly verified experimentally, in fact the predictions the theory has made have been confirmed with such stunning accuracy and precision that it could be considered the most successful scientific theory ever. A theory that successfully unites all physics and basically all of human knowledge of the Universe into one single theory has never before existed.
However, “The Standard Model” does not incorporate gravity and the general theory of relativity, and cannot explain dark energy, dark matter and why neutrinos have mass. Therefore, almost as soon as the theory came into existence physicists started looking for the next theory that would finish what the “The Standard Model” did not finish.
Example of such theories are GUT theories, SO(5), SO(10), string theories (abandoned), super string theories, and M-theories. Even though those new theories are extremely interesting they have not been verified or able to predict anything. In comparison with the “Standard Model”; super string theories, grand unified theories, chaos theories, you name it, are essentially nothing, but are still better known. Hopefully this will change in the future, either because the Standard Model gets the respect it deserves, or because a more complete theory can be verified.
About the book
This book explains to the layman what the “Standard Model” is and how it came into existence. The book is by no means a perfect book. I think there are several problems with the book. However, I decided not to take off any star because there are very few books written for science interested non-physicists that explain the “Standard Model of Elementary Particles”. Dr. Oerter deserves five stars just for his decent attempt at doing so. I find Dr. Oerter to be a good writer and popularizer. I don’t think he is as good as Isaac Asimov, or Carl Sagan, but close, and he is writing on a much more complex topic then, for example, Carl Sagan did.
I studied physics as an engineering student, and I could understand most of text (but not every detail regarding everything). However, I believe anyone who is somewhat familiar with science, especially physics and math, can understand most of this book. For me more diagrams and more equations would have helped. For readers without much background in physics more and better diagrams would definitely have helped. Dr. Oerter came close to writing a good book for the layman, but the book was still lacking in certain aspects. In the remainder of the review, I will give a brief synopsis for each chapter and present my opinions and reflections on each chapter. In a sense I have written a short review for every chapter. My intent is to both tell you what the book is about and give my opinions on the different sections of the book.
Chapter 1: The first unifications
In Chapter one Oerter gives an interesting overview of the history of physics. Physics has typically been divided up into many fields. New discoveries have led to either new sub disciplines or the merging of existing sub disciplines (unifications). Nineteenth century physics was divided into many sub disciplines.
Dynamics (the laws of motion)
Thermodynamics (the laws of temperature, heat and energy)
Waves (oscillations in water, air, and solids)
Optics
Electricity
Magnetism
However, because of the atomic hypothesis, thermodynamics and wave mechanics were swallowed up by dynamics. For example, temperature and heat were now explained in terms of atomic and molecular motion. The theory of electromagnetic fields subsumed optics, electricity, and magnetism (light is an electromagnetic wave). All of physics, it seemed, could be explained in terms of particles (atoms) and fields. New discoveries would alter the picture once again and the old field theories had to be abandoned, and the laws of classical mechanics (dynamics) had to be altered.
Finally, the physicists were able to come up with a unified theory that explained almost all of physics and in the extension all of science, the standard model of elementary particles. This chapter was very basic and not difficult to understand. I think his approach to give an overview of physics was both unique and enlightening. His description of how physics and our understanding of the Universe went through periods when our knowledge expanded and gave rise to new fields and due to new discoveries, that led to a deeper understanding resulted in the merging of these fields. So, in summary more knowledge lead to more fields, then deeper understanding united them. This went back and forth a few times. Finally, we have a unified theory of almost everything, the Standard Model (if we exclude the General theory of relativity).
Chapter 2: Einstein’s relativity and Noether’s theorem
Even though the book is a Physics book, I think it is also a book on Philosophy. The way I see it Physics is in a sense both Science and Philosophy, the kind of Philosophy that can be falsified, verified and proven wrong or correct. Let me explain what I mean by telling you about Noether’s theorem. Noether’s theorem states that whenever a theory is invariant under a continuous symmetry, there will be a conserved quantity. As an example of what a continuous symmetry is, is the following: any physical experiment that is performed at a certain time will have the same result if it is performed exactly the same way a certain time later. That seemingly self-evident observation means that Energy is conserved.
Another example is any physical experiment that is performed at a certain place will have the same result if it is performed exactly the same way somewhere else. That seemingly self-evident observation means that momentum is conserved. Let me add that “exactly the same way” really means that! Gravity, other forces, differences in light, or anything else cannot be different in the second experiment. The only thing allowed to be different is the position “x” (if that is our symmetry variable). That is what a continuous symmetry means, changing just one thing, and everything stays the same.
Noether’s theorem has been the guiding principle behind the standard model, and it is used to find conservation laws where symmetries are found, and it is used to find symmetries where conservation laws are found. It is a spontaneous symmetry brake that allows the Higgs Boson to give all other particles their mass (excepting mass less particles). This is the reason that matter and everything in our Universe exists. The Higgs Boson is also called the God particle. So, Noether’s theorem is both very useful in a practical sense and deeply philosophical at the same time. In addition to Noether’s theorem the standard model is built upon the special theory of relativity and a modern formulation of quantum mechanics (Quantum field theory), QED, QCD, as well as some discoveries regarding elementary particles. I can add that Noether’s theorem was formulated by a Jewish woman, Emmily Noether, who could not get a job in academia because she was a woman. This theorem is one of those very important but mostly unknown discoveries, like the invention of paper by the Chinese Tsai Lun.
Oerter does not attempt to explain the special theory of relativity; however, he tries to give the reader an idea of what it is. The problem with his approach is that he gives the reader just enough information to enable the observant reader to come up with the apparent paradoxes within the special theory of relativity, but not enough information to help the reader to easily resolve them. He also confuses the reader by not distinguishing between rest mass and relativistic mass. The observant reader will think that he is contradicting himself. The term relativistic mass is the total mass and the total quantity of energy in a body. The rest-mass is the mass of the body when it is not moving. The formula E = mc^2 is always true, when it refers to relativistic mass, which is why we talk about an energy/mass equivalence. The other more complex formula Oerter presents refers to rest mass. There is no such thing as an energy/rest mass equivalence (except at speed 0) but that is what the reader who is not already familiar with the subject will end up believing.
Another mistake Oerter does is in regard to the fact that the speed of clocks will be measured differently in different reference frames. On page 35 last paragraph Oerter writes “Here, we have an apparent paradox: If each reference frame sees the other as slowed down, whose clock will be ahead when the passengers leave the train?” Then he implies that the paradox has to be solved by incorporating the General theory of relativity. Even though that may be how it was first solved, you can solve this form of the so called “Twin Paradox” and other similar paradoxes from within the framework of the special theory of relativity itself. So even though I enjoyed reading about Nother’s theorem and still think this chapter could use some improvement.
Chapter 3: (The End of the World as we know it) + Chapter 4: (Improbabilities)
Oerter explains Quantum Physics in a very typical manner, and he mostly avoids making it look weirder than it actually is which he should be commended for (that is not true for every author). However, there is one thing that all Physicists seem to do when they explain Quantum Physics to the layman which annoys me greatly. The matter waves (or quantum fields) in Quantum Physics are quite strange entities. The reason they are so strange is because they do not exist in a real sense, they are more correctly stated mathematical abstractions. Oerter states this clearly, which is good.
However, he then goes on to mention De Witts’ idea about multiple Universes without acknowledging that these “bizarre solutions” to various Quantum Wave conundrums are completely unnecessary. So, to some extent he is still making Quantum Physics appear weirder then it is (but I have seen worse). Well, OK, Quantum Physics is weird, but we don’t need to make it seem even weirder.
After giving a background to the special theory of relativity and Quantum Physics, Oerter continues explaining relativistic Quantum Physics including the fantastic prediction you get when you combine the special theory of relativity with Quantum Physics; that for every particle there is a twin particle with exactly the same mass, and spin, but opposite charge and isospin. These particles were called anti-particles and until they were actually found physicists tried to get rid of them from the theory. However, the combination of the special theory of relativity and Quantum Physics would lead not only to much better explanation for such things as the radiation and light spectrum and the properties of atoms, it would also lead to new discoveries. This is what is referred to as Relativistic Quantum Mechanics.
Chapter 5: The Bizarre Reality of QED
Richard Feynman came up with a new representation of relativistic quantum physics for electrons that did not use waves, called Quantum Electro Dynamics (QED). This was one of the first steps towards the standard model. Instead of viewing electrons as particles governed by waves, Feynman viewed electrons as particles guided by fields consisting of all possible paths and their probabilities. He used the two-slit experiment as a guide when formulating the equations for the probabilities of the paths for the electrons (and in the extension may other particles). When he summed up all the possible paths and compared with the old Quantum Mechanics (Wave Mechanics) he got the same answer as Quantum Mechanics in every case. In fact, his new approach was able to explain and calculate phenomena’s like the electrons spin and the fine structure constant that Quantum Mechanics (Wave Mechanics) could not explain properly, and his approach also would prove crucial for the development of Relativistic Quantum Field Theory.
So, in summary, first came Quantum Mechanics, then Relativistic Quantum Mechanics, and then QED and Relativistic Quantum Field Theory. I can add that this chapter also explains Feynman diagrams and an infinity problem that cropped up. The three infinities that cropped up corresponded to the electron’s mass, the photon’s mass, and the electron’s charge. However, the problems with these infinitives were solved using a normalization process that is also explained in this chapter. I can add that I think QED probably seems less strange to laymen then Wave Mechanics because it is easier to visualize the probabilities of possible paths as compared to waves that do not even exist, even though their “amplitude squares” represents something real. This chapter was probably one of the harder chapters to understand (for those who know nothing about QED). This chapter could really have been made better by using many more diagrams and figures. Again, I am not going to knock a star for that because the book is overall so unique and important.
Chapter 6: Feynman Particles, Schwinger Fields
Chapter 6 was a short but interesting chapter. Julian Schwinger took a different approach to QED than Feynman; he sorts of invented a new wave mechanics, in which a quantum field can be pictured as a quantum harmonic oscillator at each point in space. Even though the two approaches used different models Freeman Dyson proved in 1949 that Schwinger’s field theory point of view and Feynman’s sum-over-all-paths approach were in practice identical. However, the two approaches are useful for different things and form the basis of Quantum Field Theory. QED and Quantum Field Theory eliminate the distinction of particle and field and in a sense removed the conundrum of the particle and wave duality. In the nineteenth century light was an electromagnetic wave (well it still is) and in the old Quantum Physics it was both a wave and a particle, however, in Relativistic Quantum Field Theory it is something completely new-a quantum field, neither a particle nor a wave, but an entity with the aspects of both.
Chapter 7: Welcome to the Subatomic Zoo
In this chapter Oerter describes the history of the “strong nuclear force” and the “weak nuclear force” and the subatomic zoo that later emerged. There are four fundamental forces of nature, electromagnetism, gravity, and the “strong nuclear force” and the “weak nuclear force”. The two latter fundamental forces were not known until the 1930’s. The studies of these two new forces led to the predictions and discoveries of new elementary particles. One of these was the pion, however, when the physicists looked for this particle in the cosmic background radiation, they found an elementary particle that was similar to the pion but had the wrong mass.
After some confusion it became clear that it was not a pion but a new never foreseen particle that was named the meson. This was a problem because it was a new entity which the existing physics theories could not explain. However, it got worse. More elementary particles were discovered in the 1940’s 1950’s and the 1960’s. Our Universe turned out to be a lot stranger than people thought, and people started talking about the subatomic zoo. These newly discovered elementary would remain big mysteries until the event of the Standard Model in 1974. This chapter was pretty straight forward and easy to understand. Oerter does an excellent job in making this history interesting and entertaining to the reader and the chapter also contains some humor.
Chapter 8: The Color of Quarks
In the 1960’s physics had become ugly because of the subatomic zoo. Murray Gell-Mann and Yuval Neeman suggested a periodic table for elementary particles (like there is a periodic table for the elements). This periodic table was referred to the eightfold way. The eightfold way was also referred to as the SU(3) theory. It led to the discovery of an elementary particle that was even more fundamental than the known elementary particles, the Quark. It was soon established that there were two kinds of fundamental elementary particles: leptons and Quarks, in addition to the Bosons. Let me explain the details. There are elementary particles with whole number spin, and they are called Boson’s, and there are elementary particles with half number spin called Fermions.
The Pauli Exclusion Principle (that no two particles can occupy the same state) applies to Fermions but not to Bosons and therefore the two different types of particles behave very differently and follow different kinds of statistical rules (Bose-Einstein statistics versus Fermi-Dirac statistics). All force carriers are Boson’s while some Fermions are used to build “normal matter”. Examples of Bosons are the photon, gluons, W and Z Boson, mesons, the Higgs Boson (the God particle). The Fermions come in three families, each with four particles and their anti-particle.
The proton and neutron each consist of three quarks. Protons consist of two up quarks and one down quark. Neutrons consist of two down quarks and one up quark. Both protons and neutrons have a net white charge. The yellow squiggly lines are gluons transporting color charge between the quarks. Asset id: 2333679305 by KRPD.
Electron / positron
Neutrino / anti-neutrino
Up quark / anti up quark
Down quark / anti down quark
muon / anti-muon
Mu Neutrino / anti-mu-neutrino
Charm quark / anti charm quark
Strange quark / anti strange quark
tau / anti-tau
Tau Neutrino / anti-tau-neutrino
Top quark / anti top quark
Bottom quark / anti bottom quark
The quarks can be used to build other particles, but leptons cannot. For example, a quark and an anti-quark pair form a particle called a meson (there are many kinds of mesons). A triplet of quarks is called a Baryon. An example of a baryon is the proton which consists of two up quarks and one down quark. Another example is the neutron which consists of one up quark and two down quarks. So just like electrons, protons and neutrons build atoms; the quarks build other elementary particles, for example, protons. As mentioned, the six flavors of Quarks are up, down, strange, charm, top and bottom.
However, the Quarks also have colors (well they are not real colors), red, blue and green which sort of correspond to the three kinds of charges for the strong nuclear force. Based on this new model a new Quantum Field Theory called Quantum-Chromodynamics (QCD) was created which together with QED would form the basis of “The Standard Model of Elementary Particles”. This was also a very straight forward chapter that was both interesting and not very difficult to understand. Again, Oerter makes the story interesting and captivating. This is perhaps the most interesting chapter in the book.
To learn more about Protons, Neutrons, Quarks, Gluons, Color Charges, and Quantum Chromodynamics you can watch this 10 minute video below.
Chapter 9: The Weakest Link
Despite the eightfold way, the Quarks, QED and QCD, all was still not well. The Weak Nuclear force was still not fully understood. Martinus Veltman, Steven Weinberg, Abdus Salam, and Sheldon Glashow were the people chiefly responsible for developing a theory for the weak nuclear force. It involved W+, W- and Z0 Bosons and something called spontaneous symmetry breaking.
These theories in turn led to something called the Higgs field and the so called Higgs particle or Higgs Boson (named after Peter Higgs who first introduced the concept of spontaneous symmetry breaking in elementary particle theory). The Higgs particle provided the physics community with a very nice surprise. The Higgs particle gives electrons (and other leptons) and the Quarks their mass. Unexpectedly we thus got an explanation as to why many elementary particles have mass and therefore why matter exists. This is why the Higgs Boson is often referred to as the God particle. It just showed up because of the theories explaining the weak force and turned out to be what created our Universe by giving the elementary particles their mass.
There was just one problem. The Higgs Boson had not yet been found when this book was written. Once the Large Hadron Collider (LHC) came online it became possible to find the Higgs Boson. This final touch to the Standard Model was the one that was the most difficult to grasp. I had a hard time understanding what spontaneous symmetry break really was, and the Mexican hat potential, etc. I think that Oerter needs to look over this chapter and find a different approach to explaining spontaneous symmetry break. I think that Oerter actually sorts of “gave up” at this point. This topic is too abstract for the layman so instead of making a good effort explaining spontaneous symmetry.
Collision of Particles in the Abstract Collider. From iStock photos.
Chapter 10: The Standard Model at Last
The standard model is built from relativistic quantum field theory, specifically QED and QCD. In chapter 9 QED was incorporated into electroweak theory which led to the Higgs Boson etc. QED is interwoven together with QCD to create a single theory whose essential elements can be written in a single equation.
Yes, that is right; an equation of everything, or almost everything. This equation is stated on 207 in this chapter. The equation over all equations that there ever was. You should buy this book just to look at it.
The Langrangian function that summarizes all of the propagators and interactions in the standard model.
The equation of everything is not as complicated as you may think. It is a Lagrangian function that summarizes all propagators and interactions, and it contains 18 adjustable numerical parameters. I admit that I don’t understand the equation fully, but Oerter explains the parameters and as mentioned it is just a big Lagrange function. As Oerter states “this equation is the simplicity at the bottom of it all, the ultimate source of all complex behavior that we see in the physical world; atoms, molecules, solids, liquids, gases, rocks, plants and animals”.
Oerter also discusses the birth of the Universe in the context of the Standard Model. In my opinion this was a very cool chapter, and Oerter does a good job at exciting the reader in this chapter. Naturally the equation of everything is a little bit difficult to understand and if you don’t know what a differential equation is you can forget about it. However, understanding the equation of everything is not important. The main point of this chapter is that there is such an equation.
Chapter 11: The Edge of Physics, Chapter 12: New Dimensions
As Oerter states in chapter 11 “The standard model is by far the most successful scientific theory ever. Not only have some of its predictions been confirmed to spectacular precision, one part in 10 billion for the electron magnetic moment, but the range of application of the theory is unparalleled. From the behavior of quarks inside the proton to the behavior of galactic magnetic fields, the Standard Model works across the entire range of human experience. Accomplishing this with merely 18 adjustable parameters is an unprecedented accomplishment, making the Standard Model truly a capstone of twentieth-century science.” However, this is not the end of physics. Gravity is explained by the General Theory of Relativity but is not incorporated into the Standard Model.
There is also dark matter and dark energy which is not part of the Standard Model. The neutrinos seem to have mass; however, they are predicted to have no mass in the Standard Model. In addition, it would be nicer to have fewer adjustable parameters than 18. Is there may be a better theory? In chapter 12 Oerter is discussing Grand Unified Theories (GUT), or SO(5) and SO(10) theories as well as super string theories, and M-theories. These are theories that might be able to do everything the Standard Model can do plus what it cannot do. However, none of these theories have ever predicted anything, so unlike the Standard Model they are speculation. There is some controversy regarding these issues, and I think Oerter might have been a tiny bit biased against super string theory here. However, he still explains what super string theory is about pretty well.
Final Conclusion and Recommendation
I highly recommend this book for anyone who wants to understand something about our world and the Universe. However, don’t expect to understand everything, it is not written so that you can. I wish Physicists would become a little better at explaining these matters to the layman using nice descriptive pictures and a little bit of math too (don’t assume math is always bad). I once read a 30 page long Swedish book on the special theory of relativity that successfully explained the kinematics, dynamics, and magnetism in relativity to your average high school kid. The Lorenz transforms, formulas for acceleration, E = mc² and magnetism were derived using simple algebra and a tiny bit of calculus at one point. That is the way these kinds of books should be written, but I have seen this only once in my life. Excluding this single example (the Swedish book), Oerter’s book is one of the best books on Physics for the layman that I have ever read.
Back cover of The Theory of Almost Everything: The Standard Model, the Unsung Triumph of Modern Physics by Robert Oerter. Click on the image to go to the Amazon page for the paperback version of the book.
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