How much background do you have in the relevant nerdy stuff though?
[Edit: Oops, I misread the above question as asking how much background you have to have to be able to understand this stuff. I certainly don’t have much background in physics myself. What I wrote below is true regardless, though, so I’m leaving the comment as it is.]
You have to have a deep mathematical grasp of quantum theory, both formal and intuitive, before you can even start to understand what the controversial issues such as MWI really are about, let alone to form any reasonably grounded opinions about them. Otherwise, you can only fool yourself that you understand anything about these topics, and any beliefs you form about them can be based only on faith in authority or arbitrary whim, not sound reasoning.
The same holds for most other topics in physics. In some areas for science, non-technical pop-science explanations can lead to correct understanding, but in physics, they are worse than useless. (The reason why physicists often display a positive view of pop-science physics books even when they don’t stand to profit from their sales is that they raise their status.)
I think that’s much too egalitarian. As best as I can tell people vary tremendously in their ability and inclination to grasp certain topics with minimal preparation. What you say is true of the majority but not of everyone. The value to the student of popular accounts also varies tremendously. What you say seems to be true if you pair the worst students with the worst books.
Hm.. this is the second time today that I posted a comment based on a misreading (see the correction above). Makes me wonder about the quality of the work I did during the rest of the day.
Regarding the pop-science approach to physics, I read a lot of such books as a teenager. Since then, I’ve studied several areas of physics with real mathematical rigor, some in university courses and others just out of curiosity, and in retrospect I must say that the popular books had failed to give me any accurate understanding whatsoever. All I got was either confusion or a somewhat coherent but in fact completely misleading picture of the real thing.
The only cases where physical theories can be explained with some accuracy in layman non-mathematical terms are those that deal with people’s everyday experiences, and don’t involve any phenomena that are outside of that. When it comes to relativity, quantum theory, cosmology, let alone more advanced and esoteric areas of modern physics, to me it seems impossible to convey any accurate understanding without the mathematics. I have yet to see a pop-science book that would successfully do it, no matter how smart the reader. (I liked this recent LW comment made by a physics about this topic.)
If you subscribe to the view that an illusion of understanding is worse than nothing at all (as I do), it’s really hard to find anything positive to say about pop-science physics books. Yet scientists will rarely criticize them, sometimes because they profit by writing them (or hope to do so one day), but more often because they raise the status of physicists and scientists in general in the eyes of the general public. Ultimately, these works allow readers to signal their smarts and sophistication, famous physicists to make lots of money, and other physicists to enjoy the high status brought this way to their profession, but certainly nobody gains any (scientific) knowledge in the process.
A couple of my own experiences. As a kid I devoured Lewis Carroll Epstein’s Thinking Physics, which so easy and fun and filled with pictures it is like a comic book, and I devoured it like one (though I always—always—answered each puzzle before seeing his explanation). Talk about popularizations, this was a frickin comic book. I think it took a week of afternoons to get through. In retrospect I don’t think it misled me. On the contrary, I think I learned a lot from it. My major as an undergraduate was mathematics but I took two semesters of physics along with the regular physics majors in my freshman year, classical mechanics and electromagnetism, so I think I am in a position to judge that book in light of a “real” education.
Second experience. I never took a course in special or general relativity per se, but I touched on both in a graduate course on differential geometry (I think it was). In light of my graduate level understanding of the mathematics of spacetime, I would not say that I had been misled by popularizations of it (though I could not at this point name you which exact popularizations of it I read—Epstein wrote one but I never read it). It has been many years but what I learned in that graduate course regarding special relativity was a certain metric, a simple, trivial metric, called I think minkowski metric (it’s been a while). That metric made the geometric aspects of special relativity utterly trivial, all the familiar amazing geometric predictions of SR regarding lengths and timing just fell right out of it, everything, the flashlight on the train, everything. It was a course on geometry so it didn’t integrate the minkowski geometry with the laws of mechanics, force, acceleration, etc. But my point is this: it did not reveal the popularizations that I had read as a teenager to be a load of bull. On the contrary, it confirmed and completed them.
To compare, I have read some of the “best” popularizations of string theory. I do not feel very enlightened by them. There is no illusion of understanding because there is no belief that I understand. In contrast, I find Feynman’s QED (the thin book, not the theory) enlightening—as far as it goes. The book has modest goals. It does not pretend to arm you with the ability to carry out real-world predictions. So I find popular books to vary tremendously in their ability to convey knowledge.
erratio:
[Edit: Oops, I misread the above question as asking how much background you have to have to be able to understand this stuff. I certainly don’t have much background in physics myself. What I wrote below is true regardless, though, so I’m leaving the comment as it is.]
You have to have a deep mathematical grasp of quantum theory, both formal and intuitive, before you can even start to understand what the controversial issues such as MWI really are about, let alone to form any reasonably grounded opinions about them. Otherwise, you can only fool yourself that you understand anything about these topics, and any beliefs you form about them can be based only on faith in authority or arbitrary whim, not sound reasoning.
The same holds for most other topics in physics. In some areas for science, non-technical pop-science explanations can lead to correct understanding, but in physics, they are worse than useless. (The reason why physicists often display a positive view of pop-science physics books even when they don’t stand to profit from their sales is that they raise their status.)
I think that’s much too egalitarian. As best as I can tell people vary tremendously in their ability and inclination to grasp certain topics with minimal preparation. What you say is true of the majority but not of everyone. The value to the student of popular accounts also varies tremendously. What you say seems to be true if you pair the worst students with the worst books.
Hm.. this is the second time today that I posted a comment based on a misreading (see the correction above). Makes me wonder about the quality of the work I did during the rest of the day.
Regarding the pop-science approach to physics, I read a lot of such books as a teenager. Since then, I’ve studied several areas of physics with real mathematical rigor, some in university courses and others just out of curiosity, and in retrospect I must say that the popular books had failed to give me any accurate understanding whatsoever. All I got was either confusion or a somewhat coherent but in fact completely misleading picture of the real thing.
The only cases where physical theories can be explained with some accuracy in layman non-mathematical terms are those that deal with people’s everyday experiences, and don’t involve any phenomena that are outside of that. When it comes to relativity, quantum theory, cosmology, let alone more advanced and esoteric areas of modern physics, to me it seems impossible to convey any accurate understanding without the mathematics. I have yet to see a pop-science book that would successfully do it, no matter how smart the reader. (I liked this recent LW comment made by a physics about this topic.)
If you subscribe to the view that an illusion of understanding is worse than nothing at all (as I do), it’s really hard to find anything positive to say about pop-science physics books. Yet scientists will rarely criticize them, sometimes because they profit by writing them (or hope to do so one day), but more often because they raise the status of physicists and scientists in general in the eyes of the general public. Ultimately, these works allow readers to signal their smarts and sophistication, famous physicists to make lots of money, and other physicists to enjoy the high status brought this way to their profession, but certainly nobody gains any (scientific) knowledge in the process.
A couple of my own experiences. As a kid I devoured Lewis Carroll Epstein’s Thinking Physics, which so easy and fun and filled with pictures it is like a comic book, and I devoured it like one (though I always—always—answered each puzzle before seeing his explanation). Talk about popularizations, this was a frickin comic book. I think it took a week of afternoons to get through. In retrospect I don’t think it misled me. On the contrary, I think I learned a lot from it. My major as an undergraduate was mathematics but I took two semesters of physics along with the regular physics majors in my freshman year, classical mechanics and electromagnetism, so I think I am in a position to judge that book in light of a “real” education.
Second experience. I never took a course in special or general relativity per se, but I touched on both in a graduate course on differential geometry (I think it was). In light of my graduate level understanding of the mathematics of spacetime, I would not say that I had been misled by popularizations of it (though I could not at this point name you which exact popularizations of it I read—Epstein wrote one but I never read it). It has been many years but what I learned in that graduate course regarding special relativity was a certain metric, a simple, trivial metric, called I think minkowski metric (it’s been a while). That metric made the geometric aspects of special relativity utterly trivial, all the familiar amazing geometric predictions of SR regarding lengths and timing just fell right out of it, everything, the flashlight on the train, everything. It was a course on geometry so it didn’t integrate the minkowski geometry with the laws of mechanics, force, acceleration, etc. But my point is this: it did not reveal the popularizations that I had read as a teenager to be a load of bull. On the contrary, it confirmed and completed them.
To compare, I have read some of the “best” popularizations of string theory. I do not feel very enlightened by them. There is no illusion of understanding because there is no belief that I understand. In contrast, I find Feynman’s QED (the thin book, not the theory) enlightening—as far as it goes. The book has modest goals. It does not pretend to arm you with the ability to carry out real-world predictions. So I find popular books to vary tremendously in their ability to convey knowledge.