Introduction

The fact that we see massive, luminous stars which cannot be older than about 106 years tells us that stars must have been formed within the last million years. In association with these luminous young stars we often see some peculiar stars with emission lines, called the T Tauri stars (see Volume 1). These can therefore be assumed to be young stars also. They have lower luminosities and are more red than the massive O and B stars but are considerably more luminous than main sequence stars of the same color. Because of their lower luminosities they must have lower masses than the O and B stars. For the lower mass stars the contraction times are longer, as we have seen in Chapter 2, because these stars cannot radiate away the surplus gravitational energy as fast as the more luminous, massive stars. If these lower mass T Tauri stars were formed at the same time as their more massive associates they have not had enough time to contract to the main sequence during the main sequence lifetime of the massive stars. Lower mass stars must therefore still be in the contraction phase. It is then reasonable to assume that these T Tauri stars are young stars still in the contraction phase.

Both kinds of stars, the massive O main sequence stars and the less massive young T Tauri stars, appear in association with large dust complexes, i.e. regions of high density where many interstellar molecules are formed. It thus appears that new stars may be born in regions of high density interstellar material.

Introduction

Supersymmetry is the first real extension of space-time symmetry. It has given us great hope that we should be able to generalize ordinary geometry into a super-geometry and in this process obtain more unique and consistent models of physics. In some cases this has been achieved, but in most cases we still lack a natural and unique extention into a superspace.

The concept of superspace, i.e., a space with fermionic coordinates as well as bosonic coordinates, was introduced first in dual models by Montonen in an attempt to construct multiloops in the Ramond-Neveu-Schwarz model. This led eventually to the superconformal algebras and super-Riemannian spaces. When supersymmetric field theories were discovered, it was soon realized that a super-space is the natural space in which to describe these models. However, these descriptions, although in the end quite successful in establishing renormalization properties, always lacked a certain sense of naturalness. For each supermultiplet different ideas had to be used.

In supergravity theories, being extensions of truly geometric theories, the hopes were even higher and the results more discouraging. So far one has only managed to write superspace actions for the N=1 theory, and none of them is a natural extension of the Hilbert action. Superspace techniques were though eventually useful in describing the classical theories and led to the really important result that any supergravity theory has infinitely many possible counterterms.

This essay is dedicated to Murray Gell-Mann upon his sixtieth birthday. I assume he will be particularly gratified to read that the inspiration for a new look at the 1964 work came during a visit to the College of Judea and Samaria at Ariel and to the “Nir” Yeshiva in Hebron. Also, while travelling in the area, I came across one of the five types of pheasant-like birds (Hebrew “HoGLaH”) that he had enumerated to me on our 1967 tour of the Negev. There were no Malayalam-speaking immigrant Cochin Jews around this time as there had been at Nabatean Mamshit (Roman “Mempsis”, and in Arabic “Kurnub”) but I did visit Tat-speaking Daghestani “mountain Jews” in the Dothan valley in northern Shomron (Samaria). It is interesting that they have become important producers of goose-liver which is exported to France. Aside from Tat proper, they use “Judeo-Tat”, a Tat-based “Yiddish”.

QUANTUM FIELD THEORY, STRONG INTERACTIONS AND SU(3) IN 1964

In 1963–65, I was at Caltech as Murray's guest. We had met at CERN during the 1962 conference, at the end of the rapporteur session on strange particles. I have related elsewhere the events of that day and Gerson Goldhaber has added a witness-participant account. Anyhow, the outcome was a two-year stay at Caltech and the beginning of a lasting friendship.

ABSTRACT

Recently Friedberg, Lee and Ren have pointed out that at low density the ideal charged boson system turns out not to be a superconductor, but becomes a type II superconductor at high density. This conclusion differs from the well-known Schafroth solution of superconductivity at any density for the same problem. Schafroth's analysis is found to contain a mistake due to the neglect of the electrostatic exchange energy Eex. Based on the Schafroth solution, Eex is shown to be +∞ in the normal phase, but 0 in the condensed phase (at T = 0). Of course, the correct solution has to give a finite Eex.

This research was supported in part by the U.S. Department of Energy.

SCHAFROTH'S SOLUTION

Schafroth's superconductivity solution of an ideal charged boson system published 35 years ago has always been considered to be the definitive work, comparable in depth to the analysis made by Landau on the diamagnetism of an ideal charged fermion system. However, recently it was found that the Schafroth solution contains a serious mistake due to the neglect of the electrostatic exchange energy Eex. It turns out that based on the Schafroth solution, Eex is +∞ in the normal phase, but 0 in the condensed phase (at T = 0). Of course, the correct solution has to give a finite Eex.

For ideal charged particles, bosons or fermions, there is only the electromagnetic interaction.

ABSTRACT

We study the algebra of normal ordered and reparametrization invariant operators of the open bosonic string field theory. These, besides the Poincaré group generators, include the ghost number operator and two translationally invariant symmetric second-rank space-time tensors. The BRST operator of string field theory is the trace of the fermionic one, and the second is the BRST transform of the former. Their algebra closes only when certain Lorentz non-invariant projections over the fermionic tensor are taken. There are many inequivalent such algebras, corresponding to manifest Lorentz invariance in lower dimensions. Some of these contain, besides the Lorentz invariant BRST, another nilpotent operator. We provide an example where Lorentz invariance is manifest in 1 + 1 dimensions.

I recall that the first time Murray asked me to come and talk at Caltech sixteen years ago, the subject was one we both shared an interest in: covariant string field theory. After all these years, things have not changed so much as to force me to change the subject matter: Plus ça change, plus c'est la même chose. I recall Murray inquiring at the time as to the underlying principle behind string theory. His penetrating question is still valid and unanswered today.

In a series of publications, we set about to list normal-ordered operators which are invariant under complex reparametrizations. In open string field theory, these include familiar operators such as the ghost number operator, the Poincaré generators, and the BRST charge.

I first met Murray Gell-Mann when he popped up in my office at the Institute for Advanced Study, and described to me the isospin-strangeness rule he had discovered. He pronounced my name correctly and interpreted its meaning correctly. That was September 1953.

The post-War decades have been the Golden Age of particle physics. Theory and experiment went hand in hand to make amazing advances. What we know now about the world of elementary particles is incredibly richer than what we did forty years ago, and we owe this to Murray above all. Looking beyond the Baroque period we are in now, I hope Murray's spirit will come back alive again.

Recently I have been taking a renewed interest in the BCS mechanism as a model for spontaneous generation of fermion mass and associated Goldstone (G) and Higgs (H) collective bosons. Here I mean by a BCS mechanism the formation of fermion pair condensates due to a short range attraction. In an idealized situation, this may be represented by a four-fermion interaction, and the dynamics is essentially determined by the properties of fermion bubble diagrams. A characteristic feature of the bubble approximation is that the Bogoliubov–Valatin (BV) fermion and the Higgs boson have the simple mass ratio 1:2. Such modes are known to exist in superconductors.

These low energy modes can be represented by an effective Ginzburg–Landau– Gell-Mann-Lévy Hamiltonian in which the boson self-coupling and the boson-fermion Yukawa coupling are related so as to satisfy the mass ratios.

I would like to correct a misrepresentation made by several of the preceding speakers. We are not celebrating the sixtieth anniversary of Murray's birthday. We are celebrating the sixtieth anniversary of his conception. His actual birthday is in September.

We are, of course, celebrating Murray Gell–Mann, whom I've known now since 1951. We joined the University of Chicago the same year, a few months apart. And before I go into the more scientific part of my lecture, I think you might be interested in the origin of the name “Murray.” Presumably it was, like some other first names, derived from a surname. And these, in turn, often come from geographical names, in the present case, from a Scottish province, “Muraih.” Already in 1203 we find a William de Moravia, and in 1317 an Orland de Morris, and in 1327, an Andrew Muraih. [This does not prove the point, because these family names could well have come from “Murie,” the Middle English form of Merry.] As a first name, it has also been surmised, as I see from a book by Partridge, Name This Child, that “Murray” comes from “Murrey” a word for dark red or eggplant colored, an adjective which in turn presumably comes from mulberry, in turn connected to maroon. Which brings us back to Murray's favorite color of corduroy jackets at the University of Chicago.

Now having explained the word Murray, I cannot refrain from giving you the origin of the name Gell–Mann.

It is an honor to have been selected among Murray's many friends and colleagues to speak to you this afternoon. No doubt I have been chosen because of the mathematical component present in high-energy theory today. Before concentrating on the interface of elementary particle physics and modern geometry, I'd like to record my own pleasure in knowing Murray this past decade. Perhaps it's just as well we didn't get acquainted earlier; I think he would have frightened me to death. You all are aware of Murray's great intellectual powers; but to me, equally amazing, is his enthusiasm for all creative endeavors, large and small. More than anyone, he firmly believes that the human mind and the human spirit can cure the ills of society. This birthday celebration expresses his personality in several ways. The diversity of topics reflects his many interests. And the theme stresses his positive view of the future.

Our charge was to pick some subject — mine is mathematics and physics — and discuss its present status and future prospects. Like twin stars, the two subjects have influenced each other greatly over the centuries, sometimes overlapping significantly, sometimes going their separate ways. In the fifties and sixties there was little contact — perhaps even some hostility. Physicists believed that too much mathematics hindered physical insight; some older ones still do. Mathematicians required more mathematical precision than physics deemed necessary and were developing abstract structures for their own sake.

In the summer of 1970 I attended as a graduate student from MPI Munich the Brandeis Summer School on Theoretical Physics at Brandeis University. Afterwards I drove in a car which I had to deliver eventually in Long Beach, California, throughout the United States. This trip was not only my first encounter with the magnificent sceneries of the United States. On a short stay at the Physics Center in Aspen, Colorado, I met in a discussion with colleagues on problems of broken scale invariance Murray Gell–Mann for the first time.

The year 1970 was an exciting one in particle physics. After several years of frustration and little progress in experimental studies, the observation of the scaling phenomena in inelastic electron–nucleus scattering at SLAC had started a new era in particle physics. I had the hunch, like numerous other theorists, that the “SLAC scaling” might have something to do with scale invariance in field theory, the topic of my Ph. D. – thesis, which had been given to me by Heinrich Mitter at the MPI in Munich. In 1970 Gell–Mann was working, partially together with Peter Carruthers, on the problem of scale invariance and its breaking in hadron physics, a topic, which at a first sight seemed unrelated to the “scaling phenomenon” seen at SLAC. I remember a number of conversations I had with Murray at the Aspen Physics Center, in which we talked about possible connections.

I find I am three and a half years older than Gell-Mann although I have always prided myself on belonging to the same generation as he does. I shall give you a contemporary's views and some early recollections of Gell-Mann and his influence on the subject of Particle Physics.

I believe I first saw Gell-Mann at the Institute for Advanced Studies in Princeton in April 1951. He had brought from MIT the expression in terms of Heisenberg fields which would give the equation of the Bethe-Salpeter amplitude. I remember him and Francis Low working on this problem and producing the most elegant of papers, which has been the definitive contribution to this subject ever since.

I left the Institute for Advanced Studies in June 1951 and went back to Lahore. Later, in 1954, I returned to Cambridge and found that in the intervening period, the subject of new particles, the so called V0-particles (Λ0, K0) had developed into a full-fledged new activity. There was the Gell-Mann-Nishijima formula which gave the connection between the charge, the isotopic spin and the strangeness - the prototype formula for other similar equations which followed this in later years and whose influence in Particle Physics one cannot exaggerate.

In July 1954, there was a conference in Scotland where Blackett took the chair and where young Gell-Mann was an invited speaker.

I first met Murray when he was a small child, a 19 year old graduate student at the Caltech of the East. I was an ancient of 26 at the time and was quite surprised when he announced upon meeting me that he knew who I was and that he had read all my papers. That was not such a monumental task at that time, but I found out that he had indeed read them. I discovered much more quickly than Viki Weisskopf that Murray was different from me and thee. We became friends and have remained so for nearly forty years.

When I went to Chicago in 1950 I began immediately agitating to hire Murray. It was no easy task to convince my senior colleagues that this was sensible since he had identically zero publications to his name. I did, however, prevail and we began a long collaboration that continued episodically for nearly 20 years. This was an exciting time in particle physics when there was a vast amount of experimental data and a paucity of theoretical tools to cope with it. It was a pleasure to work with Murray as we used everything we could lay our hands on theoretically to try to pick our way toward an understanding of what was a bewildering and complex landscape. His ingenuity, intensity, enthusiasm, and confidence that we could understand a great deal if we stuck to general principles and were not afraid to make bold conjectures was contagious.

A two-day symposium in celebration of Murray Gell-Mann's 60th birthday was held at the California Institute of Technology on January 27–28, 1989. The theme of the Symposium was “Where are Our Efforts Leading?” Each speaker was asked to choose one (or more) of the great challenges in science or human affairs and try to answer, in connection with our present effort to respond to that challenge, “Where do we stand? What kind of progress are we making? In fifty or a hundred years, how do you think today's efforts will appear?”. The topics discussed spanned a very broad range, representative of Murray's remarkably diverse interests and activities. These included particle physics and quantum cosmology, studies of complex adaptive systems, environmental challenges and studies, education and equality of opportunity, arms control and governmental issues.

Given the unusually broad scope of the Symposium, we decided it would be appropriate to publish separately a ‘physics volume,’ including all of the more technical contributions in theoretical physics and related topics. There were many marvelous contributions in other areas that we hope to publish elsewhere. The present volume includes the texts of presentations at the Symposium by Professors J. B. Hartle, E. Witten, H. Fritzsch, T. D. Lee, I. M. Singer, and V. L. Telegdi. It also includes ten additional contributed papers by well-known physicists who are close personal friends of Murray Gell-Mann.

QUANTUM COSMOLOGY

It is an honor, of course, but also a pleasure for me to join in this celebration of Murray Gell-Mann's sixtieth birthday and to address such a distinguished audience. Murray was my teacher and more recently we have worked together in the search for a quantum framework within which to erect a fundamental description of the universe which would encompass all scales – from the microscopic scales of the elementary particle interactions to the most distant reaches of the realm of the galaxies – from the moment of the big bang to the most distant future that one can contemplate. Such a framework is needed if we accept, as we have every reason to, that at a basic level the laws of physics are quantum mechanical. Further, as I shall argue below, there are important features of our observations which require such a framework for their explanation. This application of quantum physics to the universe as a whole has come to be called the subject of quantum cosmology.

The assignment of the organizers was to speak on the topic “Where are our efforts leading?” I took this as an invitation to speculate, for I think that it is characteristic of the frontier areas of science that, while we may know what direction we are headed, we seldom know where we will wind up.

When Murray Gell-Mann was starting out in physics, one of the big mysteries in the field was to understand the strong interactions, and especially the hadron resonances that proliferated in the 1950's. The existence of these resonances showed clearly that something very new was happening in physics at an energy scale of order one GeV. Another important mystery was to find the correct description of the weak interactions, and among other things to overcome the problems associated with the unrenormalizability of the simple though relatively successful Fermi theory. This problem pointed to a new development at a significantly higher energy scale.

Murray Gell-Mann played a tremendous role in advancing the understanding of these mysteries. His great contributions include his work on the strange particles; the “renormalization group” introduced by Gell-Mann and Low; early ideas about intermediate weak bosons; contributions to the proper description of the structure of the weak current; the unearthing of the SU(3) symmetry of strong interactions, and his contributions to the understanding of current algebra; the introduction of the quark model, and early ideas about QCD. His insights on these and other scientific problems are part of the foundation on which we now attempt to build, and his enthusiasm for science is an inspiration to all of us.

If we ask today what are some of the key new mysteries in particle physics, there are at least three that seem particularly pressing.