One Two Three... Infinity
One Two Three... Infinity: Facts and Speculations of Science is a popular science book authored by theoretical physicist George Gamow, first published in 1947 by Viking Press in New York.[1] The work provides an accessible exploration of key concepts in mathematics, physics, relativity, nuclear science, quantum mechanics, cosmology, and biology, blending factual explanations with speculative ideas to engage lay readers.[2] Illustrated with over 120 pen-and-ink drawings by Gamow himself, the book uses analogies and humor to demystify topics like infinite numbers, curved space-time, atomic structure, stellar evolution, and the origins of life.[3] The book is structured into four main parts, beginning with Part I: Playing with Numbers, which introduces finite and infinite sets, cardinality, and paradoxes in mathematics through two chapters.[4] Part II: Space, Time & Einstein follows with three chapters delving into relativity, the geometry of curved space, four-dimensional space-time, and concepts like time dilation and gravitational effects.[4] Part III: Microcosmos comprises four chapters on the atomic world, covering nuclear fission and fusion, radioactivity, elementary particles such as nucleons, electrons, and neutrinos, quantum uncertainty, and the building blocks of life including cells, genes, and viruses.[4] Finally, Part IV: Macrocosmos addresses the universe's scale in two chapters, discussing astronomical measurements via parallax, the structure of the Milky Way, galactic evolution, stellar life cycles, and the expanding universe estimated to be over five billion years old.[4] Gamow revised the book in 1961 to incorporate advances like thermonuclear energy and updated cosmological estimates, maintaining its reputation as a seminal text in science popularization.[4] Praised for combining technical accuracy with wit and erudition, it has influenced generations of readers by illustrating how everyday phenomena connect to profound scientific principles.[5] The Dover Publications reprint in 1988 further ensured its enduring availability, solidifying Gamow's legacy as a leading communicator of twentieth-century science.[2]Overview
Author and Background
George Gamow was born on March 4, 1904, in Odessa, Russia (now Ukraine), into a family of educators; his father was a teacher of Russian literature and history. He displayed an early interest in science, particularly astronomy and physics, and pursued higher education at the University of Odessa before transferring to the University of Leningrad (now Saint Petersburg), where he studied under physicists Yakov Krutkov and Vladimir Fock. Gamow earned his doctorate in 1928 after completing his dissertation on the structure of atomic nuclei. Facing political pressures in the Soviet Union, he emigrated in 1933, first to England and then to the United States, where he joined the faculty at George Washington University in Washington, D.C. Gamow's scientific career was marked by groundbreaking contributions to nuclear physics and cosmology. In 1928, while still in Leningrad, he developed the quantum tunneling theory of alpha decay, explaining how alpha particles escape atomic nuclei, a model that revolutionized understanding of radioactive processes and earned him international recognition. He later advanced theories on beta decay and collaborated on early work in Big Bang nucleosynthesis, predicting the abundance of light elements like helium in the universe, which laid foundational ideas for modern cosmology. Throughout the 1930s and 1940s, Gamow's research extended to stellar nucleosynthesis and the expansion of the universe, influencing fields from nuclear reactions to astrophysics. Beyond his technical research, Gamow became a pioneering popular science communicator, using wit and simplicity to bridge complex ideas with general audiences. His writing career took off with the "Mr. Tompkins" series, beginning with Mr Tompkins in Wonderland in 1940, which imagined relativistic and quantum effects through everyday scenarios in a banker's dreams. Subsequent books like Mr Tompkins Explores the Atom (1944) and One Two Three... Infinity (1947) exemplified his signature style: blending humor, analogies, and self-illustrated diagrams to demystify science. Gamow personally drew the figures for his books, including the hand-sketched illustrations in One Two Three... Infinity that enhanced its accessibility. The context for Gamow's authorship of One Two Three... Infinity emerged in the post-World War II era, a time of heightened public fascination and anxiety about atomic energy following the Manhattan Project and Hiroshima bombings. As a physicist who had consulted for the U.S. government on nuclear matters, Gamow sought to popularize science amid the "atomic age," emphasizing wonder over fear to foster informed public discourse on topics from mathematics to cosmology.Publication History and Editions
One Two Three... Infinity was first published in 1947 by Viking Press as a popular science book aimed at a lay audience, spanning 340 pages and featuring 128 black-and-white illustrations drawn by the author himself.[6][7] A revised edition appeared in 1961, also from Viking Press, incorporating updates to reflect scientific progress since the original publication.[4] Key changes included additions on thermonuclear reactions and controlled energy release in Chapter VII, an updated estimate of the universe's age to over five billion years, revisions to the astronomical distance scale using data from the 200-inch Hale telescope, a redrawn Figure 101, and new material on synthetic organisms in Chapter IX.[4] The 1961 version maintained the 340-page length and the author's illustrations.[8] Subsequent printings under Viking included minor updates in a 1965 edition, preserving the core content of the 1961 revision.[8] In 1988, Dover Publications released an affordable paperback reprint of the 1961 revised edition, which remains unchanged and serves as the standard version today, with 340 pages and the original 128 illustrations.[2][9] The book has been translated into multiple languages, including Russian (with commentaries in post-Cold War editions), Chinese, and German, extending its international reach.[10][11][12] As of 2025, no major new editions have been issued since 1965, despite significant scientific advances in fields like cosmology and biology, leaving the 1988 Dover edition as the primary accessible format.[13] The book continues to be available in print-on-demand and digital formats, including a 2024 Kindle release on Amazon.[14][15]Synopsis
Part I: Playing with Numbers
Gamow opens Part I by inviting readers to "play with numbers," transforming abstract mathematical concepts into engaging narratives that reveal their beauty and strangeness. He begins with the allure of ever-larger finite numbers, using historical vignettes to illustrate humanity's fascination with scale. For instance, the ancient Greek mathematician Archimedes, in his work The Sand Reckoner, estimated that the grains of sand required to fill the visible universe number fewer than $10^{63}, a feat achieved by devising a numeral system for vast quantities. Gamow also recounts the Indian legend of Sissa Ben Dahir, who, as a reward for inventing chess, requested one grain of wheat on the first board square, two on the second, doubling each time up to 64 squares, yielding a total exceeding $10^{18} grains—enough to cover the Earth many times over. These examples highlight exponential growth, setting the stage for modern large numbers like Avogadro's constant, approximately $6.022 \times 10^{23}, which counts the molecules in one gram-mole of any substance and underscores the atomic world's immensity. To push boundaries further, Gamow introduces the googol, defined as $10^{100} or 1 followed by 100 zeros, a term coined in 1938 by mathematician Edward Kasner with input from his nine-year-old nephew Milton Sirotta during a discussion on enormous quantities. The googolplex, $10 raised to the googol power (10^{10^{100}}$), defies physical realization, as writing it out would require more space than the observable universe contains.[16] Transitioning from colossal finites to the infinite, Gamow explores Georg Cantor's revolutionary set theory, which posits that not all infinities are equal. He explains countable infinities, such as the set of natural numbers \{1, 2, 3, \dots \}, with cardinality \aleph_0 (aleph-null), where elements can be paired one-to-one with integers despite endless extent. In contrast, the real numbers form an uncountable infinity, with cardinality $2^{\aleph_0}, known as the continuum, larger than \aleph_0. To demonstrate, Gamow presents Cantor's diagonal argument: suppose all real numbers between 0 and 1 are listed as infinite decimals (e.g., 0.d_{11}d_{12}\dots, 0.d_{21}d_{22}\dots, etc.); form a new number 0.e_1 e_2 \dots where e_n differs from d_{nn} (say, by adding 1 modulo 10, avoiding 9s for convergence). This diagonal number mismatches every listed one, proving no complete enumeration exists. This proof, from Cantor's 1891 paper, establishes transfinite cardinals like \aleph_1 for the continuum, opening a hierarchy of infinities beyond intuition.[16] To convey infinity's paradoxes, Gamow describes David Hilbert's Grand Hotel thought experiment, introduced in his 1924 lectures on the infinite. Imagine a hotel with infinitely many rooms, all occupied (guest n in room n). A new arrival prompts shifting each guest from room n to n+1, freeing room 1. For infinitely many new guests (say, from a bus numbered by naturals), assign them to even-numbered rooms after shifting originals to odds, or use prime/composite distinctions for multiple infinite buses. This illustrates that infinite sets can be placed in one-to-one correspondence with proper subsets, a property absent in finite sets, challenging everyday arithmetic.[16] Gamow then introduces imaginary numbers to solve equations without real solutions, defining i = \sqrt{-1}, the imaginary unit. Complex numbers take the form a + bi, where a and b are real, and are represented geometrically on the complex plane with real parts along the horizontal axis and imaginary along the vertical—like plotting vectors from the origin. He illustrates with a whimsical treasure hunt: instructions like "go 3 units east, then i units north" (equivalent to 3 + i) or multiplications that rotate and scale, revealing complex arithmetic's intuitive vector interpretation. This foundation hints at broader utility, as complex numbers elegantly describe physical phenomena like electrical circuits and wave propagation in physics, where real and imaginary components capture amplitude and phase without lengthy derivations.[16] The section culminates with prime numbers, the "atoms" of integers, whose distribution Gamow portrays as irregular yet infinite. He details Euclid's proof from Elements (Book IX, Proposition 20, ca. 300 BCE): assume finitely many primes p_1, \dots, p_k; form N = p_1 \cdots p_k + 1. N exceeds all p_i and is not divisible by any, so either N is prime or its prime factors are new, contradicting finitude. Primes thin out (density roughly $1/\ln n by the prime number theorem), but puzzles persist. Gamow highlights Fermat's Last Theorem, conjectured in 1637, stating no positive integers a, b, c, n>2 satisfy a^n + b^n = c^n—a claim unsolved in 1947 despite proofs for specific n up to 269. He also discusses the Goldbach conjecture, proposed by Christian Goldbach in a 1742 letter to Leonhard Euler, asserting every even integer greater than 2 is the sum of two primes (e.g., $100 = 47 + 53), verified computationally for vast numbers but unproven. These open problems exemplify number theory's enduring allure.[16][17]Part II: Space, Time, and Einstein
In Part II of One Two Three... Infinity, George Gamow delves into the geometric and topological peculiarities of space, illustrating how mathematical abstractions can reshape our understanding of the physical universe. He begins with one-sided surfaces, such as the Möbius strip, independently discovered by August Ferdinand Möbius and Johann Benedict Listing in 1858, which features only one side and one edge when formed by twisting and joining the ends of a rectangular strip.[18] Gamow explains that traversing the Möbius strip reverses orientation, as demonstrated by a drawing of a left-facing profile that appears right-facing upon return, and notes that cutting it lengthwise yields a single doubled-length loop rather than two separate pieces. He extends this to the Klein bottle, conceptualized by Felix Klein in 1882 as a non-orientable, boundaryless surface that cannot exist without self-intersection in three-dimensional space but models a four-dimensional analogue. These topologies, including the projective plane as another one-sided surface, challenge Euclidean intuitions and suggest possible structures for a finite yet unbounded cosmos, akin to a worm-eaten apple where channels form a self-contained volume without edges.[19] Gamow transitions to practical applications in cartography, highlighting distortions in mapping curved surfaces like the Earth onto flat planes and the historical quest for accurate projections. He discusses map coloring problems, where adjacent regions must differ in hue, and presents the four-color theorem, conjecturing that four colors suffice for any planar map—a claim unproven in 1947 but later verified in 1976 by Kenneth Appel and Wolfgang Haken through computer-assisted analysis of reducible configurations.[20] While five colors were already known to be adequate via Euler's formula relating vertices (V), edges (E), and faces (F) as V - E + F = 2, Gamow emphasizes the theorem's topological roots in graph theory, using it to bridge everyday puzzles with deeper spatial properties.[19] Building on these ideas, Gamow introduces non-Euclidean geometries, where space deviates from flatness due to intrinsic curvature, as pioneered by Carl Friedrich Gauss, Nikolai Lobachevsky, and János Bolyai in the early 19th century. In hyperbolic geometry, with negative Gaussian curvature like a saddle, the sum of a triangle's angles is less than 180° and multiple parallels exist through a point to a line; conversely, elliptic geometry on a sphere exhibits positive curvature, zero parallels, and angle sums exceeding 180° (e.g., 210° for a large spherical triangle). Gamow defines "straight lines" as geodesics—the shortest paths, such as great circles on a sphere—and uses the worm-eaten apple analogy to envision a three-dimensional hyperbolic space that curves back on itself, finite in extent yet edgeless, prefiguring models of a closed universe. These geometries underscore that space's properties are not absolute but depend on measurement scales and curvature.[19] Gamow then bridges mathematics to physics with Albert Einstein's special relativity, formulated in his 1905 paper, which unifies space and time into a four-dimensional Minkowski spacetime. The theory arose from the null result of the 1887 Michelson-Morley experiment, which sought but failed to detect Earth's velocity relative to the luminiferous ether using an interferometer, implying no preferred frame.[21] Einstein postulated the constancy of light speed c (approximately 3 × 10^8 m/s) in all inertial frames, leading to the Lorentz transformation and effects like time dilation, where proper time τ for a moving clock relates to coordinate time t by \tau = t \sqrt{1 - \frac{v^2}{c^2}} or equivalently, dilated time t' = t / \sqrt{1 - v^2/c^2}, as derived from the invariance of the spacetime interval ds^2 = dx^2 + dy^2 + dz^2 - c^2 dt^2.[22] Length contraction follows similarly, with moving length l' = l \sqrt{1 - v^2/c^2}. Gamow illustrates with examples, such as muons reaching Earth's surface due to dilated lifetimes or the twin paradox, where one twin's high-speed journey results in less elapsed time upon return; the resolution lies in the asymmetry of acceleration, breaking inertial symmetry, as Einstein clarified in 1918.[23] As velocity nears c, relativistic mass increases without bound, prohibiting superluminal travel.[19] Shifting to general relativity, Einstein's 1915 theory, Gamow describes gravity not as a force but as spacetime curvature induced by mass-energy, governed by the Einstein field equations. The equivalence principle equates gravitational and inertial mass, implying that free fall follows geodesics in curved spacetime. Light paths bend near massive bodies, a prediction confirmed during the 1919 solar eclipse by expeditions led by Arthur Eddington and Frank Dyson, measuring starlight deflection of 1.61″ ± 0.30″ against Einstein's 1.75″ forecast for rays grazing the Sun.[24] Gamow speculates on extreme outcomes, like light trapped in dense stars forming "frozen stars" (precursors to black holes), and notes E = mc^2 from special relativity, linking mass to energy release. He touches on wormholes as theoretical bridges in spacetime, akin to topological tunnels, though unresolved as causal loops.[19] Gamow concludes the part with relativistic implications for time travel, highlighting paradoxes like the grandfather paradox, where altering the past (e.g., killing one's ancestor) precludes one's existence, or superluminal signals inverting cause and effect. Such scenarios, potentially enabled by closed timelike curves, remain speculative and physically barred by the light-speed limit, as mass diverges asymptotically. Gamow resolves the twin paradox via the non-inertial frame of the traveler, where simultaneity shifts during turnaround, ensuring consistency without backward causation. These discussions underscore relativity's unification of space, time, and gravity, transforming abstract math into cosmic reality.[19]Part III: Microcosmos
In Part III of One Two Three... Infinity, George Gamow explores the atomic and subatomic realms, elucidating the foundational discoveries that reshaped our understanding of matter's building blocks. He begins with the atom's internal structure, drawing on Ernest Rutherford's pivotal 1911 gold foil experiment conducted at the University of Manchester. In this setup, a beam of alpha particles from a radioactive source was fired at an ultrathin sheet of gold foil, with a fluorescent screen detecting the particles' deflections. While most particles passed straight through, approximately one in 8,000 was scattered at angles greater than 90 degrees, defying the prevailing plum pudding model of the atom and revealing a minuscule, positively charged nucleus surrounded by mostly empty space.[25] This observation implied that the atom's mass and positive charge were concentrated in a tiny core, with electrons orbiting at a distance, akin to planets around the sun in a scaled-down solar system.[26] Rutherford's analysis of the scattering data yielded a quantitative formula describing the phenomenon, where the differential cross-section for alpha particle deflection is proportional to $1 / \sin^4(\theta/2), with \theta as the scattering angle; this hyperbolic dependence matched experimental observations and confirmed the nuclear model's electrostatic repulsion between the positively charged alpha particles and the gold nucleus.[27] Gamow emphasizes how this experiment, building on Geiger and Marsden's earlier measurements, provided empirical evidence for the atom's discrete structure, paving the way for subsequent quantum refinements.[28] Transitioning to the organization of elements, Gamow recounts Dmitri Mendeleev's 1869 periodic table, which arranged the known 63 elements by increasing atomic weight, revealing recurring patterns in chemical properties that he termed "periodicity."[29] Mendeleev boldly predicted undiscovered elements like gallium and germanium based on gaps in his table, but later work by Henry Moseley in 1913 established atomic number—the number of protons in the nucleus—as the fundamental ordering principle, correlating directly with an element's position and chemical behavior.[30] This shift highlighted the role of electron configurations, with elements in the same group sharing similar outer-shell electron arrangements that dictate reactivity; for instance, alkali metals in Group 1 have one valence electron, fostering their tendency to lose it readily.[31] Gamow introduces quantum mechanics by contrasting classical atomic models with Niels Bohr's 1913 quantized orbits for the hydrogen atom, where electrons occupy discrete energy levels rather than spiraling continuously into the nucleus. In Bohr's model, the energy of the electron in the nth orbit is given by E_n = -\frac{13.6 \, \text{eV}}{n^2}, where n is the principal quantum number starting from 1, yielding the ground state energy of -13.6 eV for hydrogen and explaining spectral line emissions as transitions between these levels. This quantization resolved the instability of Rutherford's planetary atom and matched the Balmer series of hydrogen lines observed in spectroscopy. Gamow further discusses wave-particle duality, a cornerstone of quantum theory, where entities like electrons and photons exhibit both particle-like (localized impacts in detectors) and wave-like (interference patterns in double-slit experiments) properties, as demonstrated by Louis de Broglie's 1924 hypothesis and Clinton Davisson's 1927 electron diffraction confirmation. A key quantum limitation Gamow highlights is Werner Heisenberg's uncertainty principle, formulated in 1927, which states that the product of uncertainties in position \Delta x and momentum \Delta p satisfies \Delta x \Delta p \geq \hbar / 2, where \hbar = h / 2\pi and h is Planck's constant.[32] This inequality arises from the wave nature of particles, implying that precise measurement of one property inherently disturbs the other; for example, localizing an electron's position with light scatters it, altering its momentum unpredictably. The principle underscores the probabilistic essence of quantum mechanics, prohibiting classical determinism at atomic scales and influencing phenomena like electron cloud orbitals rather than fixed paths.[33] Gamow, a pioneer in cosmology, devotes significant attention to the origins of chemical elements, presenting his own 1940s theory of primordial nucleosynthesis within the hot Big Bang model. In the universe's first minutes, when temperatures exceeded 10^9 K, neutrons and protons fused rapidly to form light nuclei: primarily hydrogen (about 75% by mass) through unbound protons, and helium-4 (about 25%) via deuterium bottlenecks and subsequent captures, with trace amounts of helium-3, deuterium, and lithium-7.[34] This process, detailed in Gamow's collaborations with Ralph Alpher and Robert Herman, predicted the observed cosmic abundances of these primordial elements, distinguishing them from heavier ones forged in stellar interiors, and provided early evidence for the expanding universe's thermal history.[35] Extending to the biology of the microcosmos, Gamow examines life's molecular foundations as they were understood in the mid-20th century, prior to the 1953 DNA double helix discovery. He describes chromosomes as thread-like structures in cell nuclei that carry hereditary information through genes, then believed to consist of proteins due to their complexity and abundance in chromatin. These proteinaceous genes were thought to replicate and mutate, directing protein synthesis for traits via enzyme chains, with early speculations on diamond-shaped "tetrahedral" coding schemes for amino acids.[36] Gamow portrays viruses as enigmatic entities on the life-matter boundary: crystalline outside hosts yet capable of reproducing by hijacking cellular machinery, lacking independent metabolism and thus classified as non-living reproducers rather than true organisms. In the 1961 edition, he adds discussion of synthetic viruses, referencing advances like Heinz Fraenkel-Conrat's 1950s reconstitution of tobacco mosaic virus from purified RNA and protein components, demonstrating infectivity and blurring distinctions between life and chemistry.[37]Part IV: Macrocosmos
In Part IV of One Two Three... Infinity, George Gamow explores the vast scales of the universe, beginning with ancient attempts to measure cosmic dimensions. Around 240 BCE, the Greek scholar Eratosthenes calculated the Earth's circumference to be approximately 40,000 kilometers by comparing the angle of the sun's rays at noon in Alexandria and Syene, using the known distance between the two cities and basic geometry.[38] This measurement demonstrated the power of observation and mathematics in probing planetary size without direct traversal. Later, Aristarchus of Samos proposed a heliocentric model in the third century BCE, placing the Earth in orbit around the Sun, and recognized that stellar parallax—the apparent shift in star positions due to Earth's motion—could measure distances to the stars, though the effect was too small to detect with ancient instruments, implying immense stellar separations.[39] Gamow then discusses methods for determining stellar distances, highlighting parallax as refined in the 19th and 20th centuries and the role of Cepheid variables as "standard candles." In 1908, Henrietta Swan Leavitt discovered the period-luminosity relation for Cepheids, showing that these pulsating stars' intrinsic brightness correlates directly with their pulsation period, allowing astronomers to gauge distances by comparing apparent and absolute magnitudes.[40] This relation enabled calibration of cosmic yardsticks beyond the solar neighborhood, transforming parallax-limited measurements into tools for galactic scales. Turning to galaxy structure, Gamow describes the Milky Way as an "island universe," a vast disk of stars, gas, and dust, with early telescopic observations revealing spiral nebulae as separate systems. In the 1920s, Edwin Hubble used the 100-inch Hooker telescope at Mount Wilson to observe Cepheids in the Andromeda nebula (M31), confirming in 1924 that it lay far beyond the Milky Way—about 900,000 light-years away—thus establishing spiral nebulae as distant galaxies comparable in size to our own.[41] These findings resolved debates over whether the universe consisted of a single galaxy or myriad independent ones, expanding humanity's view from a provincial stellar system to a cosmos teeming with billions of galaxies. Gamow delves into evidence for an expanding universe, drawing on redshift observations of distant galaxies. In 1929, Hubble published data showing that galaxies recede from us with velocities proportional to their distances, formalized as Hubble's law:v = H_0 d
where v is the recession velocity, d is the distance, and H_0 is the Hubble constant (initially estimated at around 500 km/s/Mpc).[42] This redshift, interpreted as Doppler stretching of light due to motion away from the observer, suggested a dynamic universe originating from a hot, dense state rather than a static one. Based on contemporary H_0 values in 1947, the universe's age was estimated at roughly 2 billion years, implying ongoing expansion from a primordial epoch. In the 1961 edition, this estimate was revised to over 5 billion years based on new astronomical data.[43] This expansion fueled cosmological debates, with the Big Bang model resolving Olbers' paradox—the puzzle of why the night sky is dark despite infinite stars—by limiting the universe's age, so light from distant sources has not yet reached us, and by the universe's finite expansion diluting stellar light over time.[43] He speculates on the "heat death," where expansion leads to ever-cooling temperatures and maximum entropy, ending in a dilute, lifeless void. Gamow ties these ideas to his own work, including pioneering Big Bang nucleosynthesis, where he and collaborators Ralph Alpher and Hans Bethe explained light element abundances (like helium) as products of nuclear reactions in the first minutes after the universe's birth, linking microscopic quantum processes to macroscopic cosmic evolution.[44]