Fact-checked by Grok 2 weeks ago

Siméon Denis Poisson

Siméon Denis Poisson (1781–1840) was a and physicist renowned for his foundational work in , including the development of the , and for advancing in fields such as definite integrals, , and . Born on June 21, 1781, in , , Poisson demonstrated early aptitude in mathematics, attending the École Centrale in before excelling at the in , where he graduated in 1800 without taking final exams due to his exceptional performance. Under the mentorship of , he began his career as a at the in 1800, advancing to deputy professor in 1802 and full professor of in 1806. He also served as an astronomer at the Bureau des Longitudes from 1808 and held the chair of at the Faculté des Sciences in from 1809, while being elected to the physics section of the in 1812. Poisson's prolific output included over 300 scientific papers and several influential treatises, such as the two-volume Traité de mécanique published in 1811, which became a standard reference in . His research spanned pure and , contributing to partial differential equations—most notably in —and to physics topics like , magnetism, elasticity, heat conduction, and . In probability and , he generalized Jakob Bernoulli's in 1835 and introduced the in his 1837 work Recherches sur la probabilité des jugements en matière criminelle et en matière civile, applying it to error analysis and jury decision-making, while also proving that the sum of random errors tends toward a Gaussian distribution. Additionally, his studies in led to key insights, such as determining that the in a tensed bar is one-fourth of the longitudinal strain, influencing the concept of in material science. Poisson died on April 25, 1840, in Sceaux near , leaving a legacy that continues to underpin , , and .

Life and Career

Early Life and Education

Siméon Denis Poisson was born on June 21, 1781, in , a small town in central , into a family of modest means. His father, also named Siméon Poisson, served as a soldier in the before becoming a local administrator, while his mother, Aimée Marie Francheterre, came from a non-noble background; the family faced class-based limitations typical of the post-Revolutionary era, though Poisson was the first child to survive infancy and was raised partly by a nurse due to his fragile health. Despite limited resources, Poisson displayed early mathematical talent, learning to read and write under his father's guidance and initially apprenticed to a uncle in around 1796, where he struggled with practical tasks but showed disinterest in medicine. He then attended the École Centrale in starting in 1796, where he quickly excelled in , largely self-taught in the basics before formal secondary instruction, overcoming financial constraints through the opportunities provided by these public institutions. In 1798, at age 17, Poisson entered the prestigious in , ranking first in the entrance examination despite his unconventional preparation, and he graduated just two years later in 1800 at age 19, exempt from the final exam based on his submitted work. Immediately upon graduation, he was appointed as a (student-teacher) at the school on the strong recommendation of his mentors, and , who recognized his exceptional analytical abilities early on and became lifelong supporters. Poisson's first publications appeared in 1800, including a paper on the theory of equations and , marking his emerging prowess in .

Professional Achievements

Poisson began his professional career at the as a in 1800, advancing to deputy professor in 1802 and full professor of mechanics in 1806. In 1808, he became an astronomer at the Bureau des Longitudes, and the following year, he received an additional professorship at the newly established Faculté des Sciences in . In 1812, Poisson was elected to the Académie des Sciences in the physics section, marking a significant milestone in his integration into France's elite scientific institutions. Poisson also held key administrative responsibilities, serving as an examiner for the from 1816 onward and participating in juries for prestigious competitions, such as the Grand Prix de Mathématiques, where his rigorous evaluations shaped the selection of emerging talent. Throughout his career, Poisson demonstrated extraordinary productivity, authoring more than three hundred memoirs and a dozen major treatises, including the influential multi-volume Traité de mécanique (1811–1833), which became a standard reference in its field. In recognition of his contributions, he was elevated to the rank of by King in 1821, though he rarely used the title. Personally, Poisson married Nancy de Bardi, an Englishwoman of descent, in 1817; the couple had four children. Poisson's relentless workload took a toll on his health, which had always been fragile, leading to his decline and death on April 25, 1840, at the age of 58 in Sceaux. He was buried in the Père-Lachaise Cemetery in , where his funeral drew prominent figures from the French scientific community.

Interaction with Évariste

In early 1831, at the age of 19, submitted his memoir titled Mémoire sur les conditions de résolubilité des équations par radicaux to the Paris Academy of Sciences, building on his earlier explorations of continued fractions and the solvability of algebraic equations that dated back to his initial 1829 submission for the Academy's in . , a leading figure in the Academy and a proponent of rigorous mathematical exposition, was appointed as the reviewer for this third iteration of Galois's work on equation theory. After months of examination, Poisson issued his report on July 4, 1831, describing the memoir as largely incomprehensible and rejecting it for the Academy's consideration. Poisson's assessment was scathing in its critique of the presentation, stating that "the argument is neither sufficiently clear nor sufficiently developed to allow us to judge its rigor" and noting that the work required substantial revision to convey its ideas effectively. He acknowledged potential merit in Galois's ideas but emphasized their scattered nature and lack of formal structure, suggesting that the young mathematician publish a comprehensive collection of his writings on equations to enable a fairer evaluation. This judgment aligned with Poisson's conservative standards, heavily influenced by his mentorship under , which prioritized exhaustive clarity and logical progression in mathematical proofs over bold, unconventional formulations. No evidence suggests malice on Poisson's part; his report was a standard application of the Academy's gatekeeping role during a period when young outsiders like Galois struggled for recognition. The rejection intensified Galois's frustration with the scientific establishment, prompting him to author several polemical texts denouncing the Academy's procedures and the perceived elitism of its members. Galois made further attempts to revise and resubmit his work, but these efforts were overshadowed by the political turmoil of the , in which he participated as a radical republican; his on July 14, 1831—just days after Poisson's report—for allegedly threatening King Louis-Philippe contributed to his marginalization. A second in May 1832, amid ongoing unrest, preceded his fatal later that month. In hindsight, Poisson's oversight marked a significant missed opportunity, as the memoir contained foundational insights into permutation groups and field theory that would later revolutionize , though they remained unappreciated until after Galois's death. This encounter was contextualized by Poisson's broader role as an examiner at the , where Galois had failed the oral entrance exam in July 1830 under similar scrutiny for lacking polish in his responses, further highlighting the institutional barriers the young faced.

Mathematical Contributions

Probability and Statistics

Siméon Denis Poisson made significant contributions to , particularly through his 1837 treatise Recherches sur la probabilité des jugements en matière criminelle et en matière civile, where he applied probabilistic methods to analyze errors in legal decision-making. In this work, Poisson examined the reliability of verdicts by modeling the probability of miscarriages of , such as wrongful or acquittals, under various sizes and voting rules. He determined optimal compositions—such as seven jurors requiring a of four for —to minimize the overall error rate, replacing binary notions of guilt or innocence with probabilities of "convictable" or "not convictable" outcomes based on evidence strength. This analysis highlighted discrepancies between theoretical probabilities and empirical judicial data, laying early groundwork for in social and legal contexts. A key innovation in Poisson's treatise was the introduction of what is now known as the , derived as a limiting case of the for rare events. Considering a sequence of independent trials with success probability p and number of trials n large such that \lambda = np remains constant, Poisson approximated the probability of exactly k successes as the trials approach the limit. The resulting is given by P(K = k) = \frac{e^{-\lambda} \lambda^k}{k!}, \quad k = 0, 1, 2, \dots This derivation, presented on page 206 of his book, built on earlier approximations by Abraham de Moivre but was explicitly tied to judicial errors, such as the low probability of multiple false testimonies in a trial when events are rare (p = 1/n). The distribution proved useful for modeling infrequent occurrences, influencing later applications in insurance and rare event prediction despite initial limited recognition. Poisson also extended the law of large numbers, building on Jacob Bernoulli's 1713 weak law and Pierre-Simon Laplace's refinements, by providing rigorous proofs for the of sample means to expected values in sequences of but not necessarily identically distributed random variables. In his 1837 work, he demonstrated that the probability of deviation from the mean decreases as the number of trials increases, even without prior knowledge of the success probability p, and addressed error propagation in aggregated observations. These results were applied to astronomical data reduction, where they helped quantify uncertainties in repeated measurements, and to , including mortality tables for purposes, enabling more accurate predictions of trends and . Poisson's formulations, including direct proofs of without relying on generating functions, solidified the law's applicability to practical and influenced modern statistical theory, though his dependent-event extensions were later refined by others.

Potential Theory and Differential Equations

Poisson extended , \nabla^2 \phi = 0, to inhomogeneous cases in 1813, deriving the general form \nabla^2 \phi = f for potentials inside domains with distributed sources, framed as a purely mathematical independent of specific physical contexts. This advancement addressed limitations in Laplace's Mécanique Céleste by providing tools for analyzing perturbations in through elliptic s (PDEs). Solutions to this equation were expressed using representations, including early forms of Green's functions, which allow decomposition of the solution into a particular for the source term f and a satisfying boundary conditions. In a key 1820 memoir on periodic quantities, Poisson developed integral representations for potentials, notably introducing the for the unit disk to solve the for . The for the disk is given by P_r(\theta - \phi) = \frac{1 - r^2}{1 - 2r \cos(\theta - \phi) + r^2}, enabling the representation of a u(re^{i\theta}) inside the disk as u(re^{i\theta}) = \frac{1}{2\pi} \int_0^{2\pi} u(e^{i\phi}) P_r(\theta - \phi) \, d\phi, assuming continuous boundary values u(e^{i\phi}). This work extended to higher dimensions and emphasized boundary value problems for elliptic PDEs, distinguishing Dirichlet conditions (prescribed values on the boundary) from conditions (prescribed normal derivatives). Poisson's advancements in elliptic PDEs included representation formulas for solutions inside bounded domains, expressing the potential via surface and volume integrals over Green's functions tailored to the domain geometry. These formulas facilitated the use of expansions for harmonic functions, bridging integral methods with trigonometric series to approximate solutions and prove convergence under suitable conditions. Although motivated by , Poisson's formulations remained rigorously mathematical, influencing subsequent developments in without reliance on physical interpretations.

Analytical Mechanics and Calculus of Variations

Poisson's major contribution to analytical mechanics is encapsulated in his comprehensive treatise Traité de mécanique, published in two volumes in 1811 and 1833, which provided a systematic exposition of Joseph-Louis Lagrange's analytical mechanics while incorporating advanced variational methods to derive equations of motion for diverse mechanical systems. This work emphasized the use of generalized coordinates and the principle of virtual work, extending Lagrange's framework to include detailed treatments of both holonomic and more complex constraint scenarios, thereby serving as a foundational text for generations of mechanicians. A pivotal innovation in this domain was Poisson's introduction of the Poisson bracket in his 1809 memoir "Mémoire sur la variation des constantes arbitraires dans les questions de mécanique," published in the Journal de l'École Polytechnique. The bracket is defined for canonical coordinates q_i and momenta p_j as \{q_i, p_j\} = \delta_{ij}, where \delta_{ij} is the Kronecker delta, and more generally for functions f and g on phase space as \{f, g\} = \sum_k \left( \frac{\partial f}{\partial q_k} \frac{\partial g}{\partial p_k} - \frac{\partial f}{\partial p_k} \frac{\partial g}{\partial q_k} \right). This structure underpins Hamiltonian dynamics, enabling the equations of motion to be expressed compactly as \dot{q_i} = \{q_i, H\} and \dot{p_i} = \{p_i, H\}, where H is the Hamiltonian function, thus facilitating the analysis of time evolution and conserved quantities in mechanical systems. In the , Poisson extended the theory beyond single-function problems to cases involving multiple interdependent functions, as detailed in his 1833 memoir "Mémoire sur le calcul des variations" presented to the Académie des Sciences. He developed criteria for the stability of equilibria by examining variation of functional, where a positive definite second variation indicates a stable minimum, providing a mathematical tool to assess the robustness of mechanical equilibria against small perturbations. These extensions were instrumental in refining variational principles for optimization in dynamics. Poisson applied these tools to specific problems in , particularly perturbations of planetary orbits, where he used variational methods and Poisson brackets to quantify deviations from Keplerian motion under gravitational influences, as elaborated in the second volume of his Traité de mécanique. In , he analyzed rotational stability and using similar frameworks, deriving equations that account for moments of inertia and external torques. Additionally, his investigations into integral invariants—quantities preserved under canonical transformations, such as phase space volumes—laid groundwork for later developments like on the incompressibility of flow in systems, with early formulations appearing in his 1823 memoir on summation formulas. Among his key innovations, Poisson reformulated to incorporate variational calculus more seamlessly, expressing the balance of and inertial forces through differential forms that align with equations, thereby enhancing its applicability to constrained systems. He also addressed non- constraints—those not integrable to position restrictions, such as velocity-dependent conditions in rolling motion—by modifying d'Alembert's approach to yield consistent without reducing to holonomic equivalents, a treatment integrated into his Traité de mécanique.

Physical Contributions

Electricity and Magnetism

In his early memoirs on electrostatics from 1811 to 1813, Siméon Denis Poisson applied , initially developed by for gravitational problems, to formulate the mathematical foundations of and magnetostatics. Poisson derived the governing equation for the electrostatic potential \phi, now known as : \nabla^2 \phi = -\frac{\rho}{\epsilon_0}, where \rho is the and \epsilon_0 is the ; this equation generalizes \nabla^2 \phi = 0 for charge-free regions and enables the solution of boundary value problems in the presence of charges. By adapting Laplace's analytical methods, Poisson bridged to experimental , providing a rigorous framework for predicting field distributions in complex geometries. In , Poisson focused on solutions for charged conductors, deriving the potential and field for uniformly charged spheres, where the surface \sigma remains constant, leading to a uniform field outside akin to a point charge at the center. For arbitrary conductors, he solved boundary value problems to determine induced surface charges that ensure surfaces, emphasizing that all excess charge resides on the exterior. Poisson also developed the for a point charge near an infinite conducting plane, placing an equal-and-opposite image charge symmetrically across the plane to satisfy the zero-potential boundary condition, thereby simplifying calculations of the force on the charge and the induced surface density, which varies inversely with distance squared from the projection point. These approaches revealed key properties, such as the linear superposition of potentials and the uniqueness of solutions under Dirichlet conditions. Extending the formalism to magnetostatics, Poisson introduced an analogous \psi satisfying \nabla^2 \psi = -\mu_0 \nabla \cdot \mathbf{M}, where \mathbf{M} is the , treating permanent magnets as distributions of bound "magnetic charges" \rho_m = -\nabla \cdot \mathbf{M} and surface densities \sigma_m = \mathbf{M} \cdot \hat{n}. He analyzed fields from uniformly magnetized spheres and cylinders, showing that a produces a uniform internal field and a external field, while also addressing current distributions by integrating over amperian loops to compute the . Poisson calculated specific surface densities for magnetized bodies, such as ellipsoids, and critiqued assumptions in Coulomb's for by highlighting inconsistencies in treating molecular alignments without continuous distributions, advocating for potential-based derivations over direct force laws. Poisson's framework extended to dielectrics, predicting induced polarization charges that modify the internal field, with the effective potential inside a linear sphere in a uniform external field reduced by the factor $3\epsilon / (2\epsilon + \epsilon_0), where \epsilon is the material ; this anticipated screening effects and bound charge contributions to overall field attenuation. His work on surface charge densities for interfaces provided early quantitative insights into variations, influencing later theories of without invoking dynamic waves. Building briefly on the general Poisson equation from , these applications underscored the versatility of elliptic partial differential equations in static .

Optics and Wave Propagation

Siméon Denis Poisson played a pivotal role in the 1818 debate over the during the Académie des Sciences prize competition, where he served as a evaluating Augustin-Jean Fresnel's on . As a proponent of the corpuscular theory, Poisson sought to undermine Fresnel's wave-based approach by computing the diffraction pattern for passing around a circular obstacle. His calculation, based on Fresnel's principles, unexpectedly revealed that the wave theory predicted a bright at the center of the shadow cast by the obstacle, a result he deemed absurd and incompatible with observation. This predicted central bright spot, now known as the Poisson spot or , arises from constructive of diffracted waves from the obstacle's edges. In 1819, experimentally confirmed the spot's existence using a small circular disk, providing crucial empirical support for Fresnel's wave theory and leading Poisson to concede the validity of wave optics. Poisson's mathematical prediction not only highlighted the counterintuitive implications of wave propagation but also demonstrated the power of methods in diffraction analysis, with the spot's intensity matching the unobstructed incident light due to balanced phase contributions. Poisson applied the wave equation to model light propagation, treating light as transverse vibrations in an elastic ether. The governing equation for the displacement u of the light wave is \frac{\partial^2 u}{\partial t^2} = c^2 \nabla^2 u, where c is the in the medium, derived from the elastic properties of the ether. He extended this to propagation in heterogeneous media, incorporating variations in to describe how waves bend and interfere, laying groundwork for analyzing and phenomena. In his seminal "Mémoire sur la théorie des ondes" (1816, published 1818), Poisson critiqued the corpuscular theory's inability to explain and , affirming the wave nature of light through detailed derivations of wave solutions. He followed this with memoirs on between 1823 and 1825, published in the Mémoires de l'Académie royale des sciences, where he refined integral expressions for diffracted amplitudes and explored implications for optical patterns. These works emphasized the superiority of wave models in predicting observable effects like the Poisson spot. Poisson's predictions extended to broader wave optics, including early analyses of and double refraction within the ether vibration framework, where he examined how transverse account for in crystals by linking refractive indices to vibration directions. His mathematical confirmations underscored the wave theory's explanatory power for these phenomena, influencing subsequent developments in optical .

Elasticity, Fluids, and

Poisson made significant advancements in the of elasticity during the , extending Joseph-Louis Lagrange's foundational work on by incorporating molecular interactions to describe the behavior of deformable solids. In his comprehensive memoir "Mémoire sur l'équilibre et le mouvement des corps élastiques" presented to the Académie des Sciences in 1828 and published in 1829, he derived the equilibrium equations for bodies under various conditions, providing a rigorous framework for analyzing deformations in isotropic media. These equations balanced internal stresses with external forces, enabling predictions of static and dynamic responses in continuous materials. A key contribution from this period was Poisson's formulation of the stress-strain relations for isotropic elastic media, where the material's response to uniaxial involves both axial and lateral deformations linked by a constant ratio. He introduced what is now known as , defined as \nu = -\frac{\epsilon_\text{lateral}}{\epsilon_\text{axial}}, initially calculating it as $1/4 based on Pierre-Simon Laplace's molecular theory and experimental data from materials like . This ratio, typically ranging from 0.25 to 0.5 in common engineering materials, quantifies the lateral contraction accompanying axial extension under tension, forming the basis for generalizations in three dimensions. Poisson's analysis in a note further explored these relations for elastic filaments and plates, emphasizing their implications for material . In , Poisson addressed limitations in Leonhard Euler's inviscid theories by integrating viscous effects and molecular , laying precursors to the Navier-Stokes equations in his two-volume Traité de mécanique (1811) and subsequent memoirs. His 1831 "Mémoire sur les équations générales de l'équilibre et du mouvement des corps solides élastiques et des fluides" treated fluids as rapidly relaxing elastic solids, deriving that included terms and compressibility-dependent gradients, such as (\epsilon/3)\nabla(\nabla \cdot \mathbf{v}) for small deformations. This molecular approach summed intermolecular forces directly, extending Lagrange's variational principles for continua while critiquing Claude-Louis Navier's integral methods as incompatible with Laplacian reasoning. Poisson applied these to specific flows, including analyses of motion through orifices and the role of in resisting shear. Poisson's work on capillary action complemented his fluid theories, modeling surface tension as arising from molecular attractions in his Nouvelle théorie de l'action capillaire (1831), which refined Laplace's earlier ideas by quantifying meniscus formation and liquid rise in tubes without relying solely on idealized surfaces. Regarding wave propagation, his 1829 elastic memoir established the existence of longitudinal (compressional) and transverse (shear) waves in solids, with speeds derived from material properties; for instance, the longitudinal wave speed in thin rods approximates \sqrt{E/\rho}, where E is Young's modulus and \rho is density, while transverse waves propagate more slowly. These derivations predicted distinct wave types during disturbances like earthquakes, with longitudinal waves traveling faster and serving as precursors—a foundational insight for seismology—and transverse waves contributing to destructive shearing. In acoustics, Poisson's framework explained sound propagation through solid continua, influencing later studies of elastic vibrations.

Thermodynamics and Heat Conduction

Poisson made significant contributions to the mathematical of heat conduction, particularly through his extensions of Fourier's foundational work presented in the 1822 Théorie analytique de la chaleur. In his 1823 "Mémoire sur la distribution de la chaleur dans les corps solides," published in the Journal de l'École Polytechnique, Poisson addressed the of heat in solid bodies by deriving solutions for transient heat flow under various conditions, emphasizing applications to conduction in homogeneous and heterogeneous materials. This work built directly on Fourier's series expansions but incorporated more general assumptions about material properties, providing analytical methods to predict distributions over time in solids subjected to initial or heat sources. A key advancement in Poisson's analysis was the generalization of the heat equation to account for variable thermal , allowing for more realistic modeling of non-uniform materials. The standard form of the heat equation for constant conductivity \kappa is given by \frac{\partial T}{\partial t} = \kappa \nabla^2 T, where T is , t is time, and \nabla^2 is the Laplacian operator; Poisson extended this to cases where \kappa varies spatially, leading to a more complex that required innovative integral transforms and series solutions for resolution. These developments enabled precise calculations of heat diffusion in contexts, such as the thermal behavior of metallic components or geological strata, and were later compiled in his 1835 treatise Théorie mathématique de la chaleur. In the realm of early thermodynamics, Poisson analyzed in fluids and gases, introducing concepts akin to mechanical equivalents of heat through studies of adiabatic processes. His 1823 paper "Sur la chaleur des gaz et des vapeurs," published in the Annales de chimie et de physique, examined the heat content and pressure-volume relations in gases during compression and expansion without heat exchange, deriving the relation PV^\gamma = \constant where \gamma = C_p / C_v is the ratio of specific heats—a precursor to modern adiabatic invariants and considerations in thermodynamic cycles. This analysis critiqued aspects of the by quantifying heat variations in vapors and ideal gases, providing quantitative insights into energy conversion that applied to steam engines and influenced Sadi Carnot's 1824 Réflexions sur la puissance motrice du feu, where Carnot referenced Poisson's results on gas temperatures for optimizing . Poisson further integrated thermal effects with mechanical deformation in his multi-volume Traité de mécanique (1811–1833), developing early frameworks for thermoelasticity by coupling heat conduction equations with elasticity to model temperature-induced stresses in solids, such as in heated structural elements. These contributions laid groundwork for understanding and contraction in continua, bridging conduction phenomena with practical applications in machine design and influencing subsequent thermodynamic developments.

Legacy

Impact on Mathematics

Siméon Denis Poisson's work profoundly shaped modern mathematics, particularly through his advancements in probability theory, partial differential equations, and analytical mechanics, establishing foundational tools that remain integral to contemporary research. His contributions bridged pure mathematics and its applications, influencing subsequent generations by providing rigorous frameworks for probabilistic inference and dynamical systems. Poisson's prolific output, exceeding 300 publications, solidified his role as a central figure in 19th-century French mathematics, succeeding Laplace as the preeminent analyst in Europe. In probability and statistics, Poisson's introduction of the in 1837 provided a cornerstone for modeling rare events and count data, enabling the development of modern . This distribution, derived as a limit of the binomial under conditions of low probability and high trials, became essential for applications ranging from to reliability analysis. Additionally, his 1835 formalization of the extended Bernoulli's ideas, justifying the convergence of empirical frequencies to theoretical probabilities and underpinning hypothesis testing and confidence intervals in statistics. These innovations formalized probabilistic reasoning, transforming it from heuristic to axiomatic. Poisson's equation, developed between 1811 and 1823, emerged as a ubiquitous model in (PDE) theory, generalizing to include source terms and serving as a prototype for elliptic PDEs. Its solutions via integral representations inspired the creation of Green's functions, which revolutionized boundary value problems by expressing solutions in terms of surface integrals, facilitating advances in and . This framework influenced the evolution of modern PDE methods, including variational principles and numerical solvers. In , Poisson brackets, introduced in 1809, provided a coordinate-free structure for dynamics, encapsulating the of and enabling the identification of conserved quantities through Poisson's theorem. These brackets laid the groundwork for later developments in Lie algebras and , where they analogize to commutators, and remain fundamental in and integrable systems. Poisson's legacy endures through numerous concepts bearing his name, such as the from 1823, which connects discrete sums to continuous integrals and underpins sampling theorems in . His work on definite integrals and formed the basis for subsequent breakthroughs in by mathematicians including Riemann and Weierstrass. Institutionally, as professor and examiner at the from 1802 onward, Poisson shaped French mathematical education by integrating advanced analysis into curricula and mentoring key figures like Dirichlet, ensuring the rigor of mathematical training in post-Revolutionary .

Impact on Physics

Poisson's formulation of the eponymous , \nabla^2 \phi = -4\pi \rho, derived in his 1811–1823 treatises on , provided a fundamental relation between and charge distribution, serving as a for the mathematical description of electrostatic fields. This became integral to James Clerk Maxwell's later unification of , enabling the modeling of in conductors and dielectrics. In applications, Poisson's development of the —implicit in his electrostatic analyses—facilitates solving boundary value problems for charged objects, such as spheres or planes, and remains a standard technique in for approximating fields near grounded surfaces. In , while seeking to refute Augustin-Jean Fresnel's wave theory of using a particle-based model, Poisson calculated in that the theory implied a bright spot at the center of a circular during —an outcome he deemed impossible. This spot, now known as the Poisson or , was experimentally confirmed by in 1819, unwittingly supporting the wave theory through validation of principles. This phenomenon laid early groundwork for understanding patterns, influencing subsequent developments in where similar effects describe behaviors in modern experiments. Poisson's 1827 work on the elasticity of isotropic materials introduced the Poisson ratio, defined as \nu = -\frac{\epsilon_\perp}{\epsilon_\parallel} where \epsilon_\perp and \epsilon_\parallel are transverse and longitudinal strains, establishing a key parameter for predicting material deformation under . With a typical value of 0.25–0.5 for most solids, this ratio is now standard in for characterizing auxetic behaviors and designing composites, such as foams or metamaterials, in applications from structures to biomedical implants. His broader contributions to elasticity theory, spanning 1823–1828, advanced the modeling of distributions in beams and plates, informing in . In , Poisson generalized the in 1823 to account for variable thermal conductivity, yielding \rho c \frac{\partial T}{\partial t} = \nabla \cdot (k \nabla T), which accurately describes in heterogeneous media. This formulation, detailed in his 1835 monograph, underpins models of in for simulating subsurface heat flow and in climate science for analyzing atmospheric processes. Poisson's prolific output during France's post-Revolutionary era elevated as a discipline, bridging Laplace's with experimental pursuits and fostering a rigorous analytical tradition that revitalized French science. His electrostatic theories directly influenced Michael Faraday's field concepts and William Thomson ()'s thermodynamic applications, while Poisson statistics—modeling rare independent events—finds modern use in to describe in coherent states and processes.

References

  1. [1]
    Siméon-Denis Poisson - Biography
    ### Summary of Siméon Denis Poisson's Biography
  2. [2]
    Siméon-Denis Poisson - Utah State University
    Poisson's contributions were not limited to probability. He worked with differential equations of mechanics, definite integrals, Poisson brackets in ...
  3. [3]
    Lecture Notes
    ### Summary of Siméon Denis Poisson's Life and Contributions
  4. [4]
    Siméon Denis Poisson | Research Starters - EBSCO
    Early Life​​ Siméon Denis Poisson was born in Pithiviers, France on June 21, 1781. His father, Siméon Poisson, was a soldier and neither he nor Poisson's mother ...
  5. [5]
    [PDF] SIMÉON-DENIS POISSON MATHEMATICS IN THE SERVICE OF ...
    The diverse aspects of Poisson's contributions to mathematics and to physics are examined, as well as the history of their development. This book reproduces ...
  6. [6]
    Évariste Galois (1811 - 1832) - Biography - MacTutor
    Poisson had reported that:- His argument is neither sufficiently clear nor sufficiently developed to allow us to judge its rigour. He did, however ...
  7. [7]
    A Social History of the “Galois Affair” at the Paris Academy of ...
    Jan 26, 2010 · In response to Poisson's report, Galois wrote several critical texts against the Academy and, more generally, against the Parisian scientific ...
  8. [8]
    English Translation of Poisson's "Recherches sur la probabilité des ...
    Feb 8, 2019 · English Translation of Poisson's "Recherches sur la probabilité des jugements en matière criminelle et en matière civile" / "Researches into the ...
  9. [9]
    [PDF] Poisson on the Poisson Distribution
    Poisson distribution. Simeon Denis Poisson (1781-1840) wrote widely on mathematics, mechanics, physics and probabil- ity, but he is best known today through ...
  10. [10]
    [PDF] probability and statistics throughout the centuries
    Siméon Denis Poisson (1781-1848). Page 7. Poisson (1781-1840) worked primarily in mathematical physics, and his most important contribution to probability was ...
  11. [11]
    A Tricentenary history of the Law of Large Numbers - Project Euclid
    Poisson (1837) proved this directly, not realizing that it follows directly from Jacob Bernoulli's Theorem. The LLN which Poisson (1837) considered first, and ...
  12. [12]
    [PDF] The Poisson kernel as an extremal function
    1.2 The Poisson kernel m,N. The Poisson integral and hence implicitly the Poisson kernel for. B were introduced in the 1820's (Poisson [16], [17]) for N = 2,3.
  13. [13]
    Mathematical Treasure: Works of Siméon-Denis Poisson
    A distinguished scientist and civil servant, he is remembered for his many contributions to applied mathematics, especially involving definite integrals and ...Missing: biography | Show results with:biography
  14. [14]
    The Mécanique Physique of Siméon Denis Poisson - jstor
    Poisson acknowledged that the law(s) governing the decrease of this force ... become smaller and as their number becomes larger. In such a way, with the.
  15. [15]
    [PDF] Seven Concepts Attributed to Siméon-Denis Poisson - arXiv
    Nov 29, 2022 · Poisson's search started as early as 1813 in his “Essay on definite integrals”25 [14] published in the Journal de l'´Ecole polytechnique. This ...
  16. [16]
    https://www.emis.de/journals/SIGMA/Bourguignon.html
  17. [17]
    [PDF] Finite Difference Method & Poisson equation - HAL
    Sep 1, 2025 · Poisson's equation first appearance was in electrostatics, when the French mathematician Siméon-Denis Poisson generalized Laplace's equation ∇2V ...Missing: publication | Show results with:publication<|separator|>
  18. [18]
    Poisson's Memoirs on Electricity - jstor
    Poisson's memoirs on electricity stand in striking contrast. On the one hand, he rests his calculations on a secure experimental foundation provided by Coulomb, ...
  19. [19]
    The spot in the shadow - Physics World
    Feb 13, 2014 · To everyone's surprise, and Poisson's chagrin, Arago observed the spot and Fresnel won the competition. The episode was deeply satisfying to ...
  20. [20]
    François Arago and the Birth of Interferometry
    Mar 1, 2023 · ... Fresnel submit his latest work on diffraction integrals. One of the referees of the prize competition was Siméon Denis Poisson (1781–1840) ...
  21. [21]
    First- and second-order Poisson spots | American Journal of Physics
    Aug 1, 2009 · In 1818 Fresnel submitted a treatise, Memoir on the Diffraction of Light,1 to the French Academy claiming that first-order diffraction ...
  22. [22]
    [PDF] Seven Concepts Attributed to Siméon-Denis Poisson
    2.3 Poisson's spot. Poisson's contribution to optics was not a successful treatment of the general phenomena of light but a prediction based on his ability ...
  23. [23]
    Water Waves in Nineteenth-Century Hydrodynamics
    Jun 3, 2003 · Poisson, Siméon Denis 1816 ''Mémoire sur la théorie des ondes,'' MAS, 1 (1816), 71–186 (read on 2 Oct and 18 Dec 1815, published in 1818).
  24. [24]
    The Physical Interpretation of the Wave Theory of Light - jstor
    60 Simeon-Denis Poisson (1781-1840). ... Fresnel's hesitation in accepting the implication of his and Arago's experimental work on the interference of polarised ...
  25. [25]
    [PDF] The First Five Births of the Navier-Stokes Equation
    close disciple Siméon Denis Poisson offered a first molecular theory. He considered a two-dimensional array of molecules, and computed the restoring force ...Missing: primary | Show results with:primary<|control11|><|separator|>
  26. [26]
    “Historical Introduction” from A Treatise on the Mathematical Theory ...
    Jan 1, 2007 · Poisson used it to investigate the propagation of waves through an isotropic elastic solid medium. He found two types of waves which, at great ...
  27. [27]
    Aspects of the foundations of infinitesimal analysis around 1820
    Poisson, S. D. 1823a. Mémoire sur la distribution de la chaleur dans les corps solides. J. Ecole polyt., 12, cah. 19, 1–144. Google Scholar. Poisson, S. D. ...
  28. [28]
    Entropy and the Experience of Heat - PMC - PubMed Central
    In 1808, and again in 1823, M. Poisson worked on the theory of sound. Moreover, in 1823, he published another paper with the title “Sur la chaleur des gaz et ...
  29. [29]
    Sadi Carnot and the Steam Engine: Nicolas Clément's lectures on ...
    Jan 5, 2009 · Sur la Chaleur des gaz et des vapeurs.' Ann. Chim. Phys. 23 (1823) p. 337–52.Google ScholarPoisson, S.-D.: 'Addition au Mémoire de M. Poisson.
  30. [30]
    Poisson's ratio at 200 | Nature Materials
    Oct 24, 2011 · Poisson's ratio is defined as the ratio of the size change in the direction perpendicular to the applied force versus the expanded length in the direction of ...
  31. [31]
    William Thomson, Lord Kelvin - Magnet Academy - National MagLab
    ... Siméon-Denis Poisson, for instance, with that of Faraday. He also applied the ideas he developed with George Gabriel Stokes regarding hydrodynamics to ...
  32. [32]
    [PDF] Poisson Quantum Information
    Aug 19, 2021 · Poisson quantum information examines the consequences of taking a Poisson limit in quantum information theory, using the intensity operator.