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Carl Neumann

Carl Neumann (7 May 1832 – 27 March 1925) was a German mathematician renowned for his foundational contributions to potential theory, integral equations, and the Dirichlet principle, as well as his role in advancing mathematical physics through studies on electrodynamics and thermodynamics.^[1] Born in Königsberg, Prussia (now Kaliningrad, Russia), to the prominent physicist Franz Neumann, Carl Neumann pursued his education at the University of Königsberg, where he earned his PhD in 1855 with a thesis on hyperelliptic integrals under the supervision of Friedrich Richelot.^[1] He later habilitated at the University of Halle in 1858 with work on the polarization of light, marking the start of his academic career as a privatdozent there.^[1] Over the next decade, Neumann held professorships at the University of Basel (1863–1865) and the University of Tübingen (1865–1868), before settling at the University of Leipzig in 1868, where he taught until his retirement in 1911.^[1] Neumann's mathematical legacy includes pioneering solutions to the Dirichlet problem for potential theory, first addressed in his 1861 paper and refined in 1870, where he introduced the concept of the "logarithmic potential" to resolve key challenges in the field.^[1] He also made significant advances in integral equations, developing methods that influenced later work on Fredholm equations, and engaged in debates with Hermann von Helmholtz on the foundations of electrodynamics, contributing formulations that bridged mechanics and electromagnetism.^[2]^[1] In thermodynamics, his 1875 Lectures on the Mechanical Theory of Heat provided rigorous mathematical treatments of energy conservation and heat phenomena, drawing on his father's experimental insights. A key figure in 19th-century mathematical institutions, Neumann co-founded the prestigious journal Mathematische Annalen in 1868 alongside Alfred Clebsch, serving as an editor and publishing numerous influential papers therein.^[1] His notable publications also encompass Vorlesungen über Riemann's Theorie der Abel'schen Integrale (1865, revised 1884), which clarified Riemann's complex analysis on abelian integrals and Riemann surfaces, and Zur Theorie des Logarithmischen und des Newtonschen Potentials (1870), solidifying his impact on partial differential equations.^[1] Neumann's work left enduring marks on mathematics, with concepts like the Neumann series (for inverting elements in Banach algebras), the Neumann-Poincaré operator in boundary value problems, and the Neumann boundary condition in partial differential equations bearing his name.^[3]^[1] As a mentor, he supervised 28 doctoral students, fostering a lineage that extends to over 20,000 descendants in the mathematical genealogy.^[4] His rigorous, principle-driven approach influenced generations, establishing him as a bridge between classical analysis and modern functional analysis.^[1]

Early Life and Education

Family and Childhood

Carl Gottfried Neumann was born on 7 May 1832 in Königsberg, Prussia (now Kaliningrad, Russia), into a prominent academic family.^[1] He was the eldest son of Franz Ernst Neumann, a renowned physicist and mineralogist who served as professor of mineralogy and physics at the University of Königsberg, and Luise Florentine Hagen, the sister-in-law of astronomer Friedrich Wilhelm Bessel.^[1]^[5] Neumann's siblings included his brother Franz Ernst Christian Neumann, a distinguished histologist and pathologist; Friedrich Julius Neumann, an economist; and sister Luise Neumann, a painter.^[1] Growing up in this intellectually stimulating household, Neumann was immersed in discussions of physics and mathematics from an early age, influenced by his father's pioneering research in optics and electrodynamics.^[5] He completed his primary and secondary education in Königsberg, attending the Altstadt Gymnasium.^[1]

Academic Training

Carl Neumann enrolled at the University of Königsberg in 1850, where he pursued studies in mathematics and physics, benefiting from the vibrant academic environment shaped by his father's influential position as a professor of physics.^[1]^[6] He completed his doctoral studies under the supervision of Friedrich Julius Richelot, earning his Dr. phil. degree in 1855.^[1]^[6] His dissertation, titled De problemate quodam mechanico, quod ad primum integralium ultraellipticorum classem revocatur, explored the application of ultraelliptic integrals to a mechanical problem, highlighting his early proficiency in complex analysis and its intersections with mechanics.^[1]^[7] Following his doctorate, Neumann prepared for an academic career by pursuing his habilitation, which he submitted in 1858 at the University of Halle under Eduard Heine.^[1] The habilitation thesis, Explicare tentatur, quomodo fiat, ut lucis planem polarisationis per vires electricas vel magneticas declinetur, investigated the alteration of light's polarization plane by electrical or magnetic forces, demonstrating his growing interest in mathematical physics and optical phenomena.^[1] This work marked a key milestone, qualifying him to lecture independently and underscoring his transition from pure analysis to applied mathematical problems.^[8]

Academic Career

Early Positions

After completing his doctoral dissertation on hyperelliptic integrals in 1855, which laid the groundwork for his subsequent teaching on advanced topics in analysis, Carl Neumann advanced in his academic career at the University of Halle. In 1858, he habilitated with a thesis on the polarization of light, qualifying as a Privatdozent, enabling him to lecture independently, and by 1863, he was appointed extraordinary professor of mathematics there.^[9]^[10] That same year, Neumann accepted a full professorship in mathematics at the University of Basel, where he focused on instructing courses in pure and applied mathematics until 1865.^[9] His tenure in Basel was brief but marked his growing reputation, leading to further opportunities in German academia. In 1865, Neumann relocated to the University of Tübingen as ordinary professor of mathematics, a position he held until 1868, during which he contributed to the institution's mathematical curriculum and research environment.^[11] Toward the end of this period, in 1868, he co-founded the influential journal Mathematische Annalen alongside Alfred Clebsch, taking on an initial editorial role to promote rigorous mathematical scholarship.^[12]

Professorships and Later Roles

In 1868, Carl Neumann was appointed as full professor of mathematics at the University of Leipzig, a position he held until his retirement in 1911.^[1] Prior to this appointment, he had served in professorial roles at the universities of Basel (1863–1865) and Tübingen (1865–1868), which served as stepping stones to his long-term position in Leipzig.^[1] That same year, Neumann co-founded the influential mathematical journal Mathematische Annalen alongside Alfred Clebsch, with the first volume appearing in 1869.^[1] He played a key role in its early editorial management, serving as a primary editor from 1873 to 1876 (volumes 6–9) and contributing to its ongoing direction thereafter, which helped establish it as a leading venue for mathematical research in Germany.^[1]^[8] During his tenure at Leipzig, Neumann took on significant administrative duties, including shaping the journal's editorial policies in collaboration with publisher B.G. Teubner.^[1] He was also a dedicated mentor, supervising 28 doctoral students according to the Mathematics Genealogy Project and educating more than two generations of future Gymnasium mathematics teachers.^[4]^[8] Neumann retired from his professorship in 1911 but remained in Leipzig for the rest of his life, passing away there on March 27, 1925.^[1]

Contributions to Mathematics

Potential Theory and Boundary Problems

Carl Neumann's foundational contributions to potential theory centered on solving boundary value problems for the Laplace equation, providing rigorous methods that advanced both mathematical analysis and physical applications. In his 1861 paper, he tackled the Dirichlet problem in the plane, which seeks a harmonic function inside a domain matching given continuous boundary values. Neumann employed Riemann's integral method, representing the solution via the logarithmic potential—a term he introduced—to construct explicit integral expressions for the potential without invoking the variational Dirichlet principle. This approach circumvented Weierstrass's critiques, which highlighted the lack of rigorous proof for the existence of minimizers in Riemann's variational framework, by relying instead on geometric assumptions and physical analogies like fluid flow.^[13]^[14] A key innovation in Neumann's potential theory was the introduction of Neumann boundary conditions, which require the normal derivative of the harmonic function to vanish on the boundary, \frac{\partial u}{\partial n} = 0. These conditions model scenarios such as electrically insulated surfaces in electrostatics or impermeable barriers in fluid dynamics, extending the Dirichlet framework to problems where flux rather than value is prescribed on the boundary. Neumann developed these in the context of his boundary value investigations during the 1860s, establishing them as essential for mixed boundary problems in potential theory.^[1]^[13] In 1870, Neumann provided a more comprehensive treatment of the Dirichlet problem, proving the existence of solutions for harmonic functions in bounded domains with continuous boundary data. His method of the arithmetic mean iteratively averages boundary values to generate a sequence of harmonic functions that converges uniformly to the solution, under assumptions of domain convexity and smoothness to ensure contraction. This technique addressed lingering concerns about existence post-Weierstrass and laid groundwork for later developments in elliptic partial differential equations.^[13]^[15] Neumann's boundary problem solutions in potential theory had direct applications to hydrodynamics, where they describe steady, irrotational flows around obstacles via velocity potentials satisfying Neumann conditions on impermeable surfaces, and to electrostatics, modeling potential distributions near charged conductors with specified surface charges or insulation. These mathematical advancements provided analytical tools for predicting physical behaviors in these fields.^[1]^[13] To solve the integral equations of the second kind that arise in these potential representations, Neumann introduced the Neumann series in his 1877 monograph. For an equation \phi(x) = f(x) + \lambda \int_a^b K(x,y) \phi(y) \, dy, the solution is given by the convergent series \phi(x) = \sum_{n=0}^\infty \lambda^n (K^n f)(x), where K^n denotes the n-fold iterated kernel operator K, and convergence holds when the spectral radius or norm of the operator K is sufficiently small (less than 1/|\lambda|). This iterative expansion, analogous to a geometric series in operator form, enabled practical computation of solutions in potential theory and influenced subsequent operator theory. In specific contexts, variants incorporate factorial terms for boundedness, such as \sum_{n=0}^\infty \frac{(\lambda K)^n}{n!} f when treating exponential-like resolvents, but the standard form proved pivotal for boundary integral methods.^[16]^[13] Carl Neumann made significant contributions to the theory of Abelian integrals through his 1865 publication Vorlesungen über Riemann's Theorie der Abel'schen Integrale, which provided a systematic exposition and completion of Bernhard Riemann's unfinished ideas on the subject.^[1] This work elaborated on Riemann's vision of associating multi-valued analytic functions with Riemann surfaces, particularly emphasizing the inversion problem for integrals of algebraic functions of higher degree.^[1] By organizing Riemann's fragmentary notes into a coherent framework, Neumann clarified the role of Abelian integrals in representing points on algebraic curves via their periods, thereby popularizing these concepts among contemporary mathematicians.^[17] Neumann's advancements in elliptic and Abelian functions focused on period relations and modular transformations, exploring how these functions behave under changes in the complex plane and their connections to the topology of Riemann surfaces.^[1] He investigated the order of connectivity of these surfaces, demonstrating how the periods of Abelian differentials determine the function's multi-valued nature and enable explicit expressions for inverses.^[1] These efforts built directly on earlier developments in elliptic functions, extending their properties to more general settings while maintaining analytical rigor. In the context of Abelian integrals, Neumann extended Carl Gustav Jacob Jacobi's foundational work on theta functions, integrating them as tools for resolving the inversion of multi-periodic integrals.^[18] By incorporating theta functions into Riemann's framework, he facilitated the representation of Abelian functions as sums or products involving these special functions, enhancing their utility in solving period problems.^[18] Neumann's influence on hyperelliptic integrals, which arise from genus-two curves, stemmed from his broader systematization of Abelian theory and informed subsequent developments in algebraic geometry.^[18] His treatment paved the way for viewing hyperelliptic integrals as special cases of general Abelian integrals, contributing to the geometric interpretation of Jacobians and the moduli space of curves.^[1] This early precursor in his 1855 doctoral thesis on elliptic integrals further underscored his foundational role in these areas.^[1]

Contributions to Physics

Electrodynamics Theories

During the 1860s and 1870s, Carl Neumann provided significant theoretical support for Wilhelm Weber's action-at-a-distance electrodynamics, which incorporated finite propagation speeds for electromagnetic interactions to align with experimental observations of current-induced forces.^[19] Neumann formalized Weber's force law using Lagrangian mechanics, deriving it from a velocity-dependent potential that ensured conservation principles while avoiding instantaneous action across distances. This approach emphasized direct interactions between charges modulated by their relative velocities and accelerations, contrasting with emerging field concepts by maintaining a corpuscular view of electricity.^[20] In 1870, Neumann engaged in a prominent debate with Hermann von Helmholtz over energy conservation in electrodynamic actions, prompted by Helmholtz's critique that Weber's velocity-dependent forces could lead to unphysical energy gains or losses in certain motion scenarios.^[21] Helmholtz argued for a field-mediated theory to uphold strict conservation, as detailed in his paper "Über die Theorie der Elektrodynamik," where he analyzed Weber-Neumann potentials and proposed modifications involving gauge transformations. Neumann defended the framework by refining the potentials to demonstrate compatibility with energy principles under specific boundary conditions, though he rejected Helmholtz's broader shift toward continuous media. This exchange highlighted tensions between action-at-a-distance models and conservation laws, influencing subsequent electromagnetic theorizing. Neumann initially expressed skepticism toward James Clerk Maxwell's field theory, favoring velocity-dependent potentials that directly linked forces to charge motions without invoking intermediary fields. He critiqued Maxwell's displacement current and wave propagation as overly speculative, preferring the mathematical elegance of Weber's law for explaining induction and Ampèrian forces.^[22] In his formulations, Neumann expressed the electrodynamic potential for interacting charges as

\psi = \frac{e}{r} \left(1 - \frac{\dot{r}^2}{2c^2}\right),

where e is the charge product, r the distance, \dot{r} the relative radial velocity, and c the propagation speed, enabling derivation of Weber's force with finite-speed corrections.^[19] This potential incorporated tools from his mathematical potential theory to model retardation effects implicitly. In his later career, around 1901–1904, Neumann shifted his views, acknowledging the advantages of Maxwell's theory, particularly its unification of optics and electromagnetism as extended by Heinrich Hertz's experimental validations. He praised the field's ability to handle radiation and thermal conduction phenomena more comprehensively than action-at-a-distance models, though he retained reservations about its foundational assumptions. This evolution reflected broader acceptance of field theories amid empirical successes, marking Neumann's contributions as a bridge between competing 19th-century paradigms.^[20]

Mechanics and Thermodynamics

Neumann made significant contributions to analytical mechanics, particularly through his efforts to formalize the foundational principles of the Galilean-Newtonian theory. In his 1869 inaugural lecture at the University of Leipzig, published in 1870, he outlined an axiomatic approach to mechanics, emphasizing the derivation of mechanical laws from basic hypotheses rather than empirical observations alone, which influenced later discussions on the epistemology of physics.^[23] This work explored variational principles and Hamiltonian formulations by treating mechanical systems in terms of generalized coordinates and integrals of motion, aligning with Jacobi's earlier methods in analytical dynamics.^[24] In his 1855 doctoral dissertation at the University of Königsberg, Neumann applied hyperelliptic integrals—building on the work of Jacobi and Abel—to solve a mechanical problem involving the motion of a particle on a sphere under a quadratic potential.^[9] The dissertation demonstrated how these integrals express solutions for such systems, providing exact treatments where series approximations fail, and highlighted their utility in non-linear dynamical systems.^[1] This application extended hyperelliptic function theory to practical mechanics, offering conceptual insights into integrable systems beyond perturbative methods. Neumann's explorations in hydrodynamics appeared in his 1883 monograph Hydrodynamische Untersuchungen, where he analyzed the motion of rigid bodies, such as spheres, in bounded fluids using potential theory.^[25] He derived expressions for fluid potentials to describe irrotational flows around moving spheres near fixed planes or spherical boundaries, emphasizing the role of velocity potentials in determining hydrodynamic forces and pressures.^[25] Although vortices were not the primary focus, his potential-based framework laid groundwork for understanding vortical structures in confined flows by analogy to electrostatic problems. In thermodynamics, Neumann delivered lectures in 1875 titled Vorlesungen über die mechanische Theorie der Wärme, interpreting heat phenomena through mechanical principles. He reformulated entropy as a mechanical quantity, deriving the second law from variational considerations of energy dissipation in isolated systems, and introduced notation for inexact differentials (δQ and δW) to distinguish reversible and irreversible processes. This mechanical perspective bridged classical thermodynamics with dynamics, portraying heat as molecular motion while avoiding molecular hypotheses, and emphasized the conservation of energy in thermal-mechanical conversions.

Recognition and Legacy

Awards and Academic Honors

Throughout his career, Carl Neumann received numerous accolades from prestigious scientific institutions, reflecting his significant contributions to mathematics and physics. In 1864, he was elected a corresponding member of the Königlichen Societät der Wissenschaften in Göttingen, later becoming a foreign member in 1868, a status he held until his death in 1925 as the academy evolved into the Akademie der Wissenschaften zu Göttingen.^[1] This early recognition came during his rising academic prominence, shortly after his habilitation and initial teaching positions. Neumann's honors continued to accumulate in later years, underscoring his enduring influence. He was elected a corresponding member of the Königlich-Preussischen Akademie der Wissenschaften in Berlin in 1893, maintaining membership as it became the Preussischen Akademie der Wissenschaften.^[1] In 1895, he joined as a corresponding member of the Königlich-Bayerischen Akademie der Wissenschaften in Munich, continuing with the Bayerischen Akademie der Wissenschaften thereafter.^[1] These elections highlighted his standing among Germany's leading scholars, bolstered by his long tenure as a professor at the University of Leipzig from 1868 to 1911. Finally, in 1919, at age 87, Neumann was elected a full member of the Mathematical-Physical Class of the Sächsischen Akademie der Wissenschaften in Leipzig.^[1] A pinnacle of his recognitions was the Pour le Mérite order for sciences and arts, awarded in 1897 for his scientific achievements, following in the footsteps of his father, Franz Neumann.^[26] This prestigious Prussian honor, limited to exceptional contributors, affirmed his international esteem, as evidenced by his corresponding and foreign memberships across major German academies, which often served as gateways to broader European scholarly networks.^[1]

Influence on Modern Mathematics and Physics

Neumann boundary conditions, which prescribe the value of the normal derivative of the solution on the boundary of a domain, remain a fundamental concept in the analysis and numerical solution of partial differential equations (PDEs). These conditions are widely applied in physics to model scenarios where flux or gradient is specified, such as insulating surfaces in heat conduction or rigid walls in wave propagation. In acoustics, they represent sound-hard boundaries that reflect waves without penetration, facilitating simulations of room acoustics and ultrasonic imaging. In quantum mechanics, Neumann conditions appear in the Schrödinger equation for waveguides and potential barriers, describing scenarios with zero probability current at the boundary, as seen in studies of quantum scattering and bound states.^[27]^[28]^[29] The Neumann series, originally developed in the context of potential theory for solving linear integral equations, forms a cornerstone of functional analysis and operator theory. It enables the expansion of the inverse of an operator as a power series when the spectral radius is less than one, providing a perturbative method for approximating solutions. This approach directly influenced the theory of Fredholm integral equations, where it underpins the resolvent formalism, and David Hilbert's extensions to infinite-dimensional Hilbert spaces, bridging classical analysis with modern operator algebras. Neumann's work on these series laid groundwork for understanding compactness and invertibility in Banach spaces, essential to spectral theory.^[30]^[31]^[32] Neumann's efforts in co-founding Mathematische Annalen in 1868 with Alfred Clebsch elevated it to a premier venue for advanced mathematical research, fostering rigorous publications that defined standards for 19th- and 20th-century mathematics. His editorial contributions, including multiple papers in early volumes, helped establish the journal's focus on pure and applied analysis, influencing the global mathematical community by prioritizing innovative, peer-reviewed work. These foundational influences trace back to Neumann's advancements in potential theory, where he addressed boundary value problems for harmonic functions.^[1] Neumann's academic legacy extends through his supervision of 28 doctoral students at institutions like Leipzig University, resulting in over 20,000 descendants via the Mathematics Genealogy Project, many advancing fields like spectral theory through extensions of operator methods. In modern numerical analysis, Neumann boundary conditions are embedded in finite element methods to handle flux specifications in simulations of structural mechanics and fluid dynamics, ensuring conservation properties in discretized models. Likewise, the Neumann series supports iterative solvers for large-scale linear systems in computational physics, enhancing convergence in preconditioned algorithms for integral equations.^[4]^[33]^[34]

Selected Publications

Key Monographs

Neumann's Vorlesungen über Riemanns Theorie der Abelschen Integrale (1865), published in Leipzig by Teubner, offered a systematic exposition of Bernhard Riemann's foundational ideas on Abelian integrals, filling gaps in Riemann's original lectures by providing rigorous proofs, extensions to higher connectivity, and applications to Riemann surfaces.^[1] This work was instrumental in disseminating Riemann's complex analysis to a broader audience, emphasizing the topological aspects of multi-valued functions and their inverses, and it underwent a second edition in 1884 to incorporate further developments.^[8] In Untersuchungen über das logarithmische und Newtonsche Potential (1877), also from Teubner in Leipzig, Neumann advanced potential theory by developing methods for solving boundary value problems involving logarithmic and Newtonian potentials, including the introduction of what became known as Neumann's boundary condition for the Laplace equation. The monograph laid groundwork for handling irregular boundaries in two and three dimensions, influencing subsequent work in electrostatics and fluid dynamics through its analytical techniques for series expansions.^[35] Neumann's Hydrodynamische Untersuchungen, nebst einem Anhange über die Probleme der Elektrostatik und der magnetischen Induction (1883), published in Leipzig, provided a detailed mathematical framework for hydrodynamic phenomena, analyzing potentials, vortex motions, and wave propagation in ideal fluids using integral equations and spherical harmonics.^[36] The appendix extended these methods to electrostatic and magnetic problems, demonstrating analogies between fluid and electromagnetic fields, and the text remains a reference for classical hydrodynamics. Among Neumann's lecture-based monographs, Vorlesungen über die mechanische Theorie der Wärme (1875), issued by Teubner in Leipzig, presented a comprehensive treatment of thermodynamics from a mechanical perspective, clarifying concepts such as exact and inexact differentials in the context of the first and second laws.^[37] Drawing on contemporary debates, it emphasized the energy principle and entropy, contributing to the axiomatization of thermodynamic processes and influencing pedagogical approaches in the field.

Major Journal Articles

Neumann's 1861 article in the Journal für die reine und angewandte Mathematik addressed the Dirichlet problem for Laplace's equation in the plane, employing a method inspired by Riemann's approach to partial differential equations. Titled "Ueber die Integration der partiellen Differentialgleichung ∂²Φ/∂x² + ∂²Φ/∂y² = 0," the paper introduced the logarithmic potential as a tool for constructing solutions that satisfy given boundary values, drawing analogies to physical problems like steady-state heat conduction. This work provided an explicit geometric construction for the solution in specific regions, laying foundational techniques for potential theory while avoiding the controversial Dirichlet principle.^[13] In 1870, Neumann published "Zur Theorie des Logarithmischen und des Newton’schen Potentiales. Erste Mittheilung" in the Berichte über die Verhandlungen der Königlich Sächsischen Gesellschaft der Wissenschaften zu Leipzig, focusing on existence proofs for boundary value problems in potential theory. The paper introduced the method of the arithmetic mean, an iterative process that averages boundary values over circles to construct harmonic functions converging to the solution of the Dirichlet problem under convexity assumptions on the boundary. This physically motivated technique established rigorous existence without relying on variational principles, influencing subsequent developments in elliptic boundary value problems.^[13] That same year, Neumann contributed to electrodynamics with a paper critiquing Helmholtz's reformulation, published as "Einige Bemerkungen zu H. Helmholtz's Abhandlung 'Über die Theorie der Elektrodynamik'" in Annalen der Physik und Chemie. Debating energy conservation in action-at-a-distance theories, Neumann defended Weber's electrodynamic potential against Helmholtz's velocity-dependent generalizations, arguing that the latter introduced inconsistencies in explaining induction phenomena. The exchange highlighted tensions between conservative principles and empirical laws, shaping late-19th-century discussions on electromagnetic foundations.^[1] During the 1870s and 1880s, Neumann published a series of articles in Mathematische Annalen advancing the theory of integral equations, notably his 1877 monograph Untersuchungen über das logarithmische und Newtonsche Potential in which he introduced the Neumann series for integral equations of the second kind, demonstrating convergence under certain kernel conditions and applying it to boundary integral formulations in potential theory. These works formalized resolvent expansions, providing tools for spectral analysis and influencing later generalizations in operator theory.^[1]

References

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Carl Neumann (1832 - 1925) - Biography - MacTutor
Carl Neumann was a German mathematician who worked on the Dirichlet principle and on integral equations. He was one of the founders of Mathematische Annalen.
[2]
Carl Neumann's Contributions to Electrodynamics - ADS
I show how Neumann contributed to physics at an important stage in its development and how his work led to a polemic with Hermann Helmholtz (1821-1894). Neumann ...
[3]
Carl Neumann Criterion -- from Wolfram MathWorld
Let A be a unital Banach algebra. If a in A and ||1-a||<1, then a^(-1) can be represented by the series sum_(n=0)^(infty)(1-a)^n.
[4]
Carl Gottfried Neumann - The Mathematics Genealogy Project
According to our current on-line database, Carl Neumann has 28 students and 20296 descendants. We welcome any additional information. If you have additional ...
[5]
Franz Neumann (1798 - 1895) - Biography - MacTutor
In 1830, he married Luise Florentine Hagen, Karl Hagen's daughter but Luise died in 1838 having given birth to five children. Five years later Neumann married ...
[6]
[PDF] IAMP Bulletin January 2024
For example,. Carl Gottfried Neumann (1832-1925), Neumann's son, and Rudolph Friedrich Alfred. Clebsch (1833-1872), practiced a mathematical physics with an ...
[7]
Neumann, Carl Gottfried | Encyclopedia.com
After passing the examination for secondary school teaching he obtained his doctorate in 1855; in 1858 he qualified for lecturing in mathematics at Halle, where ...Missing: training | Show results with:training
[8]
(PDF) The Königsberg Mathematico-Physical Seminar - ResearchGate
Jan 29, 2024 · ... Carl Gottfried Neumann (1832-1925), Neumann's son, and Rudolph Friedrich Alfred. Clebsch (1833-1872), practiced a mathematical physics with ...Missing: childhood | Show results with:childhood
[9]
Carl Gottfried Neumann | Science in Context | Cambridge Core
Sep 26, 2008 · In 1858 he became Privatdozent, and in 1863 Professor of Mathematics at Halle. Later that same year he moved to Basel, and in 1865 he became ...Missing: early positions
[10]
Carl Gottfried Neumann - Cambridge University Press
In 1858 he became Privatdozent, and in 1863 Professor of Mathematics at. Halle. Later that same year he moved to Basel, and in 1865 he became Ordinary.
[11]
Außerordentlicher Professor für Mathematik: Eberhard Karls ...
Carl Gottfried Neumann; Außerordentlicher Professor für Mathematik: Eberhard Karls Universität Tübingen (1865/1868). Außerordentlicher Professor für ...
[12]
Aims and scope | Mathematische Annalen
The journal Mathematische Annalen was founded in 1868 by Alfred Clebsch and Carl Neumann. It was continued by Felix Klein, David Hilbert, Otto Blumenthal ...
[13]
[PDF] From Attraction Theory to Existence Proofs - Numdam
Carl Neumann's earliest work on potential theory had revolved around the Dirichlet problem; his other interests in the period show that he was influenced by ...
[14]
https://www.numdam.org/item/JMPA_1861__59__335_0/
[15]
https://www.numdam.org/item/BSMF_1870_2_1_49_0/
[16]
Untersuchungen über das logarithmische und Newton'sche Potential
May 17, 2007 · Untersuchungen über das logarithmische und Newton'sche Potential. by: Neumann, Carl, 1832-1925; Newton, Isaac, Sir, 1642-1727.
[17]
Vorlesungen über Riemann's Theorie der Abel'schen Integrale
Dec 12, 2008 · Vorlesungen über Riemann's Theorie der Abel'schen Integrale. by: Neumann, Carl, 1832-1925. Publication date: 1884. Topics: Functions, Abelian, ...Missing: mathematician integrals
[18]
Introduction | SpringerLink
Mar 13, 2013 · This was done by Göpel and Rosenhain and extended by Hermite and Carl Neumann. In this way the hyperelliptic integral and beyond it the general ...
[19]
None
### Summary of Neumann's 1868 Paper on Electrodynamic Potential
[20]
[PDF] Wilhelm Weber's Main Works on Electrodynamics Translated ... - IFGW
When Carl Neumann published the present paper of 1868, he was not aware of Weber's potential energy V introduced in 1848. This information was acknowledged ...
[21]
[PDF] Helmholtz and the Velocity Gauge - Kirk T. McDonald
3,4 The gauge (1) considered by Helmholtz in 1870, well before the notion of a gauge was appreciated, is now called the α-Lorentz gauge [63, 66, 77] or the ...Missing: debate | Show results with:debate
[22]
The Rise of Classical Field Theory (Chapter 2)
Oct 1, 2019 · Adhering to the mechanical conception of substance, Maxwell, in his criticism of Neumann, denied this possibility and thus failed in this ...
[23]
On the Principles of the Galilean-Newtonian Theory
On the Principles of the Galilean-Newtonian Theory. An Academic Inaugural Lecture Delivered in the Auditorium of the University of Leipzig on 3 November 1869.
[24]
Carl Neumann's Contributions to Electrodynamics
His investigations were aimed at founding a mathematically exact physical theory of electrodynamics, following the approach of Carl G.J. Jacobi (1804–1851) on ...
[25]
Hydrodynamische untersuchungen: nebst einem Anhange über die ...
Title, Hydrodynamische untersuchungen: nebst einem Anhange über die Probleme der Elektrostatik und der magnetischen Induction ; Author, Carl Neumann ; Publisher ...
[26]
https://www.orden-pourlemerite.de/mitglieder/carl-gottfried-neumann/
[27]
[PDF] introduction to partial differential equations - UNCW
Jun 19, 2015 · Neumann boundary conditions - the derivative of the solution takes fixed val- ues on the boundary. These are named after Carl Neumann (1832-1925) ...
[28]
[PDF] Wave chaos in acoustics and elasticity - ChaosBook.org
In addition losses, at interfaces and boundaries can be quite substantial; typical boundary conditions are Dirichlet, Neumann or Robin boundary conditions.
[29]
[PDF] On the discrete spectrum of a spatial quantum waveguide with a disc ...
We im- pose the Neumann boundary condition on a disc window of radius a and Dirichlet boundary conditions on the remained part of the boundary of the strip.Missing: mechanics | Show results with:mechanics
[30]
[PDF] FREDHOLM, HILBERT, SCHMIDT Three Fundamental Papers on ...
Dec 15, 2011 · Fredholm is evident, Hilbert was concerned not so much with solving integral equations ... Neumann series we find that. K = K1 + λK2 + λ2K3 ...
[31]
[PDF] hilbert space applications in integral equations - Cal State LA
by Neumann in 1870 to be equivalent to the solution of an integral equation. This is similar to the procedure used by Poisson and Liouville, and leads to good ...
[32]
The evolution and applications of operator theory - AIP Publishing
Sep 4, 2025 · This paper presents a conceptual and historical overview of operator theory as a unifying framework in mathematics and physics.
[33]
Notes on solving PDEs by the Finite Element Method - SfePy
Neumann Boundary Conditions That is why Neumann conditions in FEM terminology are called Natural Boundary Conditions. These conditions are a part of weak form ...
[34]
[PDF] A probabilistic analysis of the Neumann series iteration
The proof of the above lemma and theorem can be found in [2, p. 457]. The Neumann series iteration is the numerical algorithm we will use throughout this paper.
[35]
Solution of the Neumann problem for the Laplace equation - EuDML
... Untersuchungen über das logarithmische und Newtonsche Potential, Teubner Verlag, Leipzig, 1877. (1877); Zur Theorie des logarithmischen und des Newtonschen ...
[36]
Hydrodynamische Untersuchungen - Carl Neumann - Google Books
Jul 18, 2023 · Dieses klassische Werk bietet eine eingehende Untersuchung der Hydrodynamik sowie spezifische Studien zu den Problemen der Elektrostatik und ...
[37]
Vorlesungen über die mechanische Theorie der Wärme
Jun 7, 2016 · Vorlesungen über die mechanische Theorie der Wärme. Author, Neumann (Carl Gottfried). Publisher, Druck und Verlag von B. G. Teubner, 1875.