Untersuchungen über die Convergenz der beim problem der drei Körper auftretenden Reihenentwickelungen ...

Happel, H.

January 1900

Inaug.-dis.--Göttingen.

Three-body problem. Dynamics.

Ueber die Reduction des Drei-Körper-Problems auf die Integration einer einzigen Differential-Gleichung ...

Scholz, Paul Ludwig,

January 1900

Inaug.-diss.--Berlin. / Lebenslauf.

Three-body problem.

Isosceles-triangle solutions of the problem of three bodies /

Buchanan, Daniel.

January 1900

Thesis (PH. D.)--University of Chicago, 1911. / "Extracted from Carnegie institution of Washington. Publication no. 161." Includes bibliographical references.

Three-body problem.

The limiting case of periodic orbits near the lagrangian equilateral triangle solutions of the restricted three body problem

Hamilton, Rognvald Thore

January 1939

[No abstract available] / Science, Faculty of / Mathematics, Department of / Graduate

Three-body problem

A three-body scattering model using delta shell interactions.

Nieukerke, Karel Johannes.

January 1979

Thesis (Ph.D.) Dept. of Mathematical Physics, University of Adelaide, 1981. / Typescript (photocopy).

Heavy ions Three-body problem.

Effect of coordinate switching on simulation accuracy of translunar trajectories

Vautier, Mana P., Sinclair, Andrew J.,

January 2008

Thesis (M.S.)--Auburn University, 2008. / Abstract. Vita. Includes bibliographical references (p. 48-49) and index.

Space trajectories Three-body problem.

The isosceles three-body problem : a global geometric analysis /

Chesley, Steven Ross,

January 1998

Thesis (Ph. D.)--University of Texas at Austin, 1998. / Vita. Includes bibliographical references (leaves 119-126). Available also in a digital version from Dissertation Abstracts.

Three-body problem. Celestial mechanics.

A variational wave function for the ground state of He³, and its application to the D(p,y)He³ capture reaction

Banville, Marcel Roland

January 1965

The present work proposes trial wave functions for the three-body problem in nuclear physics taking into account the group theoretical classification of the states given by Derrick and Blatt and by Verde. We start from the Schroedinger equation in the internal variables (the interparticle distances) obtained by Derrick from a summation over the matrix elements for kinetic energy and potential energy extended over all variables except the internal variables. An “equivalent" Schroedinger equation is set up using a potential due to Eckart. This equation has the same form as the original Schroedinger equation in the region outside the range of the nuclear forces. The variables in this equation can be separated in a hyperspherical coordinate system and the resulting separate equations can be solved. Then using a superposition principle the solutions of the original equation are expanded in terms of solutions to the "equivalent" equation. The Rayleigh-Ritz variational procedure is used to determine the coefficients of the expansions with a given potential. Because of the computational labor involved significant approximation is made in allowing only the leading terms in the angular variables to appear in the expansions while keeping a sufficient number of radial terms to insure convergence. The present functions with a radial variable R = [formula omitted] give less than 1/2 of the binding energy predicted by Blatt, Derrick and Lyness (1962) who used a radial variable R = r₁₂ + r₂₃ + r₃₁. This shows that our approximation with the former radial variable is indeed too crude to predict a reliable value for the binding energy and that more angular terms must be included in the expansions, at least for the preponderent symmetric S-state. Wave functions derived by the Rayleigh-Ritz variational principle are used to calculate cross sections for the reaction D(p, γ)He³. The electric dipole cross section depends very sensitively on the potential used to derive the wave function and a comparison with experimental data provides a test of the various model assumptions used to describe the nuclear interaction. A realistic potential must contain a tensor potential plus a hard core in the central potential. The tensor interaction couples the S and D states and is necessary to explain the quadrupole moment of He³ while the hard core produced the required mixed-symmetry S-state. The experimentally observed isotropic component of the gamma ray yield is attributed to a magnetic dipole transition between a continuum quartet S-state and the mixed-symmetry component of the ground state wave function. For a range of the variable parameter used in the calculation comparison with experiment requires a 5% admixture of the mixed-symmetry S-state in the ground state wave function. / Science, Faculty of / Physics and Astronomy, Department of / Graduate

Helium -- Isotopes

Three-body problem

Visualizing solutions of the circular restricted three-body problem

Trim, Nkosi Nathan.

January 2009

Thesis (M.S.)--Rutgers University, 2009. / "Graduate Program in Mathematical Sciences." Includes bibliographical references (p. 40).

An evaluation of approximation methods for three body scattering problems

Schwebel, Solomon L.

January 1954

Thesis--New York University. / Bibliography: p. [124]-125.