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Table of Contents
Part1. Modeling Compound-Nuclear Reactions
Chapter1. Towards more predictive nuclear reaction modelling
Chapter2. Modelling compound nuclear reactions with EMPIRE
Chapter3. CoH3: The Coupled-Channels and Hauser-Feshbach Code
Part2. Beyond Statistical Descriptions
Chapter4. Recent advances in R-matrix data analysis
Chapter5. The transition from isolated resonances to the continuum
Chapter6. Cross section correlation functions and deviations from the Porter-Thomas distribution
Chapter7. Moldauers sum rule implies superradiance in compound nuclear reactions 48
Chapter8. Multi-step direct reaction models including collectivity in nucleon induced reactions
Chapter9. New symmetry-adapted ab initio approach to nuclear reactions for intermediate-mass nuclei
Part3. Optical Models
Chapter10. Linking nuclear reactions and nuclear structure to study exotic nuclei using the dispersive optical model
Chapter11. Microscopic optical potential from chiral effective field theory
Part4. Level Densities
Chapter12. Nuclear level densities: from empirical models to microscopic methods
Chapter13. Problem of level densities in compound nuclear reactions
Chapter14. Nuclear shell model and level density
Chapter15. Constraining level densities using spectral data
Chapter16. Rotational enhancement factor for nuclear level density
Chapter17. Role of fluctuations on the pairing properties of nuclei in the random spacing model
Part5. Gamma-ray Strength Functions
Chapter18. Gamma strength functions and the Brink-Axel hypothesis
Chapter19. Gamma-ray strength functions and GDR cross sections in the IAEA photonuclear data project
Chapter20. Neutron capture on actinides studied with DANCE
Chapter21. Deconvolution of the photon strength function
Part6. Oslo Method
Chapter22. Attempting to close the loop on the Oslo technique at 198Au: constraining the nuclear spin distribution
Chapter23. Impact of restricted spin-ranges in the Oslo method: The example of (d, p)240Pu
Chapter24. Systematics of gamma-ray strength functions within the shell model
Part7. Surrogate Nuclear Reactions
Chapter25. Future perspectives for surrogate-reaction studies at storage rings
Chapter26. Prospects for surrogate neutron capture measurements with radioactive ion beams and GODDESS
Chapter27. Surrogate reaction method for neutron capture and other reactions on unstable nuclei
Chapter28. Neutron capture cross sections from surrogate reaction data and theory: connecting the pieces with a Markov-Chain Monte Carlo approach
Chapter29. Neutron transfer reactions for deformed nuclei using a Sturmian basis
Part8. Fusion, Isotope Production, and Superheavy Nuclei
Chapter30. PCN calculations for Z=111 to Z=118
Chapter31. On the role of the curvature corrections in the surface tension coefficient upon the orientation effects in the fusion reactions
Chapter32. Excitation function measurements of alpha-induced reaction on natural copper and titanium up to 46 MeV
Chapter33. Measurement of the excitation function of 96Zr(alpha, x)99Mo reaction up to 32 MeV
Part9. Fission
Chapter34. A grand tour of nuclear fission physics
Chapter35. Microscopic calculation of fission mass distributions at increasing excitation energies
Chapter36. Microscopic description of fission for the r-process in neutron star mergers 242
Chapter37. Event-by-event modeling with FREYA
Chapter38. Capabilities of the NIFFTE FissionTPC
Part10. Experimental Techniques and Facilities
Chapter39. Resonance measurements at Rensselaer Polytechnic Institute
Chapter40. Experimental facilities at iThemba LABS and measurements to constrain astrophysical processes
Chapter41. Late gamma rays from neutron-induced fission and capture from 235U.
Chapter1. Towards more predictive nuclear reaction modelling
Chapter2. Modelling compound nuclear reactions with EMPIRE
Chapter3. CoH3: The Coupled-Channels and Hauser-Feshbach Code
Part2. Beyond Statistical Descriptions
Chapter4. Recent advances in R-matrix data analysis
Chapter5. The transition from isolated resonances to the continuum
Chapter6. Cross section correlation functions and deviations from the Porter-Thomas distribution
Chapter7. Moldauers sum rule implies superradiance in compound nuclear reactions 48
Chapter8. Multi-step direct reaction models including collectivity in nucleon induced reactions
Chapter9. New symmetry-adapted ab initio approach to nuclear reactions for intermediate-mass nuclei
Part3. Optical Models
Chapter10. Linking nuclear reactions and nuclear structure to study exotic nuclei using the dispersive optical model
Chapter11. Microscopic optical potential from chiral effective field theory
Part4. Level Densities
Chapter12. Nuclear level densities: from empirical models to microscopic methods
Chapter13. Problem of level densities in compound nuclear reactions
Chapter14. Nuclear shell model and level density
Chapter15. Constraining level densities using spectral data
Chapter16. Rotational enhancement factor for nuclear level density
Chapter17. Role of fluctuations on the pairing properties of nuclei in the random spacing model
Part5. Gamma-ray Strength Functions
Chapter18. Gamma strength functions and the Brink-Axel hypothesis
Chapter19. Gamma-ray strength functions and GDR cross sections in the IAEA photonuclear data project
Chapter20. Neutron capture on actinides studied with DANCE
Chapter21. Deconvolution of the photon strength function
Part6. Oslo Method
Chapter22. Attempting to close the loop on the Oslo technique at 198Au: constraining the nuclear spin distribution
Chapter23. Impact of restricted spin-ranges in the Oslo method: The example of (d, p)240Pu
Chapter24. Systematics of gamma-ray strength functions within the shell model
Part7. Surrogate Nuclear Reactions
Chapter25. Future perspectives for surrogate-reaction studies at storage rings
Chapter26. Prospects for surrogate neutron capture measurements with radioactive ion beams and GODDESS
Chapter27. Surrogate reaction method for neutron capture and other reactions on unstable nuclei
Chapter28. Neutron capture cross sections from surrogate reaction data and theory: connecting the pieces with a Markov-Chain Monte Carlo approach
Chapter29. Neutron transfer reactions for deformed nuclei using a Sturmian basis
Part8. Fusion, Isotope Production, and Superheavy Nuclei
Chapter30. PCN calculations for Z=111 to Z=118
Chapter31. On the role of the curvature corrections in the surface tension coefficient upon the orientation effects in the fusion reactions
Chapter32. Excitation function measurements of alpha-induced reaction on natural copper and titanium up to 46 MeV
Chapter33. Measurement of the excitation function of 96Zr(alpha, x)99Mo reaction up to 32 MeV
Part9. Fission
Chapter34. A grand tour of nuclear fission physics
Chapter35. Microscopic calculation of fission mass distributions at increasing excitation energies
Chapter36. Microscopic description of fission for the r-process in neutron star mergers 242
Chapter37. Event-by-event modeling with FREYA
Chapter38. Capabilities of the NIFFTE FissionTPC
Part10. Experimental Techniques and Facilities
Chapter39. Resonance measurements at Rensselaer Polytechnic Institute
Chapter40. Experimental facilities at iThemba LABS and measurements to constrain astrophysical processes
Chapter41. Late gamma rays from neutron-induced fission and capture from 235U.