1. Introduction

    1. Physical states as representations of super-symplectic and Super Kac-Moody algebras

    2. Particle massivation

    3. What next?

  2. Identification of elementary particles

    1. Partons as wormhole throats and particles as bound states of wormhole contacts

    2. Family replication phenomenon topologically

    3. Critizing the view about elementary particles

  3. Non-topological contributions to particle masses from p-adic thermodynamics

    1. Partition functions are not changed

    2. Fundamental length and mass scales

    3. Color degrees of freedom

    4. Spectrum of elementary particles

    5. Some probabilistic considerations

  4. Modular contribution to the mass squared

    1. Conformal symmetries and modular invariance

    2. The physical origin of the genus dependent contribution to the mass squared

    3. Generalization of Θ functions and quantization of p-adic moduli

    4. The calculation of the modular contribution to the conformal weight

  5. The contributions of p-adic thermodynamics to particle masses

    1. General mass squared formula

    2. Color contribution to the mass squared

    3. Modular contribution to the mass of elementary particle

    4. Thermal contribution to the mass squared

    5. The contribution from the deviation of ground state conformal weight from negative integer

    6. General mass formula for Ramond representations

    7. General mass formulas for NS representations

    8. Primary condensation levels from p-adic length scale hypothesis

  6. Fermion masses

    1. Charged lepton mass ratios

    2. Neutrino masses

    3. Quark masses

  7. About the microscopic description of gauge boson massivation

    1. Can p-adic thermodynamics explain the masses of intermediate gauge bosons?

    2. The counterpart of Higgs vacuum expectation in TGD

    3. Elementary particles in ZEO

    4. Virtual and real particles and gauge conditions in ZEO

    5. The role of string world sheets and magnetic flux tubes in massivation

    6. Weak Regge trajectories

  8. About the basic assumptions behind p-adic mass calculations

    1. Why p-adic thermodynamics?

    2. How to understand the conformal weight of the ground state?

    3. What about Poincare invariance?

    4. What are the fundamental dynamical objects?

    5. What about the identification of conformal symmetries?

  9. M8-H duality and the two manners to describe particles

    1. Option I: fixed M4T

    2. Option II: varying M4T

    3. p-Adic particle massivation and ZEO

  10. Appendix: The particle spectrum predicted by TGD

    1. The general TGD based view about elementary particles

    2. Construction of single fermion states

    3. About the construction of mesons and elementary bosons in TGD Universe

    4. What SUSY could mean in TGD framework?