Module polymers::physics::single_chain::fjc::thermodynamics::modified_canonical
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The freely-jointed chain (FJC) model thermodynamics in the modified canonical ensemble.
Modules§
- The freely-jointed chain (FJC) model thermodynamics in the modified canonical ensemble approximated using an asymptotic approach.
Structs§
- The structure of the thermodynamics of the FJC model in the modified canonical ensemble.
Functions§
- The expected end-to-end length as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links and link length.
- The expected end-to-end length per link as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links and link length.
- The expected force as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links and link length.
- The Gibbs free energy as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The Gibbs free energy epr link as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The Helmholtz free energy as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The Helmholtz free energy per link as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The expected nondimensional end-to-end length as a function of the applied nondimensional potential distance and nondimensional potential stiffness, parameterized by the number of links.
- The expected nondimensional end-to-end length per link as a function of the applied nondimensional potential distance and nondimensional potential stiffness, parameterized by the number of links.
- The expected nondimensional force as a function of the applied nondimensional potential distance and nondimensional potential stiffness, parameterized by the number of links.
- The nondimensional Gibbs free energy as a function of the applied nondimensional potential distance, nondimensional potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The nondimensional Gibbs free energy per link as a function of the applied nondimensional potential distance, nondimensional potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The nondimensional Helmholtz free energy as a function of the applied nondimensional potential distance, nondimensional potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The nondimensional Helmholtz free energy per link as a function of the applied nondimensional potential distance, nondimensional potential stiffness, and temperature, parameterized by the number of links, link length, and hinge mass.
- The nondimensional relative Gibbs free energy as a function of the applied nondimensional potential distance and nondimensional potential stiffness, parameterized by the number of links.
- The nondimensional relative Gibbs free energy per link as a function of the applied nondimensional potential distance and nondimensional potential stiffness, parameterized by the number of links.
- The nondimensional relative Helmholtz free energy as a function of the applied nondimensional potential distance and nondimensional potential stiffness, parameterized by the number of links.
- The nondimensional relative Helmholtz free energy per link as a function of the applied nondimensional potential distance and nondimensional potential stiffness, parameterized by the number of links.
- The relative Gibbs free energy as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links and link length.
- The relative Gibbs free energy per link as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links and link length.
- The relative Helmholtz free energy as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links and link length.
- The relative Helmholtz free energy per link as a function of the applied potential distance, potential stiffness, and temperature, parameterized by the number of links and link length.