Onsager reciprocal relations
GPTKB entity
Statements (56)
| Predicate | Object |
|---|---|
| gptkbp:instance_of |
gptkb:political_theory
|
| gptkbp:applies_to |
non-equilibrium thermodynamics
|
| gptkbp:concept |
physical chemistry
has practical applications in technology explains energy transfer facilitates understanding of complex systems has historical significance in thermodynamics is essential for thermodynamic education |
| gptkbp:describes |
relationship between thermodynamic fluxes and forces
|
| gptkbp:developed_by |
principle of microscopic reversibility
|
| https://www.w3.org/2000/01/rdf-schema#label |
Onsager reciprocal relations
|
| gptkbp:involves |
cross coefficients
|
| gptkbp:is_a_basis_for |
thermodynamic modeling
|
| gptkbp:is_a_foundation_for |
modern thermodynamic theories
|
| gptkbp:is_a_framework_for |
analyzing irreversible processes
analyzing transport processes in materials |
| gptkbp:is_a_key_component_of |
thermodynamic analysis
|
| gptkbp:is_a_mathematical_formulation_of |
thermodynamic laws
|
| gptkbp:is_a_subject_of |
gptkb:Physics
research in thermodynamics advanced thermodynamics |
| gptkbp:is_a_theoretical_construct_in |
statistical physics
|
| gptkbp:is_a_theoretical_tool_for |
predicting system responses
|
| gptkbp:is_analyzed_in |
coupled processes
|
| gptkbp:is_applicable_to |
diffusion processes
heat conduction chemical kinetics |
| gptkbp:is_applied_in |
engineering thermodynamics
|
| gptkbp:is_connected_to |
fluctuation-dissipation theorem
|
| gptkbp:is_essential_for |
transport phenomena
understanding thermodynamic systems |
| gptkbp:is_fundamental_to |
irreversible thermodynamics
|
| gptkbp:is_related_to |
entropy production
dissipative systems linear response theory |
| gptkbp:is_relevant_to |
nonequilibrium statistical mechanics
|
| gptkbp:is_represented_in |
matrix equations
|
| gptkbp:is_significant_for |
material science
|
| gptkbp:is_studied_in |
graduate physics courses
|
| gptkbp:is_used_in |
gptkb:statistical_mechanics
electrochemistry |
| gptkbp:is_utilized_in |
biophysics
|
| gptkbp:key_concept |
transport theory
|
| gptkbp:legal_principle |
thermodynamic systems
enhances understanding of energy systems describes system behavior under non-equilibrium conditions has implications in various scientific fields is often discussed in academic literature is widely accepted in the scientific community links different transport phenomena underlies many physical phenomena is foundational for future research in thermodynamics. |
| gptkbp:named_after |
gptkb:Lars_Onsager
|
| gptkbp:provides |
symmetry relations
|
| gptkbp:bfsParent |
gptkb:Lars_Onsager
|
| gptkbp:bfsLayer |
4
|