The Materiality and Neutrality of Neutral Density and Orthobaric Density

• Published in: Journal of physical oceanography Vol. 39; no. 8; pp. 1779 - 1799
• Main Authors: DE SZOEKE, Roland A, SPRINGER, Scott R
• Format: Journal Article
• Language: English
• Published: Boston, MA American Meteorological Society 01.08.2009
• Subjects: Density; Earth, ocean, space; Exact sciences and technology; External geophysics; Marine; Materiality; Physics of the oceans; Salinity; Variables; Water analysis; Water sampling; Atlantic Ocean; A, Atlantic; Sphere; Vertical speed; salinity; Water mass; spatial variations; heat transfer
• ISSN: 0022-3670; 1520-0485
• DOI: 10.1175/2009JPO4042.1

Abstract The materiality and neutrality of neutral density and several forms of orthobaric density are calculated and compared using a simple idealization of the warm-sphere water mass properties of the Atlantic Ocean. Materiality is the value of the material derivative, expressed as a quasi-vertical velocity, following the motion of each of the variables: zero materiality denotes perfect conservation. Neutrality is the difference between the dip in the isopleth surfaces of the respective variables and the dip in the neutral planes. The materiality and neutrality of the neutral density of a water sample are composed of contributions from the following: (I) how closely the sample’s temperature and salinity lie in relation to the local reference θ–S relation, (II) the spatial variation of the reference θ–S relation, (III) the neutrality of the underlying reference neutral density surfaces, and (IV) irreversible exchanges of heat and salinity. Type II contributions dominate but have been neglected in previous assessments of neutral density properties. The materiality and neutrality of surfaces of simple orthobaric density, defined using a spatially uniform θ–S relation, have contributions analogous to types I and IV, but lack any of types II or III. Extending the concept of orthobaric density to permit spatial variation of the θ–S relation diminishes the type I contributions, but the effect is counterbalanced by the emergence of type II contributions. Discrete analogs of extended orthobaric density, based on regionally averaged θ–S relations matched at interregional boundaries, reveal a close analogy between the extended orthobaric density and the practical neutral density. Neutral density is not superior, even to simple orthobaric density, in terms of materiality or neutrality.