100 likes | 197 Views
Physical Oceanography:. Mass is conserved density measurements (mass/volume) Momentum* is conserved velocity measurements. (*) momentum=mass*velocity. Mass : Hydrocast and CTD. Frobisher Bay, CANADA. Mary O’Brian, chemistry, lab technician. Velocity: Radars + Sonars.
E N D
Physical Oceanography: • Mass is conserved • density measurements (mass/volume) • Momentum* is conserved • velocity measurements (*) momentum=mass*velocity
Mass: Hydrocast and CTD Frobisher Bay, CANADA
Velocity:Radars + Sonars David Huntley with “sonar” Radars send and receive electromagnetic waves (radio, police) Sonars send and receives acoustic waves (sound, whales) Same physics.
Law of Motion (Physics): F = m * a Force = Mass * Acceleration Sum of all forces = time-rate of change of (mass*velocity) � if velocities small relative to speed of light � if measured in an appropriate frame of reference (one that does NOT rotate) Forces and velocities have magnitude and direction that vary in time and space.
Time Rate of Change (Mathematics): A most fundamental property of all natural systems at all scales from universe to sub-nuclear particles Calculus: Formalizing “time rate of change” to answer the question How do we calculate the difference of a property at time t and a little time dt later as dt approaches zero?
Sum of all forces = time-rate of change of (mass*velocity) ∑ F = m*dv/dt Or per unit volume: ∑ = *dv/dt where =force/volume =mass/volume=density
Example: • F is a constant wind force • is a constant ocean density c=F/=const. Find v(t) of a water parcel c = dv/dt c * dt = dv Model: [F=m*a] Integration-1: [computer] c*∫ 1 dt = ∫ 1 dv c*(t-0) = v(t)-v(t=0) Initial condition: [data] v(t=0) = v0 Solution-1: [prediction] v(t) = v0+c*t
v(t) = v0 + c*t Solution-1: Recall: v = dx/dt v*dt = dx Integration-2: [computer] ∫ v(t) dt = ∫ 1 dx ∫ (v0 + c*t) dt = ∫ 1 dx v0*t + c*t2/2 = x(t)-x(t=0) Initial condition: [Data] x(t=0) = x0 Solution-2: [Prediction] x(t) = x0 + v0*t + c*t2/2
Homework: Please read Knauss (1997), chapter-5: p. 81-85 (acceleration and pressure gradient) p. 87-89 (Coriolis force) p. 96-99 (friction, eddy viscosity, wind stress) p. 101-102 (Reynolds stress p. 104 (Equations of motion) Study guide questions will be posted 9/16 noon at Class web-site.