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This chapter delves into fundamental concepts of systems analysis through the lens of Daisyworld, a heuristic model illustrating how negative feedback loops can stabilize a planet's climate. It contrasts equilibrium and dynamical models, focusing on system states, coupling, and the dynamics of feedback loops. By examining examples such as temperature responses and perturbations, the chapter elucidates stable and unstable equilibria, the role of forcings, and how the interactions within systems can promote climate equilibrium without intentional regulation from organisms.
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Earth Systems ScienceChapter 2: SYSTEMS • Systems Analysis – some basic concepts / definitions • Daisyworld – a “heuristic” model to demonstrate the potential for negative feedbacks on a planet to stabilize the climate • Equilibrium vs Dynamical models
Systems Analysis: some basic concepts / definitions • System – a set of interrelated parts, or components • State of a system – a set of attributes that characterize the system (depth of water in the tub; temperature of earth) • Coupling – a link between 2 components + coupling –component 1 increases, component 2 increases- coupling - component 1 increases, component 2 decreases • Feedback loops – positive and negative • Equilibrium States – stable and unstable • Perturbations & Forcings
Each person controlling their own blanket temperature (negative feedback, stable equilibrium) Jimmy & Rosalynn Carter Each was inadvertently controlling the temperature of the other’s blanket Positive feedback, unstable equilibrium
STABLE / UNSTABLE EQUILIBRIUM Stable Equilibrium:If the system is perturbed by a small amount, it will return to the same equilibrium state Unstable Equilibrium:If the system is perturbed by a small amount, it will NOT return to the same equilibrium state Example: a thermostat
Perturbation:sudden / temporary disturbance to a systemThe disturbance is temporary, but the system might take a while to recover Impact of asteroid injects massive amount of particulates into the atmosphere a volcanic eruption injects SO2 into the atmosphere, which is washed out of the atmosphere in a few years
Forcinga persistent disturbance to a systeme.g. a gradual change in solar radiation over long time,the faint young sun paradox
DAISYWORLD: A HEURISTIC MODEL • Heuristic (dictionary.reference.com) : • Of or relating to a usually speculative formulation serving as a guide in the investigation or solution of a problem: “The historian discovers the past by the judicious use of such a heuristic device as the ‘ideal type’” (Karl J. Weintraub). • Of or constituting an educational method in which learning takes place through discoveries that result from investigations made by the student.
Notice the axis Response of average surface temperature to daisy coverage (c) Equation: Temp = a*daisy + b Graph Systems Diagram
Response of daisy coverage to average surface temperature (c) Equation: Daisy = 100 – (T-22)2/4
Equilibrium States: Graphical Determination • Overlay the two graphs (this is the graphical way of setting them equal to each other). • The points where they meet are equilibrium points. • Draw a systems diagram to determine whether each one is stable or unstable.
Equilibrium States: Algebraic Determination • Response of Temp to daisies: Temp = a*daisy + bdaisy = (Temp – b)/a • Response of daisies to Temp: daisy = 100 – (Temp-22)2/4 • Set the equal to each other:(Temp – b)/a = 100 – (Temp-22)2/4 • Do some algebraic manipulation, you get a quadratic equationT2 – (44-4/a)T + (84-4b/a) = 0 • solution to a quadratic (aT2 + bT + c = 0) is:T = [-b ± sqrt(b2 – 4ac) ] / 2a • This will give 2 solutions, corresponding to P1 and P2
Notice the axis External Forcing: the response of Daisy World • Assume that the external forcing is an increase in solar luminosity • The effect of temperature on daisy coverage should not change (this depends on the physiology of daisies) • The effect of daisy coverage on temperature should change: for the same daisy coverage, higher temperature Algebraic: Temp = a*daisy + b+DT0
Response of the Equilibrium State to the Forcing • Use the new line for the effect of daisy coverage on temperature • Notice that the new equilibrium points have changed: P1, the stable point, is at a higher temperature • Notice that P1 is not as high a temperature as it would have been without the daisies responding • Feedback factor: DTeq = DTo - DTf
Climate history of Daisyworld: solar luminosity increasing • As solar luminosity increases, with no feedback (or no daisies) the average temperature will increase close to linearly • With the daisy feedback, the temperatures on Daisyworld are kept much more stable compared to the case without feedback • No “intention” is required on the part of the daisies to stabilize the climate. All this is required is a negative feedback
EQUILIBRIUM MODELS The model of Daisyworld in the text is an equilibrium model, just like the models of the bathtub and the earth’s radiation balance from lab 1. These models do not allow one to determine if it ever actually reaches equilibrium, or how long it takes to get there. In these equilibrium models, the STATE of one variable (daisy coverage, water level in the tub, or earth’s temperature) is a function of the state of a second variable (planetary temperature, rate of water coming out of faucet, solar luminosity). DYNAMICAL MODELS In dynamical models, the CHANGE of one variable (daisy growth rate, water level rate of increase, rate of earth’s temperature change) is a function of the state of the second variable.
