A thermocouple temperature sensor static equation is V = (a + b dT)dT where a =...

If the temperature difference DT between an object and it surroundings is not too great, the...

If the temperature difference DT between an object and it surroundings is not too great, the rate of cooling or warming obeys Newton’s Law of Cooling, d(DT)/dt = – K DT where K is a constant. (a) Why is there a minus sign on the right-hand side of the equation? (b) On what factors does K depend and what are its units? (c) It DTo is the temperature difference at time to, what is the temperature difference at time t...

An IR sensor is required to develop an output of 5 V for an IR radiation...

An IR sensor is required to develop an output of 5 V for an IR radiation of 20 mW/cm². For increased sensitivity, aluminum/silicon thermocouples are used because they have an output of 446mV/°C. An aluminum absorber of area 4cm² and thickness 20µm is used with an absorption efficiency of 80%. Aluminum has a density of 2.712 g/cm³ and a heat capacity of 0.897J/g/°C. The required output must be obtained within 100ms. a. What is the increase in the temperature of...

Question B: Newton's law of cooling states dθ/dt = −k (θ−T) where ? is the temperature...

Question B: Newton's law of cooling states dθ/dt = −k (θ−T) where ? is the temperature at time t, T is the constant surrounding temperature and k is a constant. If a mass with initial temperature, θ0, of 319.5 K is placed in a surroundings of 330.5 K, and k is 0.011 s-1 , what is its temperature after 4.7 minutes? Give your answer to 4 significant figures and remember to use units. ____________

The equation of state of a gas is given as bar v(P+10/bar v^2) = RsubuT, where...

The equation of state of a gas is given as bar v(P+10/bar v^2) = RsubuT, where the units of bar v and P are m^3/kmol and kPa respectively. Now 0.49 kmol of this gas is expanded in a quasi-equilibrium manner from 1.6 to 4.9 m^3 at a constant temperature of 290 K. Determine the work done during this isothermal expansion process.

Suppose that the population develops according to the logistic equation dP/dt = 0.0102P - 0.00003P^2 where...

Suppose that the population develops according to the logistic equation dP/dt = 0.0102P - 0.00003P^2 where t is measured in days. What is the P value after 10 days where A = (M-P(0)) / P(0)) if the P(0) = 40? And P(0) = 20?

1. Solve the given initial value problem. dy/dt = (t^3 + t)/(y^2); y(0) = 2 ....

1. Solve the given initial value problem. dy/dt = (t^3 + t)/(y^2); y(0) = 2 . 2. We know from Newton’s Law of Cooling that the rate at which a cold soda warms up is proportional to the difference between the ambient temperature of the room and the temperature of the drink. The differential equation corresponding to this situation is given by y' = k(M − y) where k is a positive constant. The solution to this equation is given...

(1 point) Newton's Law of Cooling states that the rate of cooling of an object is...

(1 point) Newton's Law of Cooling states that the rate of cooling of an object is proportional to the temperature difference between the object and its surroundings. Suppose t is time, T is the temperature of the object, and Ts is the surrounding temperature. The following differential equation describes Newton's Law dT/dt=k(T−Ts), where k is a constant. Suppose that we consider a 95∘C cup of coffee in a 25∘C room. Suppose it is known that the coffee cools at a...

A. The Arrhenius equation shows the relationship between the rate constant k and the temperature T...

A. The Arrhenius equation shows the relationship between the rate constant k and the temperature T in kelvins and is typically written as k=Ae−Ea/RT where R is the gas constant (8.314 J/mol⋅K), A is a constant called the frequency factor, and Ea is the activation energy for the reaction. However, a more practical form of this equation is lnk2k1=EaR(1T1−1T2) which is mathematically equivalent to lnk1k2=EaR(1T2−1T1) where k1 and k2 are the rate constants for a single reaction at two different...

The Arrhenius equation shows the relationship between the rate constant k and the temperature Tin kelvins...

The Arrhenius equation shows the relationship between the rate constant k and the temperature Tin kelvins and is typically written as k=Ae−Ea/RT where R is the gas constant (8.314 J/mol⋅K), Ais a constant called the frequency factor, and Ea is the activation energy for the reaction. However, a more practical form of this equation is lnk2k1=EaR(1T1−1T2) which is mathmatically equivalent to lnk1k2=EaR(1T2−1T1) where k1 and k2 are the rate constants for a single reaction at two different absolute temperatures (T1and...

The Arrhenius equation shows the relationship between the rate constant k and the temperature T in...

The Arrhenius equation shows the relationship between the rate constant k and the temperature T in kelvins and is typically written as k=Ae−Ea/RT where R is the gas constant (8.314 J/mol⋅K), A is a constant called the frequency factor, and Ea is the activation energy for the reaction. However, a more practical form of this equation is lnk2k1=EaR(1T1−1T2) which is mathmatically equivalent to lnk1k2=EaR(1T2−1T1) where k1 and k2 are the rate constants for a single reaction at two different absolute...