a. Using PIPE-FLO, fill in the table below with the correct viscosity values for carbon monoxide at standard atmospheric pressure. b. Create a nice plot of viscosity (Pa-s) versus temperature (C) for carbon monoxide at standard atmospheric pressure. c. A colleague suggests using a linear regression model to describe the effect of temperature on viscosity of carbon monoxide. Using the strategies we discussed in Tutorial 2, prove that this suggestion is not a good one. d. Following the technique described in Section A.3 of the textbook, determine the best-fit values of the constants b and S that appear in the empirical Sutherland correlation (Equation A.1). HINT: Remember that T in the Sutherland correlation must be in absolute temperature units. e. Use the correlation developed in part d to predict the viscosity (Pa.s) of carbon monoxide at a temperature of 35C and standard atmospheric pressure. a. Using PIPE-FLO, fill in the table below with the correct viscosity values for carbon monoxide at standard atmospheric pressure. b. Create a nice plot of viscosity (Pa-s) versus temperature (C) for carbon monoxide at standard atmospheric pressure. c. A colleague suggests using a linear regression model to describe the effect of temperature on viscosity of carbon monoxide. Using the strategies we discussed in Tutorial 2, prove that this suggestion is not a good one. d. Following the technique described in Section A.3 of the textbook, determine the best-fit values of the constants b and S that appear in the empirical Sutherland correlation (Equation A.1). HINT: Remember that T in the Sutherland correlation must be in absolute temperature units. e. Use the correlation developed in part d to predict the viscosity (Pa.s) of carbon monoxide at a temperature of 35C and standard atmospheric pressure