UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE UNBC GEOG 210 LAB FINAL Sample Exam ANSWERS Name: Lab Section Time: Student #: Lab Instructor: Name: Alias: Chris Jackson Total _____ XXXX SAMPLE ENSC 201 Lab Final Answers: The format shown here (but not the questions) is what you will see for the lab final exam. • This exam consists of X questions on X pages; charts, formulas and constants are provided on the last pages of this exam. Check you have a complete exam. • You have 80 minutes to do this exam. It is marked out of X marks and worth X% of your grade. • It is a closed book exam. Any detached pages must be stapled together. This exam is not returned to you, but you can review it with the Senior Lab Instructor. Indicate an alias if you want to see your grade posted. • Calculators are allowed. Graphing / programmable calculators must be shown to the instructor before the exam starts to demonstrate that the memory has been cleared. • Answer in the spaces provided. Use the reverse side if more space is needed. • SHOW ALL YOUR WORK TO GET FULL MARKS – AN ANSWER WITH LITTLE OR NO INDICATION OF HOW IT WAS DETERMINED IS WORTH ZERO. EXAM Q & A: These are a random selection of questions and don’t represent a complete summary of what types or weighting of questions you might see on a final lab exam. Expect a cumulative exam. 1) Give the concept/principles behind using a psychrometer to measure atmospheric humidity. If the wet bulb temperature is 10 0C, and the air temperature is 15 0C, calculate the vapour pressure and relative humidity. (5 marks) Solution to first part, The concept behind measuring humidity with a psychrometer: When the air is unsaturated, evaporation occurs as air flows over the wet wick of a wet-bulb thermometer. Evaporation requires heat, which comes from the internal energy of the air. The heat loss from the air, which provides the energy to evaporate water from the wet-bulb, can be measured as a decrease in the temperature of the wet-bulb thermometer when compared with the air temperature on the dry bulb. If the air is very dry (ie. far from saturation) there will be more evaporation from the wet-bulb and the wet-bulb temperature will decrease more. Psychrometry, through the psycrhometric equation, equates the loss of heat in the air (as measured by the wet-bulb temperature decrease) with the latent heat required to evaporate water from the wet-bulb. Solution to second part, calculating the vapour pressure (e) and RH: requires application of the psychrometric equation (see below), and use of the e* vs T curve / graph from the humidity lab. Determining e using the psychrometric equation: e = e*(Tw) − λ(T − Tw) here λ is the psychrometric constant = 66 Pa 0C-1 . From the e* vs T graph, determine e* at Tw or e* at 10 0C = e*(10) = 12.3 hPa = 1230 Pa. (To find this value use the Saturation vapour pressure curve (over water), find 10 0C on the x-axis, follow 10 0C and follow the graph vertically until it intersects the curve, and then follow the intersection point horizontally to read the e* value on the y-axis.) 1 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson Using the e* value from the graph solve for e: e = 1230 Pa – [66 Pa 0C-1 (15 0C -10 0C)] = 900 Pa Determining RH: The RH is the ratio of the actual vapour pressure to the saturation vapour pressure. The saturation vapour pressure is found on the e* vs T graph this time using the air temperature instead of the wet bulb temperature. So e* at T or e* at 15 0C = e*(15) = 17 hPa = 1700 Pa. RH = 900 Pa e × 100% = × 100% = 53% * 1700 Pa e 2) A cool winter Canadian air mass with a temperature of -4 0C and a relative humidity of 91% meets a warm air mass sweeping northward from Texas with a temperature of 17 0C and a relative humidity of 26%. In the mixing process will the southern border of the Canadian air mass gain or lose water vapour content? Show your method of determination and explain. (5 marks) Solution: Since RH is highly dependent upon temperature (not just water vapour content) we cannot tell from the RH alone which air mass (i.e. the Canadian or Texan) will actually have more moisture. To determine this you need to find the vapour pressure (e -- the actual amount of moisture for each air mass) as vapour pressure doesn’t vary with temperature. Since you know the RH, and the air temperatures, you can use these to determine the vapour pressures for each air mass. The air mass with the highest moisture content (i.e. e value) will lose moisture when it mixes with a drier air mass. For the Canadian air: From the e* vs T graph, e* at T= -4 0C or e*(-4) = 4.4 hPa = 440 Pa. Rearranging RH = e × 100% to solve for e we get: e = e* (RH) e* Solving for e for the Canadian air mass: e = e* (RH)= (440 Pa)(0.91) = 400.4 Pa = 4 hPa For the Texan air: From the e* vs T graph, e* at T= 17 0C or e*(17) = 19.4 hPa = 1940 Pa. Rearranging RH = e × 100% to solve for e we get: e = e* (RH) e* Solving for e for the Texan air mass: e = e* (RH)= (1940 Pa)(0.26) = 504.4 Pa = 5 hPa So the Texas air mass is actually more humid (i.e. has more moisture content) so when they mix the southern part of Canadian air mass will increase in moisture. 2 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE 3) To answer these refer to Figure 1. a) Explain the rather anomalous dip in the QE curve (and the related rise in QH) during July and August. (2 marks) Chris Jackson Figure 1, Lab Final Review: Vancouver’s monthly averaged annual energy budget. Solution: The QE dip in July and August occurs because availability of water for evapotranspiration is limited. There is no longer enough moisture available for evapotranspiration to meet its full potential. Since Q* is still high, this decrease in QE is utilized with an increase in QH, which results because it is drier and energy now goes into heating the air. b) How is it possible for the heat used in evapotranspiration (QE) to exceed the available net radiation (Q*) in the September to February period? (2 marks) ∗ Solution: Energy used in evapotranspiration comes not only from radiation (Q ), but when there is a deficit, the ground’s heat storage (negative or upward QG) and energy supplied via sensible heat (negative QH or heat going from the air toward the surface) can provide energy for evapotranspiration. 4) Answer on a tephigram. (See the tephigram below) a) Plot the data from the table below as two vertical profiles, one of T at each pressure level and one of Td at each pressure level (2 marks) Pressure P (hPa) Temp. T (°C) 1000 850 700 650 500 400 29 15 4 8 -11 -25 Dew pt. Temp Td(°C) 11 11 1 2 -19 -30 Wet bulb Temp Tw(°C) 19 12 2.5 4 -13 -27 Mixing rat. r (g/kg) 8.5 10 6 7 1.8 0.8 Saturation mixing ratio rs (g/kg) 25 14 7 10 3 1.7 rel. hum. RH (%) 34 71 86 70 60 47 Stability Layer 1 Layer 2 Layer 3 Layer 4 Layer 5 n/a conditionally unstable conditionally unstable stable (inversion) conditionally unstable conditionally unstable b) Complete the table above by adding the missing data for everything but the Stability column (0.5 marks each; total 12 marks). c) On the vertical profile you have plotted, find the lifting condensation level (LC) for a parcel lifted from the surface. (1 mark) The LCL is formed at 790 hPa d) Continue to lift the now saturated parcel to where it crosses the environmental lapse rate (ELR) again. (2 marks) i) What is this level in hPa? It crosses the ELR again at 500 hPa 3 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson ii) On your tephigram, name it. See tephigram for LFC or Level of Free Convection e) On the tephigam and table above, identify the stability of each layer. (3 marks) See tephigram below and the stability column in the table above 5) Repeat the questions given in the midterm review. See midterm review sample questions and answers posted on the course website. 4 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson 6) Using the plotted weather station information for a surface weather map (figure given at the end of this review), determine the: isobars at 4 hPa intervals (4 marks), identify any high (H) and/or low (L) pressure areas (2 marks), and locate any associated fronts (3 marks). (total 9 marks) This answer is the same as what was done for the weather lab. The L in red represents a low pressure centre. Correct answers should show the 980 to 1008 hPa isobars and a cold and a warm front which are correctly located and identified by their symbols. L 7) Given a temperature of 14 0C and a wet bulb temperature of 7 0C, find the following and explain how you found them. (Do not use a tephigram to answer this question.) Be sure to show the units. a) Vapour pressure and dew point temperature (3 marks) Want: vapour pressure = e; and dew point temperature = Td Know: T = 14 0C Tw = 7 0C e = e*(Tw) - λ(T – Tw) where λ = 66 Pa 0C-1 and e = e*(Td) Determine vapour pressure using: e = e*(Tw) - λ(T – Tw) where λ = 66 Pa 0C-1 and from the saturation vapour pressure graph get e*(Tw) at 7 0C = 10 hPa or 1000 Pa e = 1000 Pa - [66 Pa 0C-1 (14 0C – 7 0C)] = 538 Pa = 5.4 hPa Determine Td using the e value above and the saturation vapour pressure curve but this time reading it to get Td from e. (i.e. e = e*(Td)) e at 5.4 hPa = aTd of 1.3 0C 5 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson b) Saturation vapour pressure and relative humidity. (2 marks) Determine e* from the saturation vapour pressure graph get e*(T) at 14 0C = 16 hPa or 1600 Pa Determine RH using e from question a) above and e* RH = e 5.4 hPa × 100% = × 100% = 33.75% = 34% * 16 hPa e c) Which of the values in a) and b) can be used when comparing the air’s actual vapour content between locations where temperature and moisture content might vary? Why? (3 marks) Only e and Td of the humidity measures above (e, e*, Td or RH), can be used to compare moisture content between areas with different temperature because neither of these ways of determining humidity depends on temperature. The others depend on temperature (i.e. the potential for moisture in the air (e*) rises and falls with temperature changes; and RH changes with both moisture and temperature.) d) Which of the values in a) and b) above could be used when comparing vapour content between locations where elevation as well as moisture content might vary? (3 marks) None of the above measure of humidity (e, e*, Td or RH) can be used to compare moisture content in areas where elevation changes as pressure decreases with increasing elevation and e and Td depend on pressure. (Not asked for but FYI – only mixing ratio (r) is not dependent on pressure.) 8) Show your work on the tephigram. See the tephigram below for these answers. a) Plot the data from the table below on the attached tephigram. This will result in a vertical profile for T, and a plotted data point for Tw at 1000 hPa. (2 marks) Pressure P (hPa) Temp. T (°C) Dew pt. Temp Td(°C) Wet bulb Temp Tw(°C) Mixing rat. r (g/kg) Saturation mixing ratio rs (g/kg) rel. hum. RH (%) 1000 10 -2 0C 5 3.5 g kg-1 7.8 g kg-1 45% 600 -25 300 -30 Do not complete Do not complete Do not complete Do not complete Do not complete Do not complete Do not complete Do not complete Do not complete Do not complete b) Use Normand’s rule to find: (2 marks) i) the LCL for a parcel lifted from 1000 hPa The LCL occurs at 840 hPa ii) Td at 1000 hPa Td at 1000 hPa = -2 0C c) At 1000 hPa, find the following. For full marks, be sure to explain how you found each of these and clearly show your method on the tephigram. (3 marks) i) mixing ratio r at 1000 hPa = 3.5 g kg-1 ii) saturation mixing ratio rs at 1000 hPa = 7.8 g kg-1 6 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE iii) RH RH = Chris Jackson r 3.5 g kg −1 × 100% = × 100% = 44.9% = 45% 7.8 g kg −1 rs d) For a parcel lifted from 1000 hPa find: (4 marks) i) the level of free convection (LFC) The LFC occurs at 780 hPa ii) equilibrium level The equilibrium level occurs at 570 hPa iii) the amount of moisture condensed during the ascent from the surface to the equilibrium level The amount of moisture condensed = rinitial – rfinal = 3.5 g kg-1 – 0.9 g kg-1 = 2.6 g kg-1 7.8 g/kg 7 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson 9) Explain how you might recognize the frontal passage of: a) A warm front from the perspective of a person at a location where the front is passing over? (3 marks) Initially the observer would see cirrus clouds increasing in amount and density followed by altostratus which would become status clouds that are thicker and closer to the ground and gradually precipitation would start from nimbostratus clouds. Steady winds would gradually increase from the east or southeast and switch to south or south west as the front passes. Temperatures would warm as the front passes. (Pressure would drop as the front passes but this wouldn’t be visible to a ground observer so not really a good answer here.) b) A cold front from a weather chart? In your answer make sure to indicate the type of chart you are using. (3 marks) Assume that the cold front symbols aren’t on the chart. A cold front on a surface weather map is indicated by the cold front symbols on the chart (but you are to assume this isn’t given). On a surface weather map a cold front is identified by the winds shifting (usually from south or south west to north or north west), a temperature decrease, a pattern of cumulus type clouds associated with a front, and a pressure decrease and then increase as the front passes. c) Sketch a cross-section diagram (not an actual cross-section) through a low pressure system that represents the types of weather features you expect to see along the cross section. Make sure to appropriately label it. (10 marks) 10) If the height of a water column in a water barometer is 9.70 m and the water temperature is 210C, what is the pressure at that location? (4 marks) The density of water (ρw) at various temperatures is: Temperature (°C) 15 17 19 21 23 25 -3 Density - ρw (kg m ) 999.099 998.774 998.405 997.992 997.538 997.044 Want to determine the pressure from a water barometer Know: Pa = ρw g ΔZw + e*(T) where: ρw = density of water for 21 0C = 997.992 kg m-3 (from the table above) g = gravity = 9.80665 m s-2 (from the equation sheet) e*(T) at 21 0C = 25 hPa = 2500 Pa (from the saturation vapour pressure curve) ΔZw = 9.70 m (given in the question above) 8 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson To get these units to make sense and complete the addition you need to realize that -1 -2 1 kg m s = 1 Pascal (Pa) Pa = ρw g ΔZw + e*(T) = (997.992 kg m-3)(9.80665 m s-2)(9.70 m) +2500 Pa = 94933.495 (kg m-3)(m s-2)(m) + 2500Pa = 94933.495 (kg m-1 s-2) + 2500Pa = 94933.495 Pa + 2500 Pa = 97433.5 Pa = 97.4 hPa 11) Answer all parts: A spherical alien spaceship has entered orbit around the earth, 3.0 x 107 m above the earth’s surface. The spaceship has a radius of 1 km and a surface temperature of 3000 K. It is a radiative “black-body”. Though it may not seem like it, this question is similar to one from the radiation lab where you determined the solar constant. For this problem it may help to draw a picture of the situation in this problem as this will enable you to understand the what you are being told. a) What is the flux density (W m-2) leaving the spaceship’s surface? (2 marks) S = spaceship in orbit around Earth. Spaceship’s radius is 1 km. Spaceship’s temperature = 3000 K S Earth 7 Radius from spaceship orbit to Earth = 3.0 x 10 m Want to determine the flux density (Wm-2) leaving the spaceship’s surface. Know E = σ T4 and know the space ship’s temperature So: Espaceship = (5.67 x 10-8 Wm-2 K-4) (3000 K4) = (5.67 x 10-8 Wm-2 K-4) (8 x 1013 K4) = 4.59 x 106 Wm-2 b) What is the total flux (W) emitted by the spacecraft? (2 marks) Total fluxspaceship = (Espaceship)(Area of the spaceship) Area of the spaceship = 4πr2 where the spaceship’s radius = 1 km Area of the spaceship = 4π(1 km)2 = 4π(1000 m)2 = 1.26 x 107 m2 So: Total fluxspaceship = (4.59 x 106 Wm-2)( 1.26 x 107 m2) = 5.78 x 1013 W c) What is the flux density (W m-2) reaching the earth’s surface from the spacecraft, ignoring the effects the atmosphere might have on attenuating this radiation? (2 marks) Flux density reaching = Total fluxspaceship the earth’s surface Surface area of shell at the radius of the spaceship to Earth orbit from the spaceship Flux density reaching = 5.78 x 1013 W = 5.78 x 1013 W = 5.78 x 1013 W = 5.11 x 10-3 Wm-2 the earth’s surface 2 4πr for the radius of the spaceship to Earth orbit 4π(3 x 107)2 m2 1.13 x 1016 m2 from the spaceship 9 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson d) How does this value compare to the solar constant? Would you be worried about the intensity of this radiation? Explain. (2 marks) The flux density reaching the earth from the spaceship is very small (5.11 x 10-3 Wm-2) when compared to the solar constant which is 1367 Wm-2. Unless this spaceship emits a very harmful unknown type of radiation that hurts at very low intensities this should not be a problem as the spaceship’s temperature of 3000 K indicates this radiation should be in between long and short wave radiation. e) BONUS QUESTION: What is the wavelength of maximum emission from the alien spacecraft? (2 marks) λmax = 2.88 × 10−3 m K 2.88 × 10−3 m K = = 9.6 × 10− 7 m 3000 K T 10 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson Lab Exam Constants and Formulas: Distance from the earth to the moon: 3.84 x 108 m Distance from Earth to Sun: 1.50 x 1011 m Distance from Mercury to the sun: 5.79 x 1010 m ~ water density: ρwater = 1000 kg m-3 ~ air density: ρair = 1.2 kg m-3 mercury density at 00C: ρHg = 13595.1 kg m-3 g = 9.80665 m s-2 Radius of the sun: 7x108 m Radius of the earth: 6.37 x 106 m Surface Area of a circle = π r 2 Surface Area of a sphere = 4 π r 2 Solar flux: 3.865 x 1026 W 1 nautical mile = 1852 m σ = 5.67 x 10 -8 W m-2 K-4 LV = 2.5 x 106 J kg-1 E of 1 mm h-1 is equivalent to QE of 680 W m-2 00C = 273.15 K Solar constant: 1367 W m-2 K = °C + 273.15 Kirchoff’s Law: aλ = Єλ 5(0F − 32) C= 9 2.88 × 10 −3 m K Wein’s Law: λmax = T 0 E = σ T4 where Є =1 as 0 E = Є σ T4 Q* = K* + L* Q* = K ↓- K ↑ + L ↓- L ↑ L* = L↓ + L↑ ⎡9 ⎤ F = ⎢ (0C )⎥ + 32 ⎣5 ⎦ I = Io cos Z cos Z = sinø sinδ + cosø cosδ cosh K* = K↓ + K↑ = [K↓ (1 –α)] L* = L↓ - σT04 α= K↑ K↓ Q* = QH + QE + QG P = Et + r + ∆S QE = Lv Et β= QH QE Pa = ρw g ΔZw + e*(T) ΔPL = ρL g ΔZL g ΔZ p VG = f ΔN δ = − 23.4 cos ( 360(T J + 10) 365 ) e = ρv Rv T where Rv = 462 J kg-1 K-1 (for water vapour) e = ρd Rd T where Rd = 287 J kg-1 K-1 (for dry air) vpd = (e*(T) – e) e = e*(Td) e = e*(Tw) - λ(T-Tw) where λ = 66 Pa 0C-1 (over water) e = e*(Tw) - λ(T-Tw) where λ = 58.2 Pa 0C-1 r= (over ice) 0.622 × e g × 1000 P−e kg RH = e e * (T ) × 100% = r × 100% rs f = 2Ωsin ø where Ω = 7.27 x 10-5 s-1 11 UNBC ENSC 201 SAMPLE FINAL LAB EXAM ANSWERS FOR STUDENT PRACTICE Chris Jackson 12
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