Difference between revisions of "PChem312 s22 w2"
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::Thermal imaging (IR) can be used to evaluate heat loss...we have one of these cameras. | ::Thermal imaging (IR) can be used to evaluate heat loss...we have one of these cameras. | ||
− | ::- Balloons are interesting. The most important feature of a balloon is that the volume can change (boundary is not fixed). When you add more stuff, the pressure inside the balloon does | + | ::- Balloons are interesting. The most important feature of a balloon is that the volume can change (boundary is not fixed). [''Edited sentence follows, 1/21/2022, bes''] When you add more stuff, the pressure inside the balloon does change, but it mainly responds by increasing volume. Under most cases, a balloon is considered a closed system, but in reality, helium can diffuse through the walls of a latex balloon and hence are not truly closed. This is why we have Mylar balloons that can hold helium for months. It would be weird if a balloon attempted to be adiabatic...not even sure how this would be designed since the stretchiness of the walls is required to expand, resulting is thinner walls...balloons are by design diathermic. |
− | ::As noted above, when you add air/gas to a balloon, the volume changes, | + | ::As noted above, when you add air/gas to a balloon, the volume changes, and the pressure changes as well. In your notes, please draw a graph of pressure (y-axis) and volume of air (x-axis) and ass-u-me the balloon will burst at 30 psi, when 5 liters of air has been added. |
::Continuing with the balloon...watch this weather balloon [https://youtu.be/jXP-va2t4D8 video] then answer the questions below in your notes: | ::Continuing with the balloon...watch this weather balloon [https://youtu.be/jXP-va2t4D8 video] then answer the questions below in your notes: | ||
Line 37: | Line 37: | ||
====Lab Assignment==== | ====Lab Assignment==== | ||
− | Due by 6 pm TODAY (email Excel file)...make this [[Media:Heating_Cooling_H2O.pdf|Heating-Cooling Curve for Water | + | Due by 6 pm TODAY (email Excel file)...make this [[Media:Heating_Cooling_H2O.pdf|Heating-Cooling Curve for Water]]. So that i am very clear, you will open Excel, enter in the values shown for the constants (or global variables), and then use these constant to do the calculations and then graph. In a best case, you would come to CSB (either 377 or 378) and work on this assignment. IF you have questions, you can stop in lab after i do a 10 min intro to glassblowing. |
− | :Note: This work is to be done independently...ie. each student will enter all data into their own Excel file; please assist your friends but never touch their keyboard. | + | '':Note: This work is to be done independently...ie. each student will enter all data into their own Excel file; please assist your friends but never touch their keyboard.'' |
===Wed, Jan 19, 2022=== | ===Wed, Jan 19, 2022=== | ||
+ | ====Announcements==== | ||
+ | :1) Welcome to 5G ('''5'''th '''G'''eneration) cell service. This technology, which in part uses the C-Band (~4GHz) microwave technologies, may interfere with the altimeter on commercial airlines, hence thee has been a lot of concern over the launch. The cell phone companies have agreed to not use this frequency around airports for the time being...stay tuned. | ||
+ | |||
+ | :2) Great job in lab. There is a lot more to learn about glass and glass blowing, but i just wanted to give you a brief experience. If you like doing this, let me know; I usually leave at least 2 torches out on the lab bench all semester long. As you noticed, glass tubing comes in many sizes, some have a standard wall thickness (you did not work with this), some have a thick wall (your first tubing), and then some are specialized like the capillary tubing (very thick wall/very narrow opening). As you might have expected, when ordering glass tubing, you have a few parameters that need to be specified. First, you need to make sure you are purchasing [https://en.wikipedia.org/wiki/Borosilicate_glass borosilicate glass] and not [https://en.wikipedia.org/wiki/Soda%E2%80%93lime_glass soda lime glass] or a glass that has some invisible coating. Borosilicate glass, sometimes labels as "Pyrex" or "Kimex," is made using a well defined composition and hence it has the same coefficient of expansion (COE). As you see in the picture below, glass tubing has an ID (inner diameter) and an OD (outer diameter). You can also specify the wall thickness, but you really only need to specify 2 of the three parameters when ordering. | ||
+ | :[[File:Screen Shot 2022-01-19 at 6.52.13 AM.png|thumb|500px|none]] | ||
+ | |||
+ | :Next week in lab, we will fill your thermometer with ethanol, seal it, and then calibrate. | ||
+ | |||
+ | ====Class Assignment==== | ||
+ | 1) continuing with Sec 1.4: Equations of State/Ideal Gas Law | ||
+ | :- Review: There is a STATE --> described by STATE VARIABLES --> the relationship between the state variables is the EQUATION OF STATE (variables). | ||
+ | :- Equations of state allow us to have predictive powers. | ||
+ | :- Q: Why do we fit data to math equations? A: data reduction...x/y data set of 100 points can be reduced to slope and y-intercept. | ||
+ | :- PV=nRT or PV=NkT | ||
+ | ::* Units or "Dimensional Analysis" is VEY important. Write out in your notes the work that shows nR = Nk; | ||
+ | :::- R = 0.08314(bar*L)/(mol*K), | ||
+ | :::- k = 1.38e-23 J/K, <-- really J/(molecule*K) | ||
+ | :::- N = 6.022e23 molecules per mole or Avogadro's number | ||
+ | ::::nR = 1 mole * 0.08314(bar*L)/(mol*K) = 0.08314 (bar*L)/K | ||
+ | ::::Nk = 6.022e23 molecules * 1.38e-23 J/(molecules*K) = 8.31 J/K | ||
+ | :::::so does 0.0831 (bar*L)/K = 8.31 J/K ? | ||
+ | :::::to equate these units you need to convert bar*L in to Pascal*m<sup>3</sup> → see Table 1.1 or the front inside cover 1 bar = 1e5 Pa and 1 L = 1e-3 m<sup>3</sup>; so 1e5 * 1e-3 = 100, so 0.0831 (bar*L)/K *100 = 8.31 (Pa*m<sup>3</sup>)/K. | ||
+ | :::::so does a Pa*m<sup>3</sup> = J...yes it does...a Pa = kg/(m*s<sup>2</sup>) * m<sup>3</sup> = (kg*m<sup>2</sup>)/s<sup>2</sup> = J | ||
+ | ::::::What a pain in the ass...right? | ||
+ | |||
+ | :- Intensive (density)/Extensive (mass/volume) properties. | ||
+ | |||
+ | :2) Sec 1.5: Brief Intro to a Real Gas | ||
+ | :So although the ideal gas law is pretty good, not all gases are "ideal." So that we have a general understanding of how gases behave, there is the [[Media:The Kinetic Molecular Theory of Gases.docx|"Kinetic-Molecular Theory of Gases"]]...it states: | ||
+ | ::a. A gas consists of a collection of small particles traveling in straight-line motion and obeying Newton's Laws. | ||
+ | ::b. The molecules in a gas occupy no volume (that is, they are points). | ||
+ | ::c. Collisions between molecules are perfectly elastic (that is, no energy is gained or lost during the collision). | ||
+ | ::d. There are no attractive or repulsive forces between the molecules. | ||
+ | ::e. The average kinetic energy of a molecule is 3kT/2...more on this later. | ||
+ | |||
+ | :A guy named, van der Waals put together an equation which took into a account that there ARE interactions between gas atoms/molecules (d above are not totally true). Eq. 1.22 (p 15) is the van der Waals equation...of state for non-ideal/real gases. | ||
+ | ::::[[File:van der Waals eq.PNG|400px]] | ||
+ | :- Please use Excel to reproduce [[:File:van der waals example EXCEL.PNG|this figure]]; the van der Waals coefficients can be found [[:File:van der Waals table.PNG|here]]. PLEASE use global variables/universal constants/constant values so that once the Excel file is completed, you can change these parameters and the rest of the spreadsheet will update. If you don't know what a global variable is...ie. B3 vs. $B$3...please see https://youtu.be/6y_Nf6uvPxw | ||
+ | |||
+ | END | ||
+ | |||
===Fri, Jan 20, 2022=== | ===Fri, Jan 20, 2022=== | ||
+ | ====Announcements==== | ||
+ | :1) We are done with Chapter 1...fyi, this is a very slow start to the semester. Chapter 2 has some very important topics that set the foundation for thermodynamics, so i am not going to start this today, but instead in-person on Monday...9 am CSB 378. Let me remind you that attendance in PChem is essential. | ||
+ | |||
+ | ====Class Assignments==== | ||
+ | :1) You only assignment today is to verify all previous assignments. As i noted through out the wiki pages, i will check on MONDAY to make sure you did all the items i requested in the past 2 weeks. Each will count as a homework/lab assignment: | ||
+ | ::- Lab 1 carbon copies with notes on NOVA program, with answers to all 12 questions posted on wiki (week 1). | ||
+ | ::- Do your notes contain the units listed in Table ME-1.2? | ||
+ | ::- Do your notes contain the example worked out in section ME1.3? | ||
+ | ::- From last Friday...did you write out in your notes the 3 "heat" calculations (answers → 4810 J, you tell me, and ...)? | ||
+ | :::'''Note: although i could give you the answers to these problems, you should be confident in your answers based on your process of answering the problem; if you did not understand the problem, then you should go back to review the material or seek help.''' | ||
+ | ::- From last Friday...did you write out in your notes the 4 "heat"/ΔH calculations (ansers → 6.02 kJ, ..., 109 kJ, ...)? | ||
+ | ::- Do you have a graph drawn in your notes showing how you think that pressure inside of a balloon increases as a gas is added? | ||
+ | ::- Do you have answers (2) in your notes regarding the weather balloon video? | ||
+ | ::- Do you have the Gen Chem Lab calculations 3-6 in your notes? | ||
+ | ::- Did you submit the Heating-Cooling Curve for Water...last Tues? (''Don't worry i can check this myself'') | ||
+ | ::- Did you "Write out in your notes the work that shows nR = Nk" | ||
+ | ::- Did you complete the Excel file using the van der Waals equation of state? | ||
+ | I will print (no you) this [[PChem_Check_List_01|PChem Check List (first 2 weeks)]] and check your work on Monday. |
Latest revision as of 13:47, 21 January 2022
Mon, Jan 17, 2022
Announcements
- 1) Good Monday morning and happy Martin Luther King Jr. Day! If you have not recently seen/heard the original August 28, 1963 (I was 4 month old) MLK Jr. speech, i suggest you watch it now. Here is the full 17 min audio of the speech and here is a shorter 6 min "highlight" video. This is without a doubt a beautiful and timely speech. A particular part resonates with me as a teacher...he notes, "I have a dream that my four little children will one day live in a nation where they will not be judged by the color of their skin but by the content of their character."
- 2) Lab this week will be a hybrid experience...ie. there will be an assignment/worksheet posted below as well as meeting in-person in small groups of 4. Please review the list below to see when you are scheduled to show up. Please be on time, there will be a quick intro prior to you can starting your glassblowing; if you miss this, it will result in a timing problem.
Class Assignment
- 1) On Friday you were asked to read Section 1.3...by today. As noted, this section has a collection of bold terms that should now be aded to your notes. The main point of this section is to point out that when we engage in discussion of thermodynamics, we must be specific about every detail of the system and to clearly differentiate this from the surroundings. Consider the examples below:
- - If you wish to carry a cup of hot coffee from the cafeteria to your first lecture, you will choose a system (a container) that is closed (so it does not spill), is adiabatic (so it does not loose heat), and has a fixed volume/boundary (because it would be weird if it didn't). The coffee would be considered isolated from the surroundings in a closed system. The company YETI would not be able to charge so much for a travel coffee mug if it did not seal well (remain closed as opposed to open), if it lost heat on sitting (diathermic as opposed to adiabatic), or if the steel walls where thin and easily dented.
- Thermal imaging (IR) can be used to evaluate heat loss...we have one of these cameras.
- - If you wish to carry a cup of hot coffee from the cafeteria to your first lecture, you will choose a system (a container) that is closed (so it does not spill), is adiabatic (so it does not loose heat), and has a fixed volume/boundary (because it would be weird if it didn't). The coffee would be considered isolated from the surroundings in a closed system. The company YETI would not be able to charge so much for a travel coffee mug if it did not seal well (remain closed as opposed to open), if it lost heat on sitting (diathermic as opposed to adiabatic), or if the steel walls where thin and easily dented.
- - Balloons are interesting. The most important feature of a balloon is that the volume can change (boundary is not fixed). [Edited sentence follows, 1/21/2022, bes] When you add more stuff, the pressure inside the balloon does change, but it mainly responds by increasing volume. Under most cases, a balloon is considered a closed system, but in reality, helium can diffuse through the walls of a latex balloon and hence are not truly closed. This is why we have Mylar balloons that can hold helium for months. It would be weird if a balloon attempted to be adiabatic...not even sure how this would be designed since the stretchiness of the walls is required to expand, resulting is thinner walls...balloons are by design diathermic.
- As noted above, when you add air/gas to a balloon, the volume changes, and the pressure changes as well. In your notes, please draw a graph of pressure (y-axis) and volume of air (x-axis) and ass-u-me the balloon will burst at 30 psi, when 5 liters of air has been added.
- Continuing with the balloon...watch this weather balloon video then answer the questions below in your notes:
- why did the balloon pop at high altitudes? (yes, this appears to be a compilation of multiple flights although it is not stated in the video comments).
- Could you calculate the change in volume as a function of altitude? how might you do this?
- Continuing with the balloon...watch this weather balloon video then answer the questions below in your notes:
- 2) This section (1.3) introduces the 0th Law of thermodynamics. It is the case that laws are numbered 1, 2, etc. but in this case it became evident after the 1st, 2nd, and 3rd laws were defined, that there was a clear observation that should have been acknowledged by a "law." The 0th Law of Thermodynamics says, thermometers work...or more formally what is written in your textbook (p. 11).
- 3) Sec 1.4. This section has been previously discussed in Gen Chem, but here the authors add a little math-crap to again show that math is a very useful tool. To remind you of the Gen Chem "Gas Laws" lab you did i ask you to redo the calculations using the ideal gas equation you did a few years ago...
- Complete steps 3-6 in your notes...the small bottle had a volume of 50 mL.
END
Tues, Jan 18, 2022
Announcements
- 1) We will begin training in glass blowing. Will will have a short "how-to" intro and then each of you will be given ~50 mins to make a rudimentary thermometer. Please attend lab (CSB 373) at the time listed below:
- - from 2-3 pm Sara S., Sarah P., Jordan K., Lucas
- - from 3-4 pm Jonathan, Eliza, Isaac, Alex
- - from 4-5 pm Zoie, Joseph, Jordan P., Madeline
- - from 5-6 pm Sreya, Brendan, Matt
Lab Assignment
Due by 6 pm TODAY (email Excel file)...make this Heating-Cooling Curve for Water. So that i am very clear, you will open Excel, enter in the values shown for the constants (or global variables), and then use these constant to do the calculations and then graph. In a best case, you would come to CSB (either 377 or 378) and work on this assignment. IF you have questions, you can stop in lab after i do a 10 min intro to glassblowing. :Note: This work is to be done independently...ie. each student will enter all data into their own Excel file; please assist your friends but never touch their keyboard.
Wed, Jan 19, 2022
Announcements
- 1) Welcome to 5G (5th Generation) cell service. This technology, which in part uses the C-Band (~4GHz) microwave technologies, may interfere with the altimeter on commercial airlines, hence thee has been a lot of concern over the launch. The cell phone companies have agreed to not use this frequency around airports for the time being...stay tuned.
- 2) Great job in lab. There is a lot more to learn about glass and glass blowing, but i just wanted to give you a brief experience. If you like doing this, let me know; I usually leave at least 2 torches out on the lab bench all semester long. As you noticed, glass tubing comes in many sizes, some have a standard wall thickness (you did not work with this), some have a thick wall (your first tubing), and then some are specialized like the capillary tubing (very thick wall/very narrow opening). As you might have expected, when ordering glass tubing, you have a few parameters that need to be specified. First, you need to make sure you are purchasing borosilicate glass and not soda lime glass or a glass that has some invisible coating. Borosilicate glass, sometimes labels as "Pyrex" or "Kimex," is made using a well defined composition and hence it has the same coefficient of expansion (COE). As you see in the picture below, glass tubing has an ID (inner diameter) and an OD (outer diameter). You can also specify the wall thickness, but you really only need to specify 2 of the three parameters when ordering.
- Next week in lab, we will fill your thermometer with ethanol, seal it, and then calibrate.
Class Assignment
1) continuing with Sec 1.4: Equations of State/Ideal Gas Law
- - Review: There is a STATE --> described by STATE VARIABLES --> the relationship between the state variables is the EQUATION OF STATE (variables).
- - Equations of state allow us to have predictive powers.
- - Q: Why do we fit data to math equations? A: data reduction...x/y data set of 100 points can be reduced to slope and y-intercept.
- - PV=nRT or PV=NkT
- Units or "Dimensional Analysis" is VEY important. Write out in your notes the work that shows nR = Nk;
- - R = 0.08314(bar*L)/(mol*K),
- - k = 1.38e-23 J/K, <-- really J/(molecule*K)
- - N = 6.022e23 molecules per mole or Avogadro's number
- nR = 1 mole * 0.08314(bar*L)/(mol*K) = 0.08314 (bar*L)/K
- Nk = 6.022e23 molecules * 1.38e-23 J/(molecules*K) = 8.31 J/K
- so does 0.0831 (bar*L)/K = 8.31 J/K ?
- to equate these units you need to convert bar*L in to Pascal*m3 → see Table 1.1 or the front inside cover 1 bar = 1e5 Pa and 1 L = 1e-3 m3; so 1e5 * 1e-3 = 100, so 0.0831 (bar*L)/K *100 = 8.31 (Pa*m3)/K.
- so does a Pa*m3 = J...yes it does...a Pa = kg/(m*s2) * m3 = (kg*m2)/s2 = J
- What a pain in the ass...right?
- - Intensive (density)/Extensive (mass/volume) properties.
- 2) Sec 1.5: Brief Intro to a Real Gas
- So although the ideal gas law is pretty good, not all gases are "ideal." So that we have a general understanding of how gases behave, there is the "Kinetic-Molecular Theory of Gases"...it states:
- a. A gas consists of a collection of small particles traveling in straight-line motion and obeying Newton's Laws.
- b. The molecules in a gas occupy no volume (that is, they are points).
- c. Collisions between molecules are perfectly elastic (that is, no energy is gained or lost during the collision).
- d. There are no attractive or repulsive forces between the molecules.
- e. The average kinetic energy of a molecule is 3kT/2...more on this later.
- A guy named, van der Waals put together an equation which took into a account that there ARE interactions between gas atoms/molecules (d above are not totally true). Eq. 1.22 (p 15) is the van der Waals equation...of state for non-ideal/real gases.
- - Please use Excel to reproduce this figure; the van der Waals coefficients can be found here. PLEASE use global variables/universal constants/constant values so that once the Excel file is completed, you can change these parameters and the rest of the spreadsheet will update. If you don't know what a global variable is...ie. B3 vs. $B$3...please see https://youtu.be/6y_Nf6uvPxw
END
Fri, Jan 20, 2022
Announcements
- 1) We are done with Chapter 1...fyi, this is a very slow start to the semester. Chapter 2 has some very important topics that set the foundation for thermodynamics, so i am not going to start this today, but instead in-person on Monday...9 am CSB 378. Let me remind you that attendance in PChem is essential.
Class Assignments
- 1) You only assignment today is to verify all previous assignments. As i noted through out the wiki pages, i will check on MONDAY to make sure you did all the items i requested in the past 2 weeks. Each will count as a homework/lab assignment:
- - Lab 1 carbon copies with notes on NOVA program, with answers to all 12 questions posted on wiki (week 1).
- - Do your notes contain the units listed in Table ME-1.2?
- - Do your notes contain the example worked out in section ME1.3?
- - From last Friday...did you write out in your notes the 3 "heat" calculations (answers → 4810 J, you tell me, and ...)?
- Note: although i could give you the answers to these problems, you should be confident in your answers based on your process of answering the problem; if you did not understand the problem, then you should go back to review the material or seek help.
- - From last Friday...did you write out in your notes the 4 "heat"/ΔH calculations (ansers → 6.02 kJ, ..., 109 kJ, ...)?
- - Do you have a graph drawn in your notes showing how you think that pressure inside of a balloon increases as a gas is added?
- - Do you have answers (2) in your notes regarding the weather balloon video?
- - Do you have the Gen Chem Lab calculations 3-6 in your notes?
- - Did you submit the Heating-Cooling Curve for Water...last Tues? (Don't worry i can check this myself)
- - Did you "Write out in your notes the work that shows nR = Nk"
- - Did you complete the Excel file using the van der Waals equation of state?
I will print (no you) this PChem Check List (first 2 weeks) and check your work on Monday.