There were two major events this week (actually, there were three). First we had the covalent bonding test with a day of review beforehand. Then, it was mole day, when we got to eat mole cookies and drink hot chocolate, listen to the mole song which drove Jackson crazy, and write an essay on hydrogen bonding and polarity. Lastly, we had the AP pre-test and the next day started the ionic and metallic bonding unit. The difference in electronegativity between hydrogen and oxygen results in the electron of hydrogen being pulled slightly towards the oxygen atom. This causes the hydrogen to have a slightly positive charge and the oxygen to have a slightly negative charge. Thus, in water, the slightly positive hydrogen's are attracted to the slightly negative oxygen's of different molecules. This attraction is called hydrogen bonding. It is not an actual bond, however, and is thus notated by a dashed line. Ionic bonding is a bond between a metal and a nonmetal in which the nonmetal takes the metals atoms and the two atoms are then attracted by the difference in charge. In metallic 'bonding', the cations are arranged in a lattice structure with all of the valence electrons being fairly free to move about the substance. This explains why metals are such good conductors of electricity.
So far, I understand this new section on ionic and metallic bonding very well. I was wondering why metals are ductile and malleable, although I think we will probably cover that very soon. I was also wondering why this section was called, "May the force be with you", as it doesn't seem relevant yet. I kind of hope it will be some pun on something we learn later, so halfway through the section I will be able to look back at it and go, 'Hah! I get this now.' I tried to be very engaged and a part of the learning process this week, despite the fact that most of this week was testing. I understood everything about this section so far, although I said that about the hybridization too and that didn't turn out so good. Anyways, I need to work on studying, especially with old material. I need to refresh my memory with everything, and in my free time (ha ha) I should do practice problems. I really didn't know about the sea of electrons, so now whenever I touch a metal I get this weird sensation of 'oh my, this is actually vibrating at speeds too fast for my comprehension, and the valence electrons are just kind of floating around all over the place...this is a bit worrying'.
Saturday, October 26, 2013
Sunday, October 20, 2013
10/21/13 Weekly Reflection
Most of this week was spent on VSEPR models and WebMO. Hybridization and the test on bonding coming up next week were also covered. However, the VSEPR and WebMO report was the center of attention for this week. WebMO is a really cool website that a couple of chemists came up with that you can use to diagram whatever molecules you would like. You can change settings for comparative purposes, draw ball and stick and space filling models, show dipole moments, and examine molecular diagrams for all sorts of fun stuff. It is a program that costs money and I think it was originally intended for colleges, but Dr. Finnan got us hooked up (thanks again, by the way). To better understand the WebMO and get more practice with it, we did a report in which we have to give the molecules we made and a table of information about them, as well as a paragraph explaining why each of these molecules is how it is. We also spent some time on hybridization because so many people were confused by it. Hybridization, as far as I can tell, is something that occurs constantly for all atoms that it is capable of occurring for (unlike hybridization), and in these elements the s and p orbitals are combined to form a hybrid sp orbital.
I have a few questions from this week, and I will do my best to explain them as clearly as possible. I was curious as to why hybridization occurs in any period excluding the second. For example, why does sulfur hybridize, but selenium and phosphorus do not? I had a couple of other questions, but as I was writing them out I answered them by myself, so I decided against writing them. For example, I had been wondering about why hybridization even happens, and I realized that it was simply a way of explaining why all of the bonds in, for example, tetrahedral molecules exhibit the same properties. I started the week with a confident, complete understanding of hybridization, but then I realized that my understanding of it was wrong. That put a damper on things, because now I had to get rid of some of what I had learned before and relearn it, which is frustrating because then you are never quite sure what is new and what were your preconceived, incorrect notions. I think I figured it out though. I completely understand VESPR models, and I tried very hard to participate as much as possible. Throughout this whole hybridization reimagination process, however, I realized that I had to work on my turnaround time for new, contradictory ideas. It took me way too long to change my thinking quickly and effectively on that particular topic. I will definitely be considering that problem and how to fix it.
I have a few questions from this week, and I will do my best to explain them as clearly as possible. I was curious as to why hybridization occurs in any period excluding the second. For example, why does sulfur hybridize, but selenium and phosphorus do not? I had a couple of other questions, but as I was writing them out I answered them by myself, so I decided against writing them. For example, I had been wondering about why hybridization even happens, and I realized that it was simply a way of explaining why all of the bonds in, for example, tetrahedral molecules exhibit the same properties. I started the week with a confident, complete understanding of hybridization, but then I realized that my understanding of it was wrong. That put a damper on things, because now I had to get rid of some of what I had learned before and relearn it, which is frustrating because then you are never quite sure what is new and what were your preconceived, incorrect notions. I think I figured it out though. I completely understand VESPR models, and I tried very hard to participate as much as possible. Throughout this whole hybridization reimagination process, however, I realized that I had to work on my turnaround time for new, contradictory ideas. It took me way too long to change my thinking quickly and effectively on that particular topic. I will definitely be considering that problem and how to fix it.
Sunday, October 13, 2013
10/14/13 Weekly Reflection
This week we covered a lot of material and did a lot of practice with bonding. We started the week with a review of VESPR molecules. We finished making balloon (or electron domain) models and made gumdrop (molecular domain) models. We went back and finished our lab calculations and examined the general trend in class data. Wednesday was a shortened class because of Skytime, but we still had time to get through a POGIL on evaluating lewis structures using formal charge, resonance structures, and bond order. We lost time on Thursday as well because of a fire drill, but we still managed to get through another POGIL about similar concepts, this time including hypervalency. On Friday we white boarded a bunch of problems involving finding the best lewis structure for a molecule. Some of the most important considerations for this were formal charge, hypervalency, electron deficiency, octets/modified octets, and resonance structures. All of these were important because they are likely indicators of whether or not a lewis structure is correct. Then, we had a massive blast to the past with hybridization which linked orbital structures and detailed how and when atoms can have hybridized shells. First, you must add energy, forcing the electrons to disobey Hund's rule, which leaves more orbitals open to bond (like in the case of carbon). Then, all of the orbitals that were changed by this addition of energy are to be redrawn as a part of a hybrid orbital, sp.
I believe I may understand hybridization now, although after (and during) the Lquiz I was horribly confused. After a good period of focusing on other things I have had time to mull it over and I am fairly sure I understand it. As far as I can tell, Hybridization is just a way of describing how atoms in the second period can form the bonds that they do while allowing it to still be drawn in orbital diagrams. I understood the lewis structures, but I need more practice with them. It didn't help that Jackson was really, really good at doing them quickly (as was Nishant) but I needed a little more time to get my thoughts together, so I couldn't be sure if I reached my answers on my own or through their work. I tried hard to participate in my own personal growth and that of my table mates as much as possible this week, although I felt that I was 'carried' more that usual just because my group was so much faster than I was at the work. I think that I understand most of the material that we learned this week, but I need to practice it all, especially lewis structures, a lot more to improve my meager skills. I did have a few questions. First, Why doesn't hybridization work for the elements in the third and continuing periods (other than that you said so)? Second, how do you know which elements hybridize? Is it just determined by drawing the orbitals and looking at how many bonds they should make, and then how many bonds they do and comparing the two? Lastly, How do you know what orbital will be involved in a bond and what is in a hybrid orbital? What do those even mean? Also (these are from the Lquiz), why would you ask what is in a hybrid orbital when there aren't any hybrid orbitals involved? (I'm growing to enjoy reflective blogs. They are a good place to rant about things I don't understand and redeem myself by answering things I screwed up properly.)
I believe I may understand hybridization now, although after (and during) the Lquiz I was horribly confused. After a good period of focusing on other things I have had time to mull it over and I am fairly sure I understand it. As far as I can tell, Hybridization is just a way of describing how atoms in the second period can form the bonds that they do while allowing it to still be drawn in orbital diagrams. I understood the lewis structures, but I need more practice with them. It didn't help that Jackson was really, really good at doing them quickly (as was Nishant) but I needed a little more time to get my thoughts together, so I couldn't be sure if I reached my answers on my own or through their work. I tried hard to participate in my own personal growth and that of my table mates as much as possible this week, although I felt that I was 'carried' more that usual just because my group was so much faster than I was at the work. I think that I understand most of the material that we learned this week, but I need to practice it all, especially lewis structures, a lot more to improve my meager skills. I did have a few questions. First, Why doesn't hybridization work for the elements in the third and continuing periods (other than that you said so)? Second, how do you know which elements hybridize? Is it just determined by drawing the orbitals and looking at how many bonds they should make, and then how many bonds they do and comparing the two? Lastly, How do you know what orbital will be involved in a bond and what is in a hybrid orbital? What do those even mean? Also (these are from the Lquiz), why would you ask what is in a hybrid orbital when there aren't any hybrid orbitals involved? (I'm growing to enjoy reflective blogs. They are a good place to rant about things I don't understand and redeem myself by answering things I screwed up properly.)
Sunday, October 6, 2013
10/7/13 Weekly Reflection
This week, we did more POGILs on bonds and did the actual lab work for a lab. The POGILs were on covalency, bond order and bond strength, and the one we did on Friday was the start of VSEPR (Valence Shell Electron Pair Repulsion) models. We used red balloons to mimic the electron domains of bonded electrons and we used white balloons to mimic the electron domains of lone electron pairs. The white balloons were larger than the red because the red were subject to stronger attractive forces between the nuclei of the atoms and the electrons in the bond. The first of the earlier two POGILs were looking at bond orders and bond energies and how they are connected. As the bond order increases, bond energy also increases. The second of those POGILs looked at bond length, calculated bond order and lewis dot bond order and how they interact and in what ways. This segued into resonance structures, which are multiple, equally valid representations for a molecule in which bonds could be in various different places. Lastly, we did a lab on the reaction between brass and nitric acid. We got to work with one of the seven strong acids! We observed the reaction and are now trying to use a diluted sample of the result to determine the mass percent of copper in those brass screws.
This lab was slightly confusing, mostly because my group was assigned to do something different than I had written my lab report for (I wrote it for the calibration curve, not the visualization method) and, although I knew how to do it, it was unsettling. However, I understood the VSEPR models very well. I also understood the bond orders and bond energies relationships very well - they made a lot of sense, especially if you think of bonds as both chords of energy and relationships of attraction with electrons and nuclei at the same time. The material in the second POGIL also made a lot of sense. I did my best to participate in the learning as much as I could and as well as I could. I love my table group which helps a lot (although I liked my last one as well). I still have a few questions about the lab, however. First, what determines how long the reaction takes? Is it merely the quantities of reactant, and the more reactant the longer the reaction takes? Also, I'm sure we covered this, but what determines the electronegativity of an element? Obviously there is the periodic trend, but what determines that? One of the pitfalls when thinking on the particle level is that you start thinking about everything in terms of the subatomic particles that make it up, so now I'm thinking of the keyboard as a remarkable dense and complicated - nay, fascinating -structure.
This lab was slightly confusing, mostly because my group was assigned to do something different than I had written my lab report for (I wrote it for the calibration curve, not the visualization method) and, although I knew how to do it, it was unsettling. However, I understood the VSEPR models very well. I also understood the bond orders and bond energies relationships very well - they made a lot of sense, especially if you think of bonds as both chords of energy and relationships of attraction with electrons and nuclei at the same time. The material in the second POGIL also made a lot of sense. I did my best to participate in the learning as much as I could and as well as I could. I love my table group which helps a lot (although I liked my last one as well). I still have a few questions about the lab, however. First, what determines how long the reaction takes? Is it merely the quantities of reactant, and the more reactant the longer the reaction takes? Also, I'm sure we covered this, but what determines the electronegativity of an element? Obviously there is the periodic trend, but what determines that? One of the pitfalls when thinking on the particle level is that you start thinking about everything in terms of the subatomic particles that make it up, so now I'm thinking of the keyboard as a remarkable dense and complicated - nay, fascinating -structure.
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