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Peter Solarz
we're not kids anymore.
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Xuebing Du
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@drooling-for-boys
Forget About Electrons And Protons; The Unstable Muon Could Be The Future Of Particle Physics
“Humanity can always choose to build a bigger ring or invest in producing stronger-field magnets; those are easy ways to go to higher energies in particle physics. But there’s no cure for synchrotron radiation with electrons and positrons; you’d have to use heavier particles instead. There’s no cure for energy being distributed among multiple constituent particles inside a proton; you’d have to use fundamental particles instead.
The muon is the one particle that could solve both of these issues. The only drawback is that they’re unstable, and difficult to keep alive for a long time. However, they’re easy to make: smash a proton beam into a piece of acrylic and you’ll produce pions, which will decay into both muons and anti-muons. Accelerate those muons to high energy and collimate them into beams, and you can put them in a circular collider.”
There are lots of possibilities being discussed for how we could build a next-generation particle collider, capable of pushing past the frontiers where the LHC will be fundamentally limited. We could go to a larger proton collider, we could go back to doing high-precision collisions of electrons and positrons to create large numbers of the known, existing particles, or we could push the frontiers in an entirely new way: by colliding muons with anti-muons.
“But they only live for 2.2 microseconds,” you correctly object. Good thing we understand physics. If we can get the technology there, it’s the best option imaginable.
A-level Chem: Mechanisms Pt 1
Part 2
What's the best way to explain weak force to a 4 year old?
Everything in the world is made up of atoms.These atoms are like little legos that build up everything we know. Every atom is made up of three even smaller things: protons, neutrons, and electrons. Each of these is made up of even tinier building blocks called quarks. These quarks come in six different types and each type is called a flavor.
Quarks always have a flavor, but sometimes the flavor can change. The weak force is what makes quarks change flavor. Often, this makes a proton turn into a neutron or a neutron turn into a proton. The weak force is also important in Beta Decay, which is the process that fuels stars.
Every fundamental force is carried by a fundamental particle. These particles are like quarks: very very small and hard to detect. These force-carrying particles are called bosons. We know the weak force exists because we have detected the boson that carries it. It is called the W boson and can have a positive or negative electric charge. It is also carried by the Z boson, but that is even more difficult to explain.
The weak force is very weak when compared to the Strong and Electromagnetic forces, but it is still stronger than gravity. The weak force also only works over incredibly tiny distances.
This is not a comprehensive analysis, so if you’re interested, here are some sources to read up more: LiveScience, a reddit post, Wikipedia, and Wikipedia for more info on the Standard Model and Electroweak theories.
– Admin Noah
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Things I wish I already knew going to University
Here are some reminders to myself. Hopefully, they are also helpful to some freshmen or anyone who’s curious:
1. University is not school.
You can’t shilly-shally around, take your sweet time and expect to just roll with it. Trust me, you will be in for a rude awakening. Find a goddamn studying method early in and stick with it. Flashcards and quizlets, whatever works for you. The deadlines and exams will draw closer faster than you think they will.
2. Your profs are not decoration.
Ask. Questions. Seriously. And go to office hours if you have any particular problem to resolve. Make use of that time. A lot of them will actually be thankful anyone is showing up. Against popular belief, professors indeed do make a mental note of a lot of their students. Don’t be one of those 20 people standing infront of their office for the first time a week before the exam.
3. Get as much work as possible done until noon.
It’s 12 and you have already studied for three and a half hours? Amazing. Look, I know, I am not a morning person either. But at least try it out. Get your sleep schedule in check. It will feel so much better than to procrastinate until evening and then you HAVE to do it anyway.
4. If you can explain it, you have understood it.
Done studying? Bet you’re not. Try explaining yourself the material loudly like teaching it to a clueless person. Or get yourself a study buddy and explain your subjects to each other. It’s even better if you don’t have the same majors. If you are able to explain the topic and have the other person understand it, you actually know the topic. If not, you now know where the shoe pinches. It’s also great practice!
5. You may feel a bit lonely at first.
Okay, I don’t want to scare anyone. I did find a lot of friends. Especially at first, everyone is your friend. Because everyone is scared of missing the boat and feeling left out. There will be so many people around you. Still – or maybe that’s the reason – you will probably feel a bit lonely at first. I want to tell you that this is normal. It’s because everyone is still a stranger to you and maybe you’ve just moved out! Maybe you are far away from home for the very first time. I’ve struggled with this. That’s fine! Everything will be fine. You will feel at home eventually.
I hope everyone is doing well. Take care! :)
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follow my instagram, I will let you know my next blog via instagram.
(Still working on new blog)
Organic Chemistry: Electrophilic Additions to Alkenes
Hey all! I wanted to put together a few review guides for the reactions I learned in my organic chemistry 1 class. I’m starting off with the alkene-related reactions, specifically with electrophilic additions. Despite being super hard to fully conceptualize (I still have trouble with them!!), they’re very important to recognize, because the same patterns repeat with other reaction types, particularly with alkynes. I’ll go through each reaction type here with a quick mechanism and jot down important bits of info. But before I start, I used a lot of abbreviations, so here’s a key:
R+ is carbocation
R is any group with a carbon
IM is intermediate
X is halogen
E+ is electrophile
RDS is rate-determining step
HOMO is highest occupied molecular orbital
LUMO is lowest unoccupied molecular orbital
Squiggly lines indicate enantiomers formed due to alternating wedges and dashes
Addition of HX
Introducing Markovnikov’s rule: the formation of a more stable R+ is favored b/c it’s a lower energy process
Alkene additions proceed faster via a more stable R+ IM (kinetics)
Tri-substituted carbons are favored over mono-substituted carbons
X is added to the more substituted carbon
Always watch for stereochemistry! Enantiomers can be formed as products
Carbocation Rearrangements
Carbocation rearrangements will occur so the R+ is as stable as possible
That’s why the Markovnikov product won’t always be the major product
Rearrangements usually occur through hydride shifts, but alkyl shifts can also happen if that’s the only possible route
Remember: always check to see where the positive charge is at− if you can shift a hydrogen or methyl group over to make that carbon extra substituted, then it’s probably right
With the orbital alignment (aka alkyl shift), there’s a filled-empty orbital overlap, where the migrating bond is aligned with the empty 2p orbital
Ring Expansions
Some questions are gonna ask you to do ring expansions, so always think alkyl shifts (again, this is so we form the most stable R+)
NUMBER. YOUR. CARBONS. This will get messy
Note that even though the di-substituted carbon doesn’t change after the first arrow, the shape changes from cyclopentane to cyclohexane, so it’s thermodynamically more stable
Hydration
This follows Markovnikov’s rule− the OH group is always on the more substituted carbon of the alkene
Also this is pretty much a repeat of HX addition, but with some acid-base action
Pro-tip: your catalyst, H3O+, is always gonna be the electrophile, and your nucleophile is always gonna be the double bond, so START THERE!
There’s gotta be water after that first step (hydration, duh)
Your water is now a nucleophile, and it’s gonna start attacking the R+
Remember to follow through with any possible R+ rearrangements− we won’t need it here b/c the R+ is already tri-substituted
Your catalyst MUST be regenerated!! *insert acid-base reaction*
Side note: alkene dehydration is the reverse of hydration and is an E1 process
DON’T ADD H2O/H3O+ UNDER DEHYDRATION CONDITIONS
Instead, use a strong acid, like concentrated H2SO4
Oxymercuration-Demercuration
This is essentially an alkene “hydration” w/o the rearrangement part
We don’t have rearrangement b/c the mercurinium ion doesn’t have a carbon
When the mercurinium ion bridge breaks, the nucleophile (in the second example, water), attacks the MORE substituted carbon, whereas the HgOAc attacks onto the LESS substituted carbon
The OH and HgOAc add ANTI to each other, but then the H from BH4- changes orientation on the LESS substituted carbon (forming diastereomers)
Side note: as a variation, you can also use an alcohol (ROH) instead of H2O in the oxymercuration step
Hydroboration/ Oxidation
The double bond nucleophile attacks the empty orbital in BH3
The BH3 attaches onto the LESS substituted carbon, so the positive charge builds on the MORE substituted carbon
I like drawing the third H in BH3 as an extension of BH2, so I can visually see the hydride shift
The OH from the peroxide basically replaces the BH2
The specific steps with BH3 get messy, so I was taught a revised method− basically, a concerted addition of BH3 w/ an internal H- transfer
There is regioselectivity in the sense that the partial positive charge follows Markovnikov’s rule
There is stereospecificity due to the syn (same side) addition of H and BH2 in the hydroboration product
Alkene Halogenation
Note that I2 doesn’t work here as a possible halogen
Markovnikov regioselectivity is present
There is ANTI stereospecificity, as in the two individual X’s from X2 attach themselves as opposite wedges and dashes
Alkene Halohydrin Formation
This is very similar to the previous alkene halogenation, except the second X in X2 doesn’t attach onto the final product
Rather, the nucleophile replaces the second X
Markovnikov regioselectivity is also present (this is SN1-like)
There is ANTI stereospecificity yet again (this is SN2-like)
And that’s it! Well, this is a good chunk of alkene reactions (and a pretty brief version of it). Regardless, I hope this is helpful! I hope to follow up with extra review mechanisms for additional alkene and alkyne reactions. Thanks for reading!!