Physical chemistry
Вставка
- Опубліковано 12 чер 2024
- Physical chemistry is the study of macroscopic, and particulate phenomena in chemical systems in terms of the principles, practices, and concepts of physics such as motion, energy, force, time, #thermodynamics, #quantum chemistry, #statistical mechanics, analytical dynamics and chemical equilibrium.
#PhysicalChemistry, in contrast to chemical physics, is predominantly (but not always) a macroscopic or supra-molecular science, as the majority of the principles on which it was founded relate to the bulk rather than the molecular/atomic structure alone (for example, chemical equilibrium and colloids). (Source: wikipedia)
This is the full course of Physical chemistry where the following topics have been discussed in a very comprehensive way.
⭐ Table of Contents ⭐
⌨️ (0:00:00) Course Introduction
⌨️ (0:06:22) Concentrations
⌨️ (0:11:58) Properties of gases introduction
⌨️ (0:15:29) The ideal gas law
⌨️ (0:26:10) Ideal gas (continue)
⌨️ (0:33:56) Dalton's Law
⌨️ (0:39:58) Real gases
⌨️ (0:50:44) Gas law examples
⌨️ (1:00:40) Internal energy
⌨️ (1:10:59) Expansion work
⌨️ (1:22:34) Heat
⌨️ (1:28:28) First law of thermodynamics
⌨️ (1:39:39) Enthalpy introduction
⌨️ (1:43:46) Difference between H and U
⌨️ (1:55:06) Heat capacity at constant pressure
⌨️ (2:03:20) Hess' law
⌨️ (2:11:59) Hess' law application
⌨️ (2:22:06) Kirchhoff's law
⌨️ (2:29:18) Adiabatic behaviour
⌨️ (2:41:47) Adiabatic expansion work
⌨️ (2:48:52) Heat engines
⌨️ (2:57:27) Total carnot work
⌨️ (3:07:48) Heat engine efficiency
⌨️ (3:11:30) Microstates and macrostates
⌨️ (3:21:54) Partition function
⌨️ (3:30:18) Partition function examples
⌨️ (3:37:55) Calculating U from partition
⌨️ (3:48:13) Entropy
⌨️ (3:56:34) Change in entropy example
⌨️ (4:09:55) Residual entropies and the third law
⌨️ (4:18:09) Absolute entropy and Spontaneity
⌨️ (4:27:46) Free energies
⌨️ (4:35:12) The gibbs free energy
⌨️ (4:45:48) Phase Diagrams
⌨️ (4:52:32) Building phase diagrams
⌨️ (5:00:43) The clapeyron equation
⌨️ (5:03:30) The clapeyron equation examples
⌨️ (5:18:29) The clausius Clapeyron equation
⌨️ (5:29:07) Chemical potential
⌨️ (5:35:57) The mixing of gases
⌨️ (5:48:32) Raoult's law
⌨️ (6:02:08) Real solution
⌨️ (6:12:13) Dilute solution
⌨️ (6:18:56) Colligative properties
⌨️ (6:27:26) Fractional distillation
⌨️ (6:37:35) Freezing point depression
⌨️ (6:48:50) Osmosis
⌨️ (6:56:44) Chemical potential and equilibrium
⌨️ (7:04:07) The equilibrium constant
⌨️ (7:10:46) Equilibrium concentrations
⌨️ (7:21:11) Le chatelier and temperature
⌨️ (7:36:07) Le chatelier and pressure
⌨️ (7:45:18) Ions in solution
⌨️ (7:54:48) Debye-Huckel law
⌨️ (8:02:22) Salting in and salting out
⌨️ (8:15:12) Salting in example
⌨️ (8:25:33) Salting out example
⌨️ (8:35:59) Acid equilibrium review
⌨️ (8:45:33) Real acid equilibrium
⌨️ (8:54:36) The pH of real acid solutions
⌨️ (9:02:12) Buffers
⌨️ (9:11:12) Rate law expressions
⌨️ (9:23:51) 2nd order type 2 integrated rate
⌨️ (9:34:18) 2nd order type 2 (continue)
⌨️ (9:42:54) Strategies to determine order
⌨️ (9:53:02) Half life
⌨️ (9:59:55) The arrhenius Equation
⌨️ (10:12:00) The Arrhenius equation example
⌨️ (10:20:46) The approach to equilibrium
⌨️ (10:34:55) The approach to equilibrium (continue..)
⌨️ (10:46:47) Link between K and rate constants
⌨️ (10:56:39) Equilibrium shift setup
⌨️ (11:06:13) Time constant, tau
⌨️ (11:16:13) Quantifying tau and concentrations
⌨️ (11:23:26) Consecutive chemical reaction
⌨️ (11:26:48) Multi step integrated Rate laws
⌨️ (11:41:39) Multi-step integrated rate laws (continue..)
⌨️ (11:51:24) Intermediate max and rate det step
⭐ Credit ⭐
This great course was Presented by : Dr. Michael Groves,
Department of chemistry and biochemistry, California state university.
License: Creative Commons Attribution license (reuse allowed)
YT: / @michaelgroves4463
⭐ Join our community ⭐
Join our FB Group: / cslesson
Like our FB Page: / cslesson
Website: cslesson.org
⭐ Learn More: ua-cam.com/play/PLKp3X-578hN9jCm2MEGCg50RKxCFZjU5Y.html
⭐ Table of Contents ⭐
⌨️ (0:00:00) Course Introduction
⌨️ (0:06:22) Concentrations
⌨️ (0:11:58) Properties of gases introduction
⌨️ (0:15:29) The ideal gas law
⌨️ (0:26:10) Ideal gas (continue)
⌨️ (0:33:56) Dalton's Law
⌨️ (0:39:58) Real gases
⌨️ (0:50:44) Gas law examples
⌨️ (1:00:40) Internal energy
⌨️ (1:10:59) Expansion work
⌨️ (1:22:34) Heat
⌨️ (1:28:28) First law of thermodynamics
⌨️ (1:39:39) Enthalpy introduction
⌨️ (1:43:46) Difference between H and U
⌨️ (1:55:06) Heat capacity at constant pressure
⌨️ (2:03:20) Hess' law
⌨️ (2:11:59) Hess' law application
⌨️ (2:22:06) Kirchhoff's law
⌨️ (2:29:18) Adiabatic behaviour
⌨️ (2:41:47) Adiabatic expansion work
⌨️ (2:48:52) Heat engines
⌨️ (2:57:27) Total carnot work
⌨️ (3:07:48) Heat engine efficiency
⌨️ (3:11:30) Microstates and macrostates
⌨️ (3:21:54) Partition function
⌨️ (3:30:18) Partition function examples
⌨️ (3:37:55) Calculating U from partition
⌨️ (3:48:13) Entropy
⌨️ (3:56:34) Change in entropy example
⌨️ (4:09:55) Residual entropies and the third law
⌨️ (4:18:09) Absolute entropy and Spontaneity
⌨️ (4:27:46) Free energies
⌨️ (4:35:12) The gibbs free energy
⌨️ (4:45:48) Phase Diagrams
⌨️ (4:52:32) Building phase diagrams
⌨️ (5:00:43) The clapeyron equation
⌨️ (5:03:30) The clapeyron equation examples
⌨️ (5:18:29) The clausius Clapeyron equation
⌨️ (5:29:07) Chemical potential
⌨️ (5:35:57) The mixing of gases
⌨️ (5:48:32) Raoult's law
⌨️ (6:02:08) Real solution
⌨️ (6:12:13) Dilute solution
⌨️ (6:18:56) Colligative properties
⌨️ (6:27:26) Fractional distillation
⌨️ (6:37:35) Freezing point depression
⌨️ (6:48:50) Osmosis
⌨️ (6:56:44) Chemical potential and equilibrium
⌨️ (7:04:07) The equilibrium constant
⌨️ (7:10:46) Equilibrium concentrations
⌨️ (7:21:11) Le chatelier and temperature
⌨️ (7:36:07) Le chatelier and pressure
⌨️ (7:45:18) Ions in solution
⌨️ (7:54:48) Debye-Huckel law
⌨️ (8:02:22) Salting in and salting out
⌨️ (8:15:12) Salting in example
⌨️ (8:25:33) Salting out example
⌨️ (8:35:59) Acid equilibrium review
⌨️ (8:45:33) Real acid equilibrium
⌨️ (8:54:36) The pH of real acid solutions
⌨️ (9:02:12) Buffers
⌨️ (9:11:12) Rate law expressions
⌨️ (9:23:51) 2nd order type 2 integrated rate
⌨️ (9:34:18) 2nd order type 2 (continue)
⌨️ (9:42:54) Strategies to determine order
⌨️ (9:53:02) Half life
⌨️ (9:59:55) The arrhenius Equation
⌨️ (10:12:00) The Arrhenius equation example
⌨️ (10:20:46) The approach to equilibrium
⌨️ (10:34:55) The approach to equilibrium (continue..)
⌨️ (10:46:47) Link between K and rate constants
⌨️ (10:56:39) Equilibrium shift setup
⌨️ (11:06:13) Time constant, tau
⌨️ (11:16:13) Quantifying tau and concentrations
⌨️ (11:23:26) Consecutive chemical reaction
⌨️ (11:26:48) Multi step integrated Rate laws
⌨️ (11:41:39) Multi-step integrated rate laws (continue..)
⌨️ (11:51:24) Intermediate max and rate det step
Hello I want to ask you that do have included practice questions in between ?
thank you!!!!!
Can you share the handout link download in pdf?
Sir do u have any pdf of this lecture??
À
⭐ Table of Contents ⭐
⌨️ (0:00:00) Course Introduction
⌨️ (0:06:22) Concentrations
⌨️ (0:11:58) Properties of gases introduction
⌨️ (0:15:29) The ideal gas law
⌨️ (0:26:10) Ideal gas (continue)
⌨️ (0:33:56) Dalton's Law
⌨️ (0:39:58) Real gases
⌨️ (0:50:44) Gas law examples
⌨️ (1:00:40) Internal energy
⌨️ (1:10:59) Expansion work
⌨️ (1:22:34) Heat
⌨️ (1:28:28) First law of thermodynamics
⌨️ (1:39:39) Enthalpy introduction
⌨️ (1:43:46) Difference between H and U
⌨️ (1:55:06) Heat capacity at constant pressure
⌨️ (2:03:20) Hess' law
⌨️ (2:11:59) Hess' law application
⌨️ (2:22:06) Kirchhoff's law
⌨️ (2:29:18) Adiabatic behaviour
⌨️ (2:41:47) Adiabatic expansion work
⌨️ (2:48:52) Heat engines
⌨️ (2:57:27) Total carnot work
⌨️ (3:07:48) Heat engine efficiency
⌨️ (3:11:30) Microstates and macrostates
⌨️ (3:21:54) Partition function
⌨️ (3:30:18) Partition function examples
⌨️ (3:37:55) Calculating U from partition
⌨️ (3:48:13) Entropy
⌨️ (3:56:34) Change in entropy example
⌨️ (4:09:55) Residual entropies and the third law
⌨️ (4:18:09) Absolute entropy and Spontaneity
⌨️ (4:27:46) Free energies
⌨️ (4:35:12) The gibbs free energy
⌨️ (4:45:48) Phase Diagrams
⌨️ (4:52:32) Building phase diagrams
⌨️ (5:00:43) The clapeyron equation
⌨️ (5:03:30) The clapeyron equation examples
⌨️ (5:18:29) The clausius Clapeyron equation
⌨️ (5:29:07) Chemical potential
⌨️ (5:35:57) The mixing of gases
⌨️ (5:48:32) Raoult's law
⌨️ (6:02:08) Real solution
⌨️ (6:12:13) Dilute solution
⌨️ (6:18:56) Colligative properties
⌨️ (6:27:26) Fractional distillation
⌨️ (6:37:35) Freezing point depression
⌨️ (6:48:50) Osmosis
⌨️ (6:56:44) Chemical potential and equilibrium
⌨️ (7:04:07) The equilibrium constant
⌨️ (7:10:46) Equilibrium concentrations
⌨️ (7:21:11) Le chatelier and temperature
⌨️ (7:36:07) Le chatelier and pressure
⌨️ (7:45:18) Ions in solution
⌨️ (7:54:48) Debye-Huckel law
⌨️ (8:02:22) Salting in and salting out
⌨️ (8:15:12) Salting in example
⌨️ (8:25:33) Salting out example
⌨️ (8:35:59) Acid equilibrium review
⌨️ (8:45:33) Real acid equilibrium
⌨️ (8:54:36) The pH of real acid solutions
⌨️ (9:02:12) Buffers
⌨️ (9:11:12) Rate law expressions
⌨️ (9:23:51) 2nd order type 2 integrated rate
⌨️ (9:34:18) 2nd order type 2 (continue)
⌨️ (9:42:54) Strategies to determine order
⌨️ (9:53:02) Half life
⌨️ (9:59:55) The arrhenius Equation
⌨️ (10:12:00) The Arrhenius equation example
⌨️ (10:20:46) The approach to equilibrium
⌨️ (10:34:55) The approach to equilibrium (continue..)
⌨️ (10:46:47) Link between K and rate constants
⌨️ (10:56:39) Equilibrium shift setup
⌨️ (11:06:13) Time constant, tau
⌨️ (11:16:13) Quantifying tau and concentrations
⌨️ (11:23:26) Consecutive chemical reaction
⌨️ (11:26:48) Multi step integrated Rate laws
⌨️ (11:41:39) Multi-step integrated rate laws (continue..)
⌨️ (11:51:24) Intermediate max and rate det step
Thank you for this
THANKS U'RE A LIFE SAVIOR
Best viewed at 2x speed
I am from india and i am here because of study to complete in with 12 hours,
Thanks for this video.
Will you please help me with organic and inorganic chemistry also?
Wow Beautiful lecture 👌. A lot of review from general chemistry and physics. I love how this course goes in depth in the overlap of physics and chemistry ⚗.
Amazing 👍
Amazing
Very Good.
I have a BS in Food and Nutrition with 4 semesters of Chemistry and a BS in Physics. I have always wanted to take Physical Chemistry. I am enjoying this lecture. Thank you.
Sounds like a lot of BS
Right, something a BS person would say... @@savage22bolt32
You are such amazing tutor...
Best lecture 💝🦋
Thank you very much. You sir are a hero. !!
Thank you so much! This helped me review Physical Chemistry and Thermodynamics~ :)
This is amazing 🔥🙏🔥🙏
Hi! May I kindly ask if I can have a copy of the powerpoint. Thank you so much for making this video it is extremely helpful! Mad respect.
Thank you very much
Perfect Lecture! Merci Beaucoup!
Good job..
so good , thanks
❤❤❤❤excellent
Thanks for the upload!
Thank you sir
Excellent work
Can i prepare for chemistry olympiad learning from this video?
Thanks so much. I'm a chemistry phobia but your video is making me calm
Hi Everyone! Feel free to check out the full version of this course (Academic Lesson repackaged my content here) and my quantum chemistry course (www.youtube.com/@michaelgroves4463/playlists).
Life savior thx.❤️🙏
Lastly, Thank You Sir.
Thank you so much 🙏🤩
is this for olympiads or jee
cool
Sir your work is out standing
please made course of inorganic chemistry as you do in above tutorial
this course is what you use for your alevels??!
Thank you exelente curse
Very useful, thank you.
:D thx
prof, why in adiabatic equation time 3:06:08 why is there a gamma -1 for all the equations from second row? where do we get it
from?
화학/화학공학과 전공 관련 강의 동영상이 제 UA-cam 채널에 많이 있어요. 공부하는데 많은 도움이 되었으면 좋겠네요.^^......
(There are many lecture videos about chemistry/chemical engineering majors on my UA-cam channel. I hope it helps you a lot in studying.)^^....
Quantam chemistry please
just in the last two days I saw a new discovery of a material that changes drastically it's insulation/conductivity properties with a magnetic field. what would cause that to happen?
I want to take full lecture on inorganic chemistry . Because I am studying Bs chemistry.
Wonderful video, do you plan on creating a video for quantum chemistry?
Super great 💡 idea
ua-cam.com/play/PL_j40xIfCA33gFKog0uQ3Zii1O2eEiA3E.html
@@jayaprakashhm8456 Thanks friend, this appears to be what I was looking for.
@@usernamehere94 yeah I was also looking for the same and Spectrometry too
Quantum chemistry please
This is incredible ❤️ Love from 🇮🇳🇮🇳
Great job sir ❤️❤️❤️
is this for jee neet or ncert based can i use ?
Will this help me for my AS level exams?
Great video, seriously very helpful. However is there a PDF of these slides I could download so I don't have to come back to this video every time if I just want to double-check something?
İ found a brief physical chemistry book with all formulas. Want the link?
@@sultanmuradsfrov9511 pls share
@@sultanmuradsfrov9511 yes plz share with us
@@shahzadiammara3920 just write: physical chemistry in brief pdf
@@tharuneswarjaisankar5975 just write physical chemistry in brief pdf
올림픽 보다가 알고리즘에 끌려서 왔는데 겁나 재밌넼ㅋㅋㅋㅋㅋㅋㅋㅋㅋ
Is there a link for the calculus review?
Almost done with organic 2, I seriously can’t wait for this class
Bro, Can you please tell in which order should i watch these courses?
@@Attitudecom-rc6sq gen chem, organic, pchem
@@enrihoward6077 brother , could u please send me one for complete separate chemical kinetics ? Will really appreciate
dude... i've got this course and organic 2 at the same semester
@@EliwoodX8 I'm planning to do the same. Can you share how was the study load
so, you don't have any formal logic? if not, can you recommend a page for me?
wow, Videos like these are always well appreciated, I don't need all that extra bullshit.. You got a subscriber @Academic Lesson person
At 1:53:08, why using lower temperature instead of delta T?
Dr. Groves, at 5 mins 5 secs, you say “and be left with newtons PER metre, or joules” . N m is ‘ newton - metres ‘, the SI unit. (Not newtons PER metre . Anyway, I’m sure you know this, and my question is :- it is obvious what “ newtons PER metre “ would mean, but how do you interpret or comprehend ‘ newton - metres ‘ ? That is, “ newtons TIMES metres “, ( N x m ). Thanks, and your (these) lectures are great.
Joules are simply a measurement of energy, they have the unit Newtons×meter because 1 joule has been defined as the amount of energy transferred (otherwise known as work done) when an object is moved 1 meter with the force of one Newton, another definition is the energy required to accelerate a 1kg mass at 1m/s^2 through a distance of 1m
I dare anyone to fully watch this video in one sitting
👍
Does anyone know a good inorganic course like this.
3:11:39 Statistical Mechanics
Thanks bro
Great course - however, there's a conspicuous typo in the Introduction with "destroyed"
Is this for neet also...
Ye jee k liye relavant h kya
I don’t think that Kelvin is defined in terms of Celsius… Isn’t it the other way around?
en.wikipedia.org/wiki/Kelvin
You are right but the definition changed (direction) just recently, in 2019. As I understand it, only from then on the Kelvin is the source of definition for deg. Celsius.
Yes indeed, the Kelvin scale is defined via fixation of Boltzman's constant and all other temperature scales are derived from that in the SI. This removed the experimental ambiguity of the triple point of water etc. This is, however, a very nerdy subject but important subject.
@@maxsk9074
Strange, since I studied it in the 1980s and in my courses Kelvin was primitive, fundamental, etc.
@@writerightmathnation9481
Previous definition: The kelvin, unit of thermodynamic temperature, is 1/273.16 of the thermodynamic temperature of the triple point of water.
2019 definition: The kelvin, symbol K, is the SI unit of thermodynamic temperature. It is defined by taking the fixed numerical value of the Boltzmann constant k to be 1.380649×10−23 when expressed in the unit J⋅K−1, which is equal to kg⋅m2⋅s−2⋅K−1, where the kilogram, metre and second are defined in terms of h, c and ΔνCs.
this seems to be what happened. i mean even for most scientists nothing will change so its nice to know but pretty pointless
but calling K "primitive" sounds like peak heresy to me as a physics guy - even back in the 80s 😁
Boye,s low
2:53
4:17:15
SOCIEMENT
thanks a lot professor, I love physical chemistry but you know what I can't see its applications in life can you please do that
الanalytical اللي ليها تطبيقات كتير
الكورس مفيد ولا لا؟؟
Translation video phasics
6:19:30
6:25
::)
KNOW THAT I WILL BE HERE EATING MY BREAKFAST LUNCH AND DINNER
1,7,7-Trimethylbicyclo[2.2.1]heptan-2-one
Z236900083-22_2Bac-SM,A-Biof_2023_اللهم اني اسألك بأسرار هذه سورة الشريفة ان تفهمني كتابك
atar banglata chai
Is this useful for neet????????
did you study is this ncert based is this good for jee also?
Nope
in my opinion this guy is just reading nothing to do with building the foundations
15:32
15:00
17:29
36:00
)
35:00
34:36
Sir your sound quality very disturbing
엥
ពិធិចូលកាន់តាំនែងគង់ សំអុល. អញ្ចងអោយ
.
Awww, how bad this isn't in spanish
5:05 Literally right after saying not to make unnecessary unit errors, you say that a Joule is a Newton per Meter. For Shame! At least it's written correctly on the slide...
It's a "Newton-Meter," ie, Newtons TIMES Meters. "Newton per Meter" is Newtons DIVIDED by Meters.
Best video in youtube by far, if you can share the ppt that would be great !
រៀនបានពីឆ្នាំ ទៅបោះពុម្ពសៀវភៅ