Grades

On Thu, Dec 11, 2008 at 11:01 PM, Martin Mason wrote:
Grades will not be done by noon on Friday... I have just finished 2A and have only finished the first problem on 4A. I will be available on Monday at around noon for those of you who would like to go over your final.

Prof. Mason, you make us suffer! Now we have to wait the weekend in excruciating, nail biting agony as we ponder our fate in your class! =P

Thanks again for a great semester!

Mason's last blog entry

Great Job on the Blog everyone!
Here is a link to the notes from today. Sorry about all the typos.
http://docs.google.com/Doc?id=d3w6sww_1082fng9h8hs

For those of you who happen to read the blog, here is a hint for the exam.....

I spent six years of my life working with cyclotrons. You might want to review how they work and the principles behind them.

have fun,
mmason

Chapter 28

I have to agree with Sung..
I had the book hand in hand with me while doing chapter 28 and I still don't get most of the stuff that's on there.
There were a lot of equations used in the homework that we never saw in class.

mason~~~

mason, chapter 28 is soo hard :'( you know i rarely miss 100% on the homework, and i am not getting any score more than 100% this time . I will study as much as possible but chapter 28 is the most difficult stuff i have evern encountered in my life ! (crying crying)

Here is the link to the notes for today. We have finished chapter 27 today. Expect that we will do most of chapter 28 on Wednesday, so you might want to read ahead!

http://docs.google.com/Doc?id=d3w6sww_1007p7qnh8gp

have fun!
mmason

Magnetic Field =O=

Hi ladies and gentlemens, here is Kenny who doesn't know Physics at all but writes this blog for you. How ridiculous!? However it is my duty~~~

**OK~~ Let's start with our quiz. The hardest quiz I ever had in this week~~~It is a capacitor problem that we used to find potential different in anytime and anywhere. (2 charge problems are exception.)

a.) Compute the charge on the capacitor just before the switch is thrown from position 2 back to position 1.

Start with Q = CE (1 - e^(-t/RC)), where RC = T = 1.3E-5 * 960 = 0.01248sec
We have E = 18V, C= 1.3E-5, t = 10ms = 0.01 sec and RC = 0.01248. So we can find V!!!!!
Q = (1.3E-5)(18)(1 - e^(-0.01/0.01248) = 1.29*10^-4 C

Then we did c. first rather than b. , because c is easier!!!

c.) Compute the voltage drops across the capacitor at the instant described in Part A.

Pull out you equation sheet!!! V = Vo(1-e^(-t/RC)), the best way to do this problem~~!!

Vo = 18V t = 0.01sec RC = 0.01248
V = 18(1-e^(-0.01/0.01248)) = 9.92V~~~~ That's it~~~!!!

Go back to b.

b.) Compute the voltage drops across the resistor at the instant described in Part A.

Evaluate this problem as Kirchhoff's rule problem.
Vo - Vc -IR = 0
18V - 9.92V = IR - 8.02V

d) Compute the voltage drops across the resistor just after the switch is thrown from position 2 back to 1

In this problem, battery is taking out from the circult, the capacitor becomes the power source!!

Vc - IR = 0 (Kifchhoff's rule again!!)

9.92 = IR ~~~~~!!!

Question e is equal to question d!! Did anyone do it in the quiz?? I hope not !!!!!

f.) Compute the voltage drops across the capacitor just after the switch is thrown from position 2 back to position 1.

This time we have V = Voe^(-t/RC)

g.) Compute the charge on the capacitor 10.0 ms after the switch is thrown from the position 2 backe to position1.

We have a faith from PMason to solve this, which is:

Q =CV

muti C for both sides on the equation at part h.

CV = CVoe^(-t/RC)
q = Q0 e^(-t/RC)

Here, I need to apologize with problem g & f, I missed the final answer for both question. Can anyone help me out, upload the answer by a comment!? Thank alot and I am so sorry......

How did you do!? Well done!? Bless you and hope PMason gives everybody an A~~~~~

Forget about the old stuff~~~ That is a new chapter coming in, and which is magnetic field!!!

We started with playing magnets!! As we saw that they attract and repel each other in particular way, we noticed that magnet has two poles - North pole and South pole. (What a big new!!! ...... for an elementary school child =@=")

**Then, we discussed some characteristics of magnets and magnetic field.
1. North geographic pole is a south magnetic pole. Oppositely, South geographic pole is a north magnetic pole. (WHAT??@@??)
Yeah, that surprise me also. North is not north?? south is not south?? It may causes you seconds to understand it. Let's take a look with a compass, it helps. The south needle attract with the north magnetic pole in the south pole. Therefore the south needle always point towards south. It can also apply on north needle. It is clear?? @@??

2. Ways to dismagnet a magnet
It should be an extra info. - We can dismagnet magnets by banging one to another, or put them into fire . (High temperature disorders the orientation of the magnetic field inside the magnets.

3. Orientation determination (Magnet)
Just like what I described above in 1.

4. Destory of a magnet
Only one point - If you cut a magnet in half, the origial south pole and north pole are keeping in same magnetic pole. New poles are created in other ends of the magnetic.

N == S ----Cut it half----> N=S N=S

5. Reorientation
Do you remeber how PMason put a line of staple on the huge magnet that Chung plays alot!? The staple gets magnetic field for awhile. It shows that metal can reoriented by touching another magnet!!!

**The following is the main part of this meeting!!! Magnetic Field.
PMason put some metal powder around a magnet. We saw a particular pattern formed! That pumpkin liked shape is the visual shape of magnetic field.

Actually Magnetic Field (B - SI unit: Tesla & Gauss) is pretty much like other Field. It also has flux. We know Electric flux is equal to the intergral of E*dA. Magnetic flux is equal to the intergral of B*dA. The main different of Magnetic flux from Electric flux is the net magnetic flux in a closed three dimensional surface. Because there are no magnetic monopoles as pole should be in pair. So the net magnetic flux coming out of a close 3-D surface is equal to ZERO!!!!

Lastly, we played with an oscilloscope. PMason described the structure of the oscillosocope. The visual light from the oscilloscope can easily influenced by changing the charges of the parallel plates inside the oscilloscope. It is hard to explain all the variables. However we must remeber, It visualized Britney Spears Voice !!!!!!

............Oh my God ~~~ I wrote so much stuff. In order to make this blog complete. I want to add something at the end. "Where I have words on my Lab Notebook!!" I hope it helps everyone to know which exercise(s) we have done for today's lecture.

Where I have words on my Lab Notebook:
11.4.1 b.c.d
11.5.1 a
11.6 all

It is time to play PS3 ~~~ see ya~~~~
Kenny@Mason4B

Fire Fire everywhere

Here are the Capacitance notes from class today:
http://docs.google.com/Doc?id=d3w6sww_8367z2pt7g9

Have fun and stay warm!
mmason

Exam 2

There WILL be class tomorrow(Wednesday). There will also probably be a quiz. (Think applications of guass' law or intro to capacitance or both!) We will be talking about capacitance and finishing most of chapter 24.

The exam is graded. I was pretty happy with the result. There were more A's this time then on the first exam. However, the average went down somewhat. Several of you brought your grades up substantially!

See you all in class,
mmason

homework

So what's going on with the homework? Was it still due at 12?

About the solution given yesterday in SI....

there's some mistakes been pointed out....

and milan wants me to write nothing more than this....

so here are the solutions

http://docs.google.com/Doc?id=dhtfdzv3_5hbrhsjhm
img18 page1

http://docs.google.com/Doc?id=dhtfdzv3_7ctpg6whk
img19 page2


Milan's practice exam solution

and they are here.

http://docs.google.com/Doc?id=dhtfdzv3_13dgm2r3f7&hl=en
img25 page1

http://docs.google.com/Doc?id=dhtfdzv3_11hdw6qjfx&hl=en
img24 page2

http://docs.google.com/Doc?id=dhtfdzv3_9dxbmcrdq&hl=en
img23 page3

http://docs.google.com/Doc?id=dhtfdzv3_21drc83zhd&hl=en
img22 page4

http://docs.google.com/Doc?id=dhtfdzv3_19f8967ggq&hl=en
img21 page5

http://docs.google.com/Doc?id=dhtfdzv3_17f9qddpd6&hl=en
img20 page6

and these are the handout for ch.21 & ch22

http://docs.google.com/Doc?id=dhtfdzv3_23c64x6md4&hl=en
img26 page1

http://docs.google.com/Doc?id=dhtfdzv3_25dgm2wchk&hl=en
img27 page2

http://docs.google.com/Doc?id=dhtfdzv3_27x28sqx8r&hl=en
img28 page3

IMPORTANT!!!!!! Si Study section for Exam 2 on Sat 11/1/08

mimi said:

Hey, guysThere is a special SI session for Mason's 4B class
on Saturday 11/1/08, and I do have a lot of stuff to share with you
guys, and they might help for u for preparing the second
exam! And i also have some interesting probs for those ppl
who are ready for the exam!please feel free to come~~
Place: study room~~hopefully i can get a classroom
Time: 1 pm - whenever u are ready for the examHave fun
on physicsHappy halloween : )cya on Sat

mimi

Circuits Notes

Here are the notes on Circuits

http://docs.google.com/Doc?id=d3w6sww_705hjfgjvhs

Have fun!
mmason

DC current: Resistors, and Introduction to Kirchhoff's Law

on wed. October 22, class started with a fiesta of knowledge just like all Wednesdays.

In the fiesta of knowledge we were asked to find the resistance and resistivity of a copper extension cord, the max current through a copper wire and some other stuff that I do not remember.

After the fiesta we started unit 7: Direct current circuits,we skipped the first couple sections.

we started on 7.7 Using a multimeter

we built a circuit with a resistor and were given a multimeter.

We learned how to use the multimeter to measure measure DC current(amps), potential difference (volts) and resistance and this is how is done for the multimeter we were using:

1)To measure DC current the selector on the multimeter has to be on Amps, the correct range, connected in series with the circuit element and the positive test lead in the amps receptacle.

2)To measure potential difference(volts) the selector has to be in volts, correct range, connected parallel to the circuit element, and the positive test lead in the volts receptacle.

3)To measure resistance(ohms) the selector has to be on ohms, correct range, the resistor has to be disconnected from the battery, and the positive test lead in the resistance receptacle.

the negative test lead stays at the same position on the negative charge receptacle for this multimeter.

Then we moved on to Electric Power

we found out that if you multiply voltage (Joules/coulombs) and current (coulombs/seconds) the coulombs cancel and we end up with Joules/seconds which are the units for power. so, we get the definition of power:

P=VI (power=voltage X current

Resistance and its measurement

In a circuit potential energy is lost due to resistance. one of the most common resistors is the light bulb which turns potential energy into heat and light. But most electric circuits use resistors made of carbon, known as graphite, for resistance. Carbon is used because its resistance does not vary with the current passing trough them. They are cheap make and and can be made with low or high resistances.

Carbon resistors are color coded with different color bands that tell us its value in ohms. To get the value of the resistor we use the following table:

The Resistor code Table

Black =0

Brown =1

Red =2

Orange=3

Yellow =4

Green =5

Blue =6

Violet =7

Gray =8

White =9

silver =(+/-) 10%

gold =(+/-) 5%

so this is how we use the table to get the value of a resistor

value of the resistor (ohms)= AB x 10^C (+/-)D

Gold, and silver bands represent the tolerance of the resistors(if your first line is gold or silver turn the resistor around you are reading it backwards).

once you is turned around the fist two color band are A and B.(do not multiply A and B)

A and B are just placed next to each other and that is the first number.

the third color line is the exponent C, and finally the fourth line is you tolerance, D.

Prof. Mason gave a 2 resistors and we calculated their resistance using the Resistance Value Table, the we did the same for some combinations he wrote on the board. Then he proceeded to show what happens when a resistor is subjected to a higher current that what is rated for. Using a generator he burned a poor defenseless resistor to a crisp.

Measuring Resistances in Series and Parallel

We were given two identical resistor and then three identical resistor using a multimeter we measured the resistance in parallel and in series and we found that resistors in series in parallel the voltage stays the same but the two currents add up to the total current.

When we put the resistors in parallel the current stays the same voltages coming from the two resistor in parallel add to the total voltage of circuit

so this are the formulas:

Resistors in Parallel:

1/Req=(1/R1)+(1/R2)+(1/R3)+..........

Resistors in Series:

Req=R1+R2+R3+............

We also found that we have circuit with two resistors in parallel we can find the equivalent resistor using these formulas and then replace it with a single resistor.

Introduction to Kirchhoff 's Laws

First law: Junction Rule(based on charge conservation)

The sum of all the current entering any node or branch point of a circuit entering any node or branch point of a circuit must equal the sum of all currents leaving the node.

Second law: The Loop Law (based on energy conservation)

Around any closed loop in circuit, the sum of all emfs, voltage gains provided by batteries or other power sources, and all potential drops across resistor and other circuit elements must equal zero.

------------------------------------------------------------------------------------------------

we stopped because the class ended I agree with professor Mason this class is to short. Thursday, Friday, Saturday, and Sunday, four days without going to class is too much.

P.S I missed some of the stuff we did right after brake because Dante and Joy were holding up the line at the Mountie grill. It took them 25 minutes to order water and a cookie.

BAM!! + BAM! = 2BAM!

Jesus

Monday, Oct 20th, 2008

Hmm...... My first blog and I don't remember much lol

orz... I have no idea where to start but I'll give it a shot

So, the first question(?) we did in class was the empty cageish(?)

barrel that was electrically charged and aluminum foil was

hung inside the cage, and out side of the cage.

Our task was to guess how these foils reacted when the cage

became charged.

The inner ones did not get affected because the electric field

inside a conducting substance cancels out, and only the outside

ones flipped towards the outside. ( I aint rly sure if this is useful)

The second part(!) was ...... rolling balls down the nailed board(?)

The factors that affected the time the balls took to fall out was

1. The Cross sectional Area ( same as a wire, R = inversily proportional)

2. The Length of the run ( same as a wire, R = directly proportional to length)

3. The Density of the nails ( for sitting, the denser the better, but...... for

- the balls, less denser -> faster time )

The 3rd part was the...... relativity of parallel structure, series structure

of the batteries, and the light bulbs.

When light bulbs were set in a parellel structure, every lightbulb lit up

with the same brightness of a single bulb.

But when the light bulbs were set in a series structure, the brightness

decreased as more bulbs were added to the circuit.

When the batteries were set in a parallel structure, the voltage

equaled to a single battery, but the lifttime of the battery increased.

V = v1 + v2 + v3 ................for series structure

V = v1 = v2 = v3................ for parallel structure

R = r1 + r2 + r3................. for series structure

1/R = 1/r1 + 1/r2 + 1/r3 ..... for parallel structure

AND V = IR -> OHM's Law(?)

V -> voltage
I -> current
R -> resistance

Basically thats all I remember... for more detail,

go ask the professor maybe?

Special BLOG #2: well...it's about the HW #3

special blog AGAIN....but this time is just because i got mad at one of the question....

thought that there might be people like me got stuck....so here i come.

by the way this post is about Question #3 Down The Wire part 3

it says Find the total number of collisions ( Ne) that all free electrons in this extension cord undergo in one second.

did we talk about collision last time? ...I dont think so - -..

anyways...in order to do this question we must know that in the process of current flow..electrons are having collision EVERY second. with this.. it turns the question more sense than it sounds like initially. (collision in the current? wth.....)

sadly. this question is NOT in 4.1, which is what we were talking about last time in class.

this question is actually a current resistivity problem...(which is what we gonna talk about tomorrow...)

but how do we find T(i.e time) in I = n*q*Vd*A equation?...here we go.

1st we know that F=qE (back in the beginning of the electrict field...)

and also F=ma. then we can get ma=qE

since acceleration is just a simply Velocity per unit time... we know that a = V/T

then we can rewrite the equation to.... V = (qE/m)*T and this is the key equation of part 3..

since I = n*q*Vd*A...and we know that V = (qE/m)*T

we can then subsitude and get (I/A) = n*q*T*(qE/m), which equavilen to J = (n*T*q^2/m)E

does anyone wonder what's the p given in the question for?

here is where we use p, turn your book to Pg. 851. we can find a equation call p = E/J (25.5)

nice....now we can combine the two equation we have to generate our T(time) qeuation....

from J = (n*T*q^2/m)E, we can move J and E around and make (m/n*T*q^2) = E/J

and we know form p = E/J (25.5), we know p = (m/n*T*q^2), furthermore, we can move p and T and generate this T equation, T = (m/n*p*q^2), and now we are good to go.

since the question asked collisions per second, we can think about it is the total electrons collisions in the cord every second... therefore, the answer will be (n*V)/T. just plug number

in and you are good to go....

(end)

Wednesday 10/15/08

Hi everyone, here's what happened in class on Wednesday,

But before I start, Professor Mason advised me to use humor in the blog.
This is why I am going to do the exact opposite!
Just kidding...
Anyway, here's the first thing we did: the mighty quiz:

It was a question similar to the problem of the Geiger counter that we did on mastering physics.
a) The first part was to find the electric field due to a wire inside of a cylinder if I remember correctly of potential difference V = 50000 Volts:

We started out with

V = ∫ (2k λ/r) dr [The limit of integration is from r_a to r_b ]

V = 2 k λ ln (r_b/ r_a)

Then we used E = (2 k λ) / r

2 k λ = E . r ( use this equation to substitute in the potential equation)

V = E . r ln (r_b/ r_a)

E = V / (r ln (r_b/ r_a)) = 50000/ (0.07 * ln (0.14/ 88*10^-6) = 96891 N/C.

b) the Second part was to evaluate the charge of a dust particle if there was an electric force 10 times as the weight of that particle (I don’t really remember if it was a dust particle, but the mass was 30.5 * 10^-9 Kg and that’s what matters in this problem)

W = mg = 30.5 * 10^-9 * 10 = 3.05 * 10^-7 N (Use g = 10 m/s²)

F_e = 10 * W = 10 * 3.05 * 10^-7 = 3.05 * 10^-6 N = q . E

q = F / E = 3.05 * 10^-6 / 96891 = 3.15 * 10^-11 C

c) The last part of the question was asking for its direction:

The answer was going towards the wall. (The answer was given inside the description of the problem)

----------------------------------------------------------------------------------------------------------------------------------------

Now the part of the quiz was over and of course as usual, most of the students asked for a make-up quiz.
Request was denied!

Moving on to Unit 6 in our lab notebook, which is chapter 25 in the book, Professor Mason started out by explaining what an electric current is flow is.

According to Professor Mason's definition, "The rate of flow of electric charge is more commonly called electric current. If Charge is flowing through a conductor, then the official mathematical definition of the average current is giving by:

I_avg = ∆Q / ∆t

Instantaneous current is defined by I = dQ/ dt.

The Unit of current is called the ampere (A). One ampere represents the flow of one coulomb of charge through a conductor in a time interval of one second. "

According to the book's definition, "A net charge dQ flows through an area in a time dt, the current I through the area is I = dQ/dt. (Current is not a vector)"

Here's a video done by UCI addressing this issue.

http://www.physics.uci.edu/outreach/demos/electricity/foamp.php

I thought so too.. !!

So back to our labs, we had to do our first experiment: lighting a bulb.

Activity 6.3.1

a) Given a light bulb, a wire, and a battery, we had to think of 2 different ways to light a bulb. Sketch it.

b) We also had to think of two others in which the bulb doesn't light. Sketch it.
I have to say, there were marvelous drawings from most physics students.
That was a good time for some of us to think of switching majors to art.
I thought that was funny, anyway, the final conclusion was:

c) - The circuit has to be closed for the bulb to light.
- The wire has to be touching the bottom of the light bulb where electricity can travel through.
- The wire has to be touching the opposite ends of the battery simultaneously.

Activity 6.3.2
a) List some materials that allow the bulb to light:
- Keys
- Human beings
- Coins
b) List some materials that prevent the bulb from lighting:
- Rubber
- Paper
c) Categories of materials
- Metals are conductors.
- Non-metals are non-conductors.
- Semi-metals are semi-conductors.

We moved on to Activity 6.4.1 (Action of the switch)

a) The bulb socket is made of a plastic base and a piece of metal attached to the top of it in a certain shape where you can screw a bulb. It provides a conducting path for electricity to run through the metal part. The bulb must be screwed properly for it to light. If you unscrew the bulb while it is still connected to the metal piece, the circuit is open and it won't light.

b)The filament of the bulb is made of tungsten as its coefficient of linear expansion is relatively high. It is shaped in a "zigzag" way so that the two rods that are holding the filament won't break if the metal expands.

c)The light bulb will light with the switch closed (contact) as it would be a complete closed circuit, where electricity flows through all conducting materials.

d) Observations:
- The light bulb lights with the switch closed.
- The light bulb doesn't light with the switch open.

e) As current flows through the bulb, the bulb gets warmer. Some electric energy is being lost or transferred into heat energy.

f) The current path must:
- be a complete closed path.
- be made of all electric conducting material.
- produce enough energy for the bulb to glow.

I think it was time for the best part in class: THE SHORTEST BREAK FOR THE LONGEST CLASS!

Activity 6.5.1

a) We had to connect three light bulbs, a switch, a battery and a lot of wires. We had to do a circuit drawing on paper also describing this circuit. Each bulb is connected separately so that if one of the light bulbs is disconnected, the rest will still light.

b) We had to use a tunnel switch and draw it on paper also. Whichever side of the switch it is closed on, the bulb will light and the other one will not and vice versa.

c) CROSS IT OUT ! I am so happy when we get a chance to do that.

After our great drawings once again, Professor Mason explained that it was impossible for scientists to communicate in that way. That's why we had to learn the circuit diagrams, and use the electric circuit symbols indicated in the lab notebook.

Activity 6.6.1

a) The long line represents the positive terminal while the short line represents the negative terminal.

b) We had to redraw the circuits designed in Activity 6.5.1.

Activity 6.7.1

The first answer for most groups in class was C: there will be less current in the return wire.
However, the right answer was discovered later on in another activity that it was D.
The current will be the same anywhere along the wire indicated in Model D.
The current is a scalar quantity and it's never lost anywhere in the wire. It's different than the concept of some of the electrical energy being transferred to heat energy.

Activity 6.8.1

a) If I recorded this correctly, the value was + 150 mA.

b) If the leads going into and out of the ammeter are reversed, the indicator needle would go in the opposite direction trying to measure a negative value below 0 mA.

Activity 6.9.1

a) Different circuits were achieved by displacing the ammeter and drawings of the circuits were included on paper in the lab notebook. Our group only had one ammeter where we could displace it.

b) Both models seem to work as the current is not different at any location in the circuit by displacing the ammeter. We reached this conclusion by recording the values in both cases and they were consistent. This will verify our conclusion for choosing Model D in activity 6.7.1.

----------------------------------------------------------------------------------------------------------------

Lastly, Professor Mason went over his notes to explain the current using different quantities

I = ρ_n q v_d A

Professor Mason went over this equation explaining each quantity and especially the drift velocity by poking some students with a long meter stick.
He also explained the idea that if you have a bunch of electrons stuck next to each other in a wire and if somehow you push one of the electrons in one end, an electron will get loose from the other end and it's not the same electron! The rate at which the electrons travel is called the drift velocity.

Everything is nicely explained in his notes posted. We didn't spend too much time at that last topic as the class was almost over and we didn't go over Resistance and Ohms Law.

Quick note: Chapter 22 and 24 are skipped for now and we'll come back to them later before the test!

The class stopped at that point and we finished 10 minutes early.
Another great moment in our Physics 4B experience this semester.

I hope this post was helpful. If there's anything that I missed or gave wrongful information Please let me know and I'll fix it. Especially in Activity 6.7.1. & 6.9.1

See you Monday!