Chemistryacademy printed 2013 2014

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d

m v

    

  

mol A x

mol B  mol B mol A

mol A mol B x  mol B g A mol A

mol B g B x g B mol A mol B

gA x

mol A x

L atm mol K

mol A mol B gB x x  gB gA mol A mol B

R  0.0821

gA x

P1V1  P2V2   

 

D

D

D D D D

D

D

D

D

D

D

D D

D



















1

OH

O alkane

alkene O

O

NH2 amine

ether

alkyne O

O O

aldehyde

ketone

alcohol O

ester

NH amide

O

H

carboxylic acid



  

    

  



O H H

Br

Br

Br

Br

C H

Br Br

Br

C C

C C

Br

O C C

H O H

H C O

H C H


O NH



I’m sure you would all like to ace your first chemistry test. Here’s how: 1. Test yourself on the topics below to see what you know and don’t know. 2. Review this packet in its entirety. Be familiar with each of the topics that were covered in the powerpoint presentation. 3. Write down what you don’t know yet. If you don’t know something, ask a friend or ask me. 4. If you are missing anything it may be available on the class website: http://www.chemistryacademy.com 11. Draw an ether with the formula C3H8O. 1. What is chemistry? 12. Draw an amine, an alcohol, a carboxylic acid, an ester, and an 2. What is matter? amide. 13. Provide the molecular formula of leucine shown on bottom. 3. What is not matter? Give examples. 4.

What do chemists do?

14. What organic functional groups are present in sodium chloride, NaCl?

5.

Where does chemistry fit in with the other branches of science?

6.

Name a branch of science more basic than chemistry.

7.

List the branches of science from basic to applied.

8.

What is our simple scientific method?

16. What happens to molecular formulas when double bonds and rings are used?

9.

Give an example of a positive and negative control

17. Describe what you know about aristolochic acid.

15. Explain what is implied by the wedges and hatches used in the drawing of leucine. Does it contain straight chains, branched chains, or rings?

10. What is a synonym for a negative control? 11. Why are negative controls important for most drug studies?

18. Draw a chart organizing chemistry into including inorganic, and organic domains.

1.

Provide a positive control for an experiment designed to produce bubble gum that blows big bubbles

2.

How many bonds to the atoms C, N , H, and O form?

functional groups,

3. What is a useful mnemonic device for the bonding pattern of hydrogen, oxygen, nitrogen, and carbon? 1.

Who wrote The Skeptical Chymist?

2.

What is a natural product and why are they important?

3.

Why is chemistry awesome?

4.

Compare and explain the flammability of liquids to gases.

19. Be prepared to answer the essential question for this course: What is chemistry all about?

20. Be prepared to answer the essential question for this unit: what is chemistry all about? 5.

True or false: most combustion reactions produce water

6.

What is the difference between a physical and a chemical change?

7.

Provide an example of a physical and a chemical change.

8.

How could you identify methanol?














1

1


m

1


1


1


mL

1

1


1


measurement

SI Units unit

symbol

size

Unit Prefixes Prefix

mass volume distance amount brightness current time

kilogram liter meter mole candela ampere Second

kg L m mol cd A s

nano (n) micro (m) milli (m) centi (c) kilo (k) mega (M) giga (G)

billionth millionth thousandth hundredth thousand million billion

3. Complete the table Unit of measurement Length Mass Temperature brightness

6. Complete the table. Prefix Symbol

We usually use

Factor

But SI units require

Scientific notation

example

Giga Mega centi micro n

1,000 . . . .

10-3 microgram

Scientific notation 10-9 10-6 10-3 10-2 103 106 109







• • • •


_________ __________

________

_____________




pebbles Iron filings Method salt sugar sand

sand Iron filings pebbles

pebbles

Iron filings Method salt sugar

salt

Method Iron filings

Iron filings salt sugar

salt Method sugar





1




7

8


10



  















The 1989 IBM Atomic Image

By Your Name Here

Abstract: In 1989 Don Eigler from IBM ushered in the nanotechnology revolution by moving individual Xenon atoms to create the image shown above.

35 Xenon Atoms

Source: http://www-03.ibm.com/press/us/en/pressrelease/22260.wss

Eiglers Lab Notebook

Eigler with his STM Source: http://www.tainano.com/chin/Eigler.htm

Don Eigler (2006)

Source: http://www.theregister.co.uk/2006/06/13/don_eigler_valley/

Source: http://www.flickr.com/photos/jurvetson/456735511/in/set-30000/


The 1989 IBM Atomic Image

By Your Name Here

Abstract: In 1989 Don Eigler from IBM ushered in the nanotechnology revolution by moving individual Xenon atoms to create the image shown above.

35 Xenon Atoms

Source: http://www-03.ibm.com/press/us/en/pressrelease/22260.wss

Eiglers Lab Notebook

Eigler with his STM Source: http://www.tainano.com/chin/Eigler.htm

Don Eigler (2006)

Source: http://www.theregister.co.uk/2006/06/13/don_eigler_valley/

Source: http://www.flickr.com/photos/jurvetson/456735511/in/set-30000/

Don Eigler and the 1989 IBM Atomic Image The question “What is everything made out of” is one of the most fundamental questions of mankind, right up there with “Why are we here?”, and “Will that be on the test?”. Recorded ideas date back over 6000 years,1 first popularized in the west by the work of Democritus. Arguably the most compelling evidence for the atom being the fundamental particle of nature involves the human senses- smell, touch, sight, etc. Because of the small size of the atom, none of these are directly possible, so perhaps the next best thing is to observe it with the help of an instrument. This may have first occurred as early as 1981, 2 but the image that popularized it was taken by Dr. Don Eigler in 1989.3 Don Eigler is a ponytailed, well educated physicist and surfer. In 1989, he designed his own scanning tunneling microscope. An image of him with his instrument was taken during a 2006 interview.4 While studying the surfaces of solids, he came up with the idea of limiting the movement of atoms by performing his experiments at a few degrees Kelvin- close to absolute zero. In his own words from the 2006 interview, he found that “Through a combination of hard work, some horse sense and good, old fashioned blind luck, I happened to be positioned to discover that I could manipulate individual atoms with a scanning tunneling microscope.” Having discovered the ability to move individual atoms, Eigler decided to create a work of art to document his discovery. What he created is an image of the letters I B M using the noble gas Xenon, a dense and unreactive colorless gas. Was he forced at gunpoint to do the bidding of his IBM bosses?? According to Eigler: “I made that decision on my own. Management never said anything to me beforehand, and I did it with a very clear purpose in my mind. IBM gave me a job, gave me the opportunity when I needed one, gave me the opportunity to excel at doing the things that I love in life, and it was payback time. I pull no punches on that. It was my way of giving back to the corporation some of what the corporation gave to me.” Does Eigler get bored recounting the discovery, now that two decades have passed? “I don't mind talking to people when they're curious, for instance, about what I was thinking about or why did I do this or something like that. The thing is that I always get introduced to people as the guy who wrote I-B-M in atoms. After you have heard that enough times, you don't really need to hear it five more times.” Eiglers current interests are in the field of Spintronics, 5 a speculative field where future computers will be based not electricity (the translational movement of electrons) but on their spin…a sort of electricity where the electrons stay where they are. Sources: 1. Gangopadhyaya, Mrinalkanti (1981). Indian Atomism: History and Sources. Atlantic Highlands, NJ: Humanities Press. ISBN 0-391-02177. 2. G. Binnig, H. Rohrer “Scanning tunneling microscopy” IBM Journal of Research and Development 30,4 (1986) reprinted 44,½ Jan/Mar (2000). Available on the web at http://researchweb.watson.ibm.com/journal/rd/441/binnig.pdf 3. Imaging Xe with a low-temperature scanning tunneling microscope. DM Eigler, PS Weiss, EK Schweizer, ND Lang - Physical Review Letters, 1991 1189-1192. 4. A man and his microscope: IBM's quest to make atom-sized chips. The silver surfer speaks. Ashlee Vance, The Register, June 13, 2006. Available on the web at http://www.theregister.co.uk/2006/06/13/don_eigler_valley/ 5 Spintronics: A Spin-Based Electronics Vision for the Future. S. A. Wolf et al., Science 2001, Vol. 294. no. 5546, pp. 1488 - 1495





7





Element (note charges)

Number of protons

Number of electrons

Average atomic mass

O (oxygen)

8

8

15.999

Zn (zinc)3+ Sn (tin)-

Fe (iron)3+ C (carbon) H (hydrogen)+ Sg (seaborgium)

Element

Number of protons

Number of electrons

Number of neutrons

Mass number

C2+-12

6

4

6

12

10 26 Hg+-204

12 27

57 204



19 9

F-

9 protons 10 neutrons 10 electrons

41

2+

Ca

20

20 protons 21 neutrons 18 electrons

235

U

92

92 protons 143 neutrons 92 electrons













1 valence electron

+1

2 valence electrons

+2

Group 1

hydrogen 1.01 (H is a nonmetal)

2s

Li

3

Group 2

Na

3s

sodium

Mg

19

K potassium

24.31

Ca

20

calcium 40.08

39.10

5s

ď Š

37

Rb

rubidium

38

strontium 87.62

85.47 55

132.91 87

7s

Cs

cesium

6s

Fr

francium 223.02

Sr

56

Ba

barium 137.33 88

Ra

radium

226.02

3p

Transition metals: 2 valence electrons

magnesium

22.99

4s

2p

9.01 12

Group 3

Sc

21

3d

scandium 44.96 39

4d

Y

yttrium

Group 4

22

titanium 47.90

Zr zirconium

40

88.91

Lu

71

Ti

Hf

72

Lutetium

hafnium

174.97

178.49

6d

lawrencium

Lr

5f

La

Ac

actinium 227.03

41

Ce cerium 140.12

90

Th

thorium 232.04

Nb

niobium

Group 6

Cr

24

73

Ta

tantalum

Mo

42

molybdenum 95.94

W

74

Db

dubnium 262.11

59

Pr

praseodymium

140.91 91

Pa

protactinium

231.04

Mn

Tc

43

technetium 96.91

Re

75

tungsten

rhenium

183.85

186.21

180.95 105

Group 7

25

chromium manganese 52.00 54.94

92.91

261.11

58

lanthanum 138.91 89

Rf

rutherfordium

262.11

57

4f

104

V

vanadium 50.94

91.22

5d

103

Group 5

23

106

Sg

seaborgium

107

263.12

60

Nd

neodymium 144.24 92

U uranium 238.03

Bh

bohrium 264.12

61

Pm

promethium 144.91 93

Np

neptunium 237.05

Group 8

Fe

26

iron 55.85

Ru

44

Group 9

27

cobalt 58.93 45

ruthenium

Os

osmium 190.20

Hs

108

hassium

Sm

samarium 150.41 94

Pu

plutonium 244.06

Group 10

Ir

77

Pd

46

Pt

platinum 195.09

Mt

110

Eu

europium 151.96 95

Am

americium 243.06

silver 107.87

Ds

79

Au

gold 196.97

111

Rg

Darmstadtium roentgenium

(268)

63

Ag

47

106.40 78

Cu

copper 63.55

palladium

192.22 109

29

nickel 58.71

iridium

Meitnerium

Group 11

Ni

28

102.91

265.13

62

Rh

rhodium

101.07 76

Co

(272)

(281)

64

Gd

gadolinium 157.25 96

Cm

curium (247)

65

Tb

terbium 158.92 97

Bk

berkelium (249)

Zn

zinc 65.37

Cd

48

cadmium 112.40 80

Hg

mercury 200.59 112

Uub

Ununbium (285)

66

Dy

dysprosium 162.50 98

Cf

californium (251)

Al

14

4p

silicon

gallium

indium

Tl

Uut

Bi

Uuq

Po

84

bismuth

polonium (210)

208.98 115

Uup

116

Uuh

neon

20.18

Cl

Ar

18

chlorine

argon

35.45

39.95

Br

35

Kr

36

krypton

bromine

83.80

79.91

I

53

tellurium 127.60

121.75

Ne

10

F

19.00

Xe

54

iodine 126.90

xenon

131.30 86

At

85

astatine

Rn

radon

(210)

(220)

Uus

117

118

Uuo

ununtrium ununquadium ununpentium ununhexium ununseptium ununoctium (289) (295) (284) (289) (288) (293)

Ho

Holmium 164.93 99

Sb 52 Te Antimony)

207.19 114

selenium 78.96

74.92

83

lead

204.37 113

67

Pb

82

thallium

Se

He helium 4.00

fluorine

17

32.07

34

51

tin 118.69

114.82 81

7p

Sn

50

In

sulfur

As

arsenic

72.59

69.72

5p 6p

germanium

9

S

30.97 33

-1

Group 17

16.00 16

phosphorus

Ge

32

O

oxygen

P

28.09

Ga

49

N

14.01 15

Noble gases

Group 18

2

halogens

Group 16

8

nitrogen

Si

26.98

31

Group 15

7

carbon 12.01

aluminum

Group 12

30

C

B

7

6

-3 -2

Group 14

6

boron 10.81 13

5

+4, -4

+3

5

beryllium

6.94

4

Group 13

Be

4

lithium 11

metal

1s

3

0

8

Valence electrons:

Alkaline earth metals

H

1

nonmetal

Alkali metals

Es

einsteinium (254)

68

Er

erbium 167.26 100

Fm

fermium 257.10

Tm

69

thulium 168.93 101

Md

mendelevium (256)

Yb

70

ytterbium 173.04 102

No

nobelium (254)

Atomic number to 71

21

Symbol:

Sc

scandium to 103

44.96 metal metalloid

Solid Liquid Gas

Manmade

name Atomic mass

nonmetal


1 valence electron

+1

2 valence electrons

+2

Group 1

hydrogen 1.01 (H is a nonmetal)

2s

Li

3

Group 2

Na

3s

sodium

Mg

4s 5s

19

K

potassium 39.10

24.31

37

Rb

rubidium

Ca

20

calcium 40.08 38

strontium 87.62

85.47 55

132.91 87

7s

Cs

cesium

6s

Fr

francium 223.02

Sr

56

Ba

barium 137.33 88

Ra

radium

226.02

3p

Transition metals: 2 valence electrons

magnesium

22.99

B

2p

9.01 12

4

Group 3

Sc

21

3d

scandium 44.96 39

4d

Y yttrium

22

Lu

40

Hf

72

hafnium 178.49

Lr

104

La

58

Ac

actinium 227.03

Ce cerium 140.12

90

Th

thorium 232.04

V

vanadium 50.94 41

Nb

niobium 92.91 73

Ta

tantalum

Group 6

Cr

24

105

Db

dubnium 262.11

59

Pr

praseodymium

140.91 91

Pa

protactinium

231.04

Group 7

Mn

25

chromium manganese 52.00 54.94 42

Mo

43

W

75

molybdenum 95.94 74

76

rhenium 186.21

Sg

seaborgium

107

60

Nd

neodymium 144.24 92

U uranium 238.03

Bh

bohrium

263.12

264.12

61

Pm

promethium 144.91 93

iron 55.85

Re

technetium 96.91

Np

neptunium 237.05

Fe

26

44

183.85 106

Group 8

Tc

tungsten

180.95

261.11

lanthanum 138.91 89

Rf

rutherfordium

262.11

57

23

91.22

174.97

6d lawrencium

5f

Zr

Group 5

zirconium

Lutetium

103

4f

Ti

titanium 47.90

88.91 71

5d

Group 4

Ru

Group 9

27

45

ruthenium 101.07

Os

osmium 190.20

Hs

108

hassium

77

Sm

samarium 150.41 94

Pu

plutonium 244.06

46

Ir

78

Pd

195.09

Meitnerium (268)

63

Eu

europium 151.96 95

Am

americium 243.06

Ag

47

Pt

platinum

110

Cu

copper 63.55

palladium 106.40

192.22

Mt

29

nickel 58.71

iridium

109

Group 11

Ni

28

Rh

rhodium 102.91

265.13

62

Co

cobalt 58.93

Group 10

Ds

silver 107.87 79

Au

gold 196.97

111

Rg

Darmstadtium roentgenium (272) (281)

64

Gd

gadolinium 157.25 96

Cm

curium (247)

65

Tb

terbium 158.92 97

Bk

berkelium (249)

Zn

30

zinc 65.37

Cd

48

cadmium 112.40 80

Hg

mercury 200.59 112

Uub

Ununbium (285)

66

Dy

dysprosium 162.50 98

Cf

californium (251)

indium 114.82

5p

7p 67

Uut

Pb

83

114

Ho

164.93

Es

einsteinium (254)

(289)

68

Er

erbium 167.26 100

Fm

fermium 257.10

52

Bi

84

bismuth

Uuq

(284)

Sb

Antimony) 121.75

115

Uup

thulium 168.93 101

116

Uuh

neon

20.18

Cl

17

Ar

18

chlorine

argon

35.45

39.95

Br

35

Kr

36

krypton

bromine

83.80

79.91

I

53

tellurium 127.60

Po

Ne

10

F

19.00

Xe

54

iodine 126.90

xenon 131.30 86

At

85

astatine

Rn

radon

(210)

(220)

Uus

117

118

Uuo

ununpentium ununhexium ununseptium ununoctium (289) (295) (288) (293)

Tm

69

Te

polonium (210)

208.98

207.19

ununtrium ununquadium

Holmium 99

51

lead

204.37 113

Sn

82

thallium

selenium 78.96

74.92

tin 118.69

Tl

81

6p

50

Se

34

arsenic

He helium 4.00

fluorine

32.07

As

33

72.59

In

49

sulfur

2

Group 17

9

S

16

30.97

germanium

69.72

-1

16.00

phosphorus

Ge

32

gallium

O

oxygen

P

15

28.09

Ga

31

4p

N

Noble gases

Group 18

halogens

Group 16

8

14.01

silicon

26.98

Group 15

nitrogen

Si

14

aluminum

Group 12

7

6

-3 -2 7

carbon 12.01

Al

13

C

6

boron 10.81

5

+4, -4 Group 14

+3

5

beryllium

6.94

3

Group 13

Be

4

lithium 11

metal

Alkaline earth metals

H

1

1s

0

8

Valence electrons: nonmetal

Alkali metals

Md

mendelevium (256)

Yb

70

ytterbium 173.04 102

No

nobelium (254)

Atomic number to 71

21

Symbol:

Sc

scandium to 103

44.96 metal metalloid

Solid Liquid Gas

Manmade

name Atomic mass

nonmetal



 

  

  

w

1 1 1  0.01097 2  2  2 n 





+1

2 valence electrons

Alkali metals

+2

Group 1

1

1s

H

hydrogen 1.01

Alkaline earth metals Group 2

Li

2s

4

11

3s 19

4s

24.31

K

Rb Cs

20

87

Fr

francium 223.02

13

40.08 38

21

87.62 56

Ba

barium 137.33 88

3d

Ra

radium 226.02

Monovalent cations: Group 1, Ag: +1 Group 2, Zn: +2 Group 3, Al: +3

Sc

scandium 44.96 39

Sr

strontium

4d

71

Lu

Lutetium 174.97

6d

lawrencium

103

Lr

(and NH4+)

Ti

titanium 47.90

Zr

La Ac

23

72

Hf

hafnium 178.49 104

Rf

rutherfordium

41

Ce cerium 140.12

90

Th

thorium 232.04

Nb

niobium 92.91 73

Ta

tantalum 180.95 105

Db

dubnium

261.11

58

V

vanadium 50.94

91.22

lanthanum 138.91

actinium 227.03

Group 5

zirconium

262.11

57

5f

22

40

Y

5d

4f

Group 4

yttrium 88.91

89

common anions

3p

Transition metals: 2 valence electrons Group 3

Ca

calcium

cesium 132.91

6s 7s

magnesium

22.99

rubidium 85.47 55

Mg

sodium

potassium 39.10 37

5s

Na

12

262.11

59

Pr

praseodymium

140.91 91

Pa

protactinium

231.04

Group 6

24

Cr

Group 7

25

Mn

chromium manganese 52.00 54.94 42

Mo

molybdenum 95.94 74

W

tungsten 183.85 106

Sg

seaborgium 263.12

60

Nd

43

Tc

technetium 96.91 75

Re

rhenium 186.21 107

Bh

bohrium 264.12

61

Pm

neodymium 144.24

promethium 144.91

92

93

U uranium 238.03

Np

neptunium 237.05

Group 8

26

Fe

iron 55.85 44

Ru

Group 9

27

45

ruthenium 101.07 76

Os

osmium 190.20 108

Hs

hassium 265.13

62

Sm

samarium 150.41 94

Pu

plutonium 244.06

Co

cobalt 58.93

Rh

rhodium 102.91 77

Ir

iridium 192.22 109

Mt

Meitnerium

Group 10

28

Eu

europium 151.96 95

Am

americium 243.06

29

Ni

nickel 58.71 46

Pd

Cu

copper 63.55 47

Ag

palladium 106.40 78

Pt

silver 107.87 79

Au

platinum 195.09 110

Ds

gold 196.97 111

Rg

Darmstadtium roentgenium

(268)

63

Group 11

(272)

(281)

64

Gd

gadolinium 157.25 96

Cm curium (247)

65

30

48

80

66

Bk

berkelium (249)

81

Dy

dysprosium 162.50

113

98

Cf

californium (251)

Ho

Holmium 164.93 99

83

114

208.98

Uuq

Se Te

115

Uup

Cl

Ar

argon 39.95

35

36

Br

53

I

117

Xe

54

iodine 126.90

Uuh

Kr

krypton 83.80

bromine 79.91

85

116

18

35.45

Po

polonium (210)

neon 20.18

chlorine

tellurium 127.60 84

Bi

bismuth

lead 207.19

S

52

Sb

Ne

19.00 17

selenium 78.96

Antimony) 121.75

Pb

82

Uut

51

Sn tin 118.69

F

fluorine

sulfur 32.07 34

As

10

xenon 131.30 86

At

Rn

astatine (210)

Uus

radon (220) 118

Uuo

ununtrium ununquadium ununpentium ununhexium ununseptium ununoctium (289) (295) (284) (289) (288) (293)

7p 67

Tl

16

He helium 4.00

Group 17

16.00

arsenic 74.92

72.59

thallium 204.37

oxygen

P

33

Ge

50

9

Group 16

O

30.97

germanium

In

-2 8

phosphorus

28.09

indium 114.82

6p

Uub

Ununbium (285)

Si

69.72 49

15

2

-1

halogens

14.01

silicon

32

Ga

gallium

5p

Hg

mercury 200.59 112

4p

Cd

cadmium 112.40

Al

aluminum 26.98 31

Zn

zinc 65.37

Tb

terbium 158.92 97

Group 12

N

nitrogen

carbon 12.01 14

Group 15

Noble gases Group 18

7

6

-3 7

C

boron 10.81

9.01

5

Group 14

6

B

2p

beryllium

6.94

+3

5

Be

lithium

4

+4, -4

Group 13

(H is a nonmetal)

3

3

0

8

Valence electrons: metal nonmetal

1 valence electron

Es

einsteinium (254)

68

Er

erbium 167.26 100

Fm

fermium 257.10

Tm

69

thulium 168.93 101

Md

mendelevium (256)

70

Yb

ytterbium 173.04 102

No

nobelium (254)

to 71

Atomic number

21

Symbol: Solid Liquid Gas Manmade

Sc

scandium

to 103

44.96

name Atomic mass

metal metalloid

nonmetal



solution :


  

  

  

  


16S:

1s2 2s2 2p2 3s2 3p4


Principles and rules of electron configuration Principle or rule Heisenberg

Bad

Good

1s22p1

1s22s1

(e-position uncertain)

1s1

Aufbau (build up) Hund’s Rule (spread out) Pauli (opp. spins)

1s22s22p2 1s2

Unit 5 electrons Dr. B.’s ChemAdventure

1s22s22p2 1s2












3d periodic table scoring Please score yourself on your periodic tables and hand in to me. Period____ Names: ________________________________________________________________________________________ ________________________________________________________________________________________ __________ Accuracy: (for example, each element shows a number, straws are straight and true, arranged individually rather than by group)

_____Your score _____teacher score Neatness: (for example, highly legible, ruler used, typed in places, large clear title, etc) _____Your score _____teacher score Completeness (for example, your table has a prominent title, individual numbers for each element in the element box, and a straw or equivalent for each element

_____Your score _____teacher score Utility (for example a clear trend is visible, small differences can be differentiated, numbers on elements can be referred to, units are provided, etc) _____Your score _____teacher score

total: ________/40











our essential question:

I

O O O

O

OH H

NH O O OH

OH

O O

O O

1. taxol (paclitaxel)

O


I


W


W

stock value 

new price x investment original price

560 dollars x 1000 dollars  1150 dollars 485 dollars




O

st ck va u

′s s

$21 $20

x $500,000

$525,000


F


I H OH

O O

O

OH

O

O

H

NH O

O

H O

O

OH

OH

HO H O

O O

O OH O

H

O O

O

O

O

H

O

O OO O

1. taxol (paclitaxel)

N

azadirachtin

O

N

O

O

N

N

OH

O N

N

Co N N

3+

R

N

HO

N

O

O

O

P

O O

O

O O

3. Vitamin B12

N

O

OH O

H O O H O

H

H O

H

OH OH 4. ginsenoside rb2

N O

OH H

OH HO

O N

HO

OH OH

OH OH

O O

OH


HO

I

HO Na O S O O O

OH

HO HO HO

H O

H

OH

HO

H

OH

O H

H O H

O H

H O

O H HO H

H O H

O H O

O

H

H

HO

H O H H

OH OH O O O S O OH Na H O H

H O H H O H H

O H HO H HO

HO HO

O H

O

H

H

O H

H

O H

O

H OH

O

HO

O

H

H O OH H

O

OH H HO

HO

H OH

H OH

HO OH H HO O H HO

H O

O H

O H O H

OH



3



click on images to manipulate


F

F F

F

H H

C

H

H H

C H

O

H C

H

C H H H H

H

H C C H H O C H H H

O

OH

H

H H C

H

OH C C

OH

OH H

OH


• • • • •

13


14


Lithium

Aluminum

Sodium

bicarbonate

Calcium

Rubidium

Oxide

Fluoride

Beryllium

hypochlorite

iodide

dichromate

Barium

carbonate

nitrite

Francium

Zinc

bromate

iodate

silver

nitride

phosphide

hydroxide

phosphate


W


N

+ 1

0 + 2

+ 3

polyvalent

3

- -1 2


F


C


O

Br N

H O

Si F Li

O

Na


O


G


D H H N C H H C H H H

and

H H C H N H C H H H


U



I


W


C

r r r r  


go to 71

go to 103


d

m v

    

  

mol A x

mol B  mol B mol A

mol A mol B x  mol B g A mol A

mol B g B x g B mol A mol B

gA x

mol A x

L atm mol K

mol A mol B gB x x  gB gA mol A mol B

R  0.0821

gA x

P1V1  P2V2   

 

D

D

D D D D

D

D

D

D

D

D

D D

D







Our Essential Question:


r r r r r

r r r r r r r r r r

r


Our Essential Question:

W






  




S


C


 

 


I 12

Mg

magnesium 24.31

  

16

S

sulfur 32.07



I

1. Ice melts. What are the COOL signs of a chemical reaction you observed? Is it a chemical reaction? _____ How could you prove it?

2. Wood burns. What are the COOL signs of a chemical reaction you observed? Is it a chemical reaction? _____ How could you prove it?

3. Iron rusts. What are the COOL signs of a chemical reaction? Is it a chemical reaction? _____ How could you prove it?


  

          

 

 


         

   


 

  

     

 

   



 



I


  






I

ďƒ

H O

H O NaHCO3

+

H C C

O H

H baking soda _____ g _____ mol

H C C

O

Na

+

H O H

H

+

CO2 carbon dioxide

acetic acid

ethyl acetate

_____ g

_____ g

_____ g

_____ g

_____ mol

_____ mol

_____ mol

_____ mol

water


E







`



C

NO2 H

H O2N

NO2 H

H

H

N


T 

       


A 



E

10 grams H 2 x

mole H 2 2 moles H 2 O x  5 moles H 2 O 2 grams H 2 2 moles H 2


I


A




 






I







’ º






M2 M1

vice president sir robert boyle

1


M2 M1

1

1


1

M2 M1

44 4

1

 3.3


P1V1  P2V2 ;


T1 T2  V1 V2

T1 T2 340 K T2  ;  V1 V2 140 mL 50 mL


T1 T2  P1 P2

x

;

;


200





(


















procedure

molecular view + vocabulary



5.1 g 180.16 g/mol

.1005 L

1 mole NaOH 40 g NaOH x x 0.1 liter solution  4 g NaOH liter solution mole NaOH



D

D

D

D


HO Greasy: will dissolve in greasy solvents

watery: will dissolve in watery solvents (like water)

watery region

A “brick�: hard to dissolve in anything.



S1 S2  P1 P2

S1 S2 3.3 g /L 9.9 g/L (1 atm)(9.9 g/L)  ;  ; x=  3 atm P1 P2 1 atm x (3.3 g/L)


Percent solution by mass 

Percent solution by volume 

mass solute x 100 mass solution

volume solute x 100 volume solution

moles of solute Liters of solution


40 g NaCl 0.5 moles NaCl x x 0.08 Liters solution = 1.6 grams NaCl Liter of solution mole NaCl


Percent solution by mass 

Percent solution by volume 

mass solute x 100 mass solution

volume solute x 100 volume solution

moles of solute Liters of solution






s








D

D

D

D D

D

D

D

D



Percent error = measured chip calories/actual chip calories x 100


Title Name, Date

Data Q = mcDT Q= M= C= DT = =( )( )( ) = ___ J = ___Nutritional Calories

(For example: Potato Chip Calorimetry Or Energy Analysis of a common Snack Food) Schematic drawing With labels Of your calorimeter

caption

Conclusions Include the Nutritional Calories calculated for your chip, the estimated real nutritional calories for your chip, and an explanation for the difference.

Pick a topic: 1. What is calorimetry? 2. Sources of Error in our calorimeter design 3. A better design for the next experiment 10 points: 1. Effort: 5 points -does this represent 45 minutes of effort? 2. Calculations: 3 Points -are they accurate? 3. Analysis: 2 points: Why are the results so bad (or so good).




D

D

D

8


D

D

D D

D

D

D

D

10

D

D

D

D

D


D

D

D

D  •

 •

 •


D D D D

D

D

D

D

D

D



D


D

D

°

°

D

°

°

°

°

°


°

°

°

°

°

°

°


D D

D

D


D

D

D D

° °

°

°

°


D


D

DG = DH –TDS Where

D

DG = Gibbs Free Energy DH = Enthalpy in Joules T = Temperature (K) And DS = Entropy in Joules/K

D

D

D

D

D

D

D D

D

D

D

D

D

D

 D

D

.

D

D D


D D

D D

D

D

D

D

D

D

D D

D

D

D

D





Chemistry 1. Intro 2. data 3. matter 4. the atom 5. electrons 6. periodic table 7. bonding 8. reactions 9. the mole 10. gases 11. solutions 12. Energy 13. Reaction rates 14. equilibrium 15. Acids and bases



reaction rate 

Δconcentra tion Δtime


 reaction rate 

Δconcentration Δtime

0.100 mol / L  0.22 mol / L 4s

 0.03

mol liter  sec




collision theory










4




• • • • •







14.4


D

 

D

D

         



Name: _______________________

Period: _____

equilibrium lab 2

Perfume Lab Introduction: Esters may be prepared through the reaction of a carboxylic acid RCO2H with an Alcohol (R’OH), using a small amount of sulfuric acid as a catalyst.

RCO2H carboxylic acid

+

R’OH + alcohol

H2SO4

sulfuric acid

RCO2R’ ester

+

H2O water

+

H2SO4

sulfuric acid

Esters often have strong pleasant aromas. Carefully guarded mixtures of esters create expensive perfumes including Chanel #5, Aramis (for men) and others, some of which sell for hundreds of dollars per bottle. In this lab each student will create his own ester, and we will then share them to make perfumes.

For this chemical reaction, all of these reactants and products remain in solution. Therefore this reaction is reversible, and yields for this reaction can be low. In this experiment we will investigate the equilibrium mixture for this mixture after 24 hours.

Materials: Carboxylic acids listed on board Alcohols listed on board Sulfuric Acid (to be distributed by instructor) as a catalyst . Chemical Reaction Procedure: Mix 0.1 moles of your carboxylic acid, 0.1 moles of ethanol, and 5 drops of sulfuric acid. The calculations below will help make sure you are using the right amounts. Heat but do not boil on a hot plate for 20 minutes then store covered overnight.


Calculations: My carboxylic acid has a formula of _____, therefore one mole has a mass of ______g, and 0.1 mole has a mass of ______g. My alcohol has a formula of ______, therefore one mole has a mass of ______g, and 0.1 mole has a mass of ______g. Workup The following day, carefully neutralize the mixture with a measured amount of baking soda (NaHCO3). This reaction required ____g of baking soda for neutralization. Calculation: Sodium bicarbonate has a molecular formula of NaHCO3. Therefore one mole of NaHCO3 has a mass of ____g and 0.1 mole has a mass of ____g. Since ____ g of sodium bicarbonate reacted, this is ____moles of sodium bicarbonate. Therefore it reacted with ____moles of my carboxylic acid. Based on this we estimate that the reaction is ____% complete. All of the substances in the mixture are water soluble, except the fragrant ester you have produced. Bottle and artistically label the ester you have created. If time permits, combine small amounts of your perfume with those made by others to create your own perfume.

Results: 1. Based on our workup, our reaction created ___ g of ester after ____ hours for a ____ % yield. I would describe the odor of our ester produced as __________ I would describe the odor of our perfume as _______..

Questions

1. Show a balanced chemical equation for the reaction of acetic acid with baking soda.

3. Based on chemical equilibrium, indicate three ways the yield of this reaction could be improved.


Name: _____________________________________

Date: ______

Period: _____

Science and Technology Posters 100 Points Introduction: Choose a poster on a topic of your choice. Topic: Each group of two will present a poster on any approved topic that is titled: The Chemistry of ____________________ Choose something that you are personally interested in. Possible topics include The Chemistry of : 1. A rose

19. Scopolamine

2. Explosives

20. Mouthwash

3. DNA

21. flavonoids

4. skin cream

22. Cellular phones

5. chocolate

23. Reverse osmosis

6. dirt

24. artificial blood

7. car tires

25. hydrofluoric acid

8. the space shuttle

26. chemical warfare

rocket engine

agents

9. A battery

27. organ transplants

10. Hybrid vehicles

28. the bliss molecule

11. nuclear power

29. pain

12. Nuclear warheads

30. anabolic steroids

13. The Connecticut

31. mucous

river

32. energy drinks

14. The ozone layer

33. really smelly gases

15. Liquid crystals

34. combinatorial

16. A baseball

chemistry

17. carbon

35. dynamite

18. Coca-cola

1


Scoring Rubric 1. These posters are purely informational, not research-based. The goal is to instruct the reader in a logical, succinct, and interesting way. No experiments are necessary. 2. These posters should reflect the fact that we are near to completion of a full year high school level chemistry course. Try to get as deep as you can into your subject. 3. There should be several chemical structures included in your poster (2 minimum). 4. There should be a properly cited reference section for your poster. Include trusted scientific sources wherever possible. Include enough details in your citation that anyone could easily retrieve that source. 5. Include numerous images in your poster (2 minimum). Cite the source below the image if it is not original. All posters must be typed. Your instructor will provide details.



Name: ____________________________________ Period: _____

equilibrium worksheet 1

Writing Equilibrium Concentration Expressions Directions: Write the equilibrium constant expression for each of the equations illustrated below. These all follow the format:

for aA + bB  cC +dD

Keq 

[C]c [D]d [A]a [B]b

Example: write the equilibrium constant expression for the gas-phase synthesis of ethane (C2H6) from the elements. Solution: First, we write the balanced chemical equation: 2C(g) + 3H2 ↔ C2H6 (g) Then we use the format above to write the equilibrium constant expression:

Keq 

[C2H6 ]

[C]2 [H2 ]3

1. At 1405 K, hydrogen sulfide, also called rotten egg gas because of its bad odor, decomposes to form hydrogen and a diatomic sulfur molecule, S2. 2H2S(g) ↔ 2H2(g) + S2(g) Write the equilibrium constant expression for this reversible reaction.

2. Methanol, a formula-1 race car fuel, can be made from carbon monoxide and hydrogen gas: CO(g) + 2H2 (g) ↔ CH3OH(g) Write the equilibrium constant for this reversible reaction.

3. Write the balanced reaction for the combustion of hydrogen at 200 OC, and show that this is a reversible reaction.


Write the equilibrium constant for this reversible reaction.

4. Write a balanced reaction for the combustion of methane at room temperature. Be sure to include the physical states of the reactants and products.

Write the equilibrium constant for this reversible reaction.


Name: _______________________

Date: ______Period: _____ eauilibrium worksheet 2

Calculating Equilibrium Concentrations

Directions: Write the equilibrium constant expression for each of the equations illustrated below and solve for the missing value. These all may be solved using the equilibrium constant expression: for aA + bB ↔ cC +dD

Keq 

[C]c [D]d [A]a [B]b

And then plugging in the given data and solving for the unknown.

Example: For the reaction of carbon monoxide with oxygen to form carbon dioxide, determine the equilibrium concentration of carbon dioxide when the concentration of carbon monoxide is 0.8 moles/liter, the concentration of oxygen is 2.1 moles/liter, and the equilibrium constant is 225. Solution: We begin by writing a balanced chemical, equation for the reaction: 2CO + O2 ↔ 2CO2 We then write the equilibrium constant expression and plug in the numbers given:

Keq 

[CO 2 ]2

[CO]2 [O2 ]

; 225 

[CO 2 ]2

[0.8]2 [2.1]

Finally, we solve for the concentration of carbon dioxide:

[CO 2]  225(0.8)2 (2.1)  17.4

The concentration of carbon dioxide is 17.4 moles/liter

1. Lead sulfide may be prepared under high pressure by the reaction of lead with elemental sulfur: Pb(g) +S(g) ↔ (PbS(g)

What is the value of the equilibrium constant (Keq) if [Pb] = 0.30 mol/L and [S] = 0.184 mol/L, and [PbS] is 2.00 mol/L?

How far has this reaction progressed? A. Unfortunately, it is still mostly reactants B. This reaction is mostly products


2. Methanol can be prepared from carbon monoxide and hydrogen: CO(g) + 2H2 (g) ↔ CH3OH(g) Calculate these equilibrium constants: a. Keq when all substances have a concentration of 1 mol/L

b. Keq when all substances have a concentration of 2 mol/L

C. Keq when all substances have a concentration of 3 mol/L

d. For each reaction indicate if the reaction is mostly products, or mostly starting material. 3. For the combustion of methanol, determine the concentration of methanol given the following data: Keq = 0.32 [O2] = 2 mol/liter [CO2] = 4 mol/liter [H2O] = 5 mol/liter


Name: ____________________________ Period: _____

equilibrium worksheet 3

Le Chatelier’s Principle Henri Le Chatelier came up with a cryptic quote for explaining what causes chemical equilibrium, and what to do about it:

"Placing a stress on an equilibrium causes the equilibrium to shift so as to relieve the stress" What he was referring to were some common things one can do to modify a chemical reaction and the net result: Add reactant: reaction moves forward () Add product: Reaction moves backward (reverse;  Add temperature: Moves forward if endothermic (positive DH) Add pressure: moves toward the fewer number of moles. Remember, liquids and solids are considered to be outside of the reaction mixture – don’t count them when adding up moles.

Example: For the aqueous reaction of table salt with magnesium sulfide, the standard enthalpy of formation is +22.6 kJ/mol. Predict the equilibrium shift if the temperature is increased, if the pressure is increased, or if sodium sulfide is added to the reaction mixture. Solution: We begin by writing a balanced chemical equation:

2NaCl (aq) + MgS (aq) ↔ Na2S (aq) + MgCl2 (aq) DHo = +22.6 kJ/mol Note that in this case 3 moles of reactants form 2 moles of products, and that the standard enthalpy of formation indicates this reaction is endothermic. Using this information and the tips at the top of this worksheet, we can conclude Increasing temperature will shift the equilibrium forward () since this reaction needs heat Increasing pressure will shift the equilibrium forward ( ) since the product has fewer

moles Adding sodium sulfide is like adding water to a fire, and shift the equilibrium backwards ( )

1. For the following reaction 5 CO(g) + I2O5(s)  I2(g) + 5 CO2(g)

DHo = -1175 kJ/mol

for each change listed, predict the equilibrium shift and the effect on the indicated quantity.


Direction of Shift

Change (a) (b) (c) (d) (e)

( ; ; or no change)

decrease in volume raise temperature addition of I2O5(s) addition of CO2(g) removal of I2(g)

Effect on Quantity

Effect (increase, decrease, or no change)

amount of CO (g) amount of CO(g) amount of CO(g) amount of I2O5(s) amount of CO2(g)

2. Consider the following equilibrium system in a closed container: Ni(s) + 4 CO(g)  Ni(CO)4(g)

DHo = - 161 kJ

In which direction will the equilibrium shift in response to each change, and what will be the effect on the indicated quantity? Direction Effect on Effect (increase, decrease, Change of Shift Quantity ( ; ; or no change)

(a) (b) (c) (d) (e) (f) (g)

add Ni(s) raise temperature add CO(g) remove Ni(CO)4(g) decrease in volume lower temperature remove CO(g)

or no change)

Ni(CO)4(g) Keq amount of Ni(s) CO(g) Ni(CO)4(g) CO(g) Keq

3. For the conversion of oxygen (O2) to ozone (O3), predict the equilibrium shifts from the following changes:

Change (a) (b) (c) (d) (e) (f) (g)

add Ni(s) raise temperature add CO(g) remove Ni(CO)4(g) Apply a vacuum lower temperature remove CO(g)

Direction of Shift

( ; ; or no change)


Name__________________________ Period________

equilibrium worksheet 4

Equilibrium Review Worksheet 1.

What is the best way to drive a reversible reaction to completion?

If you were watching a chemical reaction, list three observations that would indicate that the reaction is not subject to equilibrium and can only move forward. 2. 3. 4. Write the gas equilibrium constant (Kc) for each of the following chemical reactions. 5) CS2(g) + H2 (g)  CH4 (g) + H2 (g)

8)

6)

Ni (s)

+

7)

HgO(s) 

CO(g)

Ni(CO)4 (g)

Hg

(l)

+

O2(g)

In your own words, paraphrase Le Chatelier's Principle.

9) Balance the following reaction: ___N2 (g) + ___H2 (g)  ___NH3 (g) DH= -386 KJ/mole 10. Known as the Born-Haber Process, this is an example of a __________ reaction. Predict the direction the equilibrium will shift if: 11) N2 is added? 12) H2 is removed? 13) NH3 is added? 14) NH3 is removed? 15) the volume of the container is increased? 16) the pressure is increased by adding Argon gas? 17) the reaction is cooled? 18) equal number of moles of H2 and NH3 are added? The equilibrium constant for the following reaction is 5.0 at 400 C. CO (g) + H2O(g)  CO2 (g) + H2 (g) Determine the direction of the reaction if the following amount (in moles) of each compound is placed in a 1.0 L flask. CO (g) H2O (g) CO2 (g) H2 (g) 19. 0.50 0.40 0.80 0.90 20. 0.01 0.02 0.03 0.04 21. 1.22 1.22 2.78 2.78


22. At a particular temperature a 2.0 L flask contains 2.0 mol H2S, 0.40 mol H2, and 0.80 mol S2. Calculate Keq at this temperature for the reaction: H2 (g) + S2 (g)  H2S (g)

23) Balance the following conversion of methane into the monomer ethylene, used to make the polymer polyethylene: ___CH4 (g)  ___H2C2 (g) + ___H2(g) The initial concentration of CH4 is 0.0300 M and the equilibrium concentration of H2C2 is 0.01375 M: 24) calculate the equilibrium concentrations of CH4 and H2; 25) Determine the numerical value of Keq. 26) At a particular temperature, 8.0 mol NO2 is placed into a 1.0 L container and the NO2 dissociates by the reaction (which needs balancing): ___NO2(g)  + ___O2(g) ____NO (g) 27. At equilibrium, the concentration of NO is 2.0 M. Calculate Keq for this reaction.

28. At a certain temperature, 4.0 mol NH3 is introduced into a 2.0 L container, and the NH3 partially dissociates by the reaction (please balance it): ___NH3 (g)  ___N2 (g) + ___H2(g) At equilibrium, 2.0 mol NH3 remains. What is the value of Keq for this reaction?


How to Ace the Equilibrium Exam

Howtoaceitunit18

In our previous unit we investigated the rate of chemical reactions- how fast do they go? In this equilibrium unit we point out that even if a reaction is going fast, it might not be going very far overall if the reverse reaction is also occurring. This is the big idea behind chemical equilibrium, the condition where the rate of a forward reaction is equal to the rate of the reverse reaction. We can write the equilibrium constant expression and from this we can determine if we are getting anywhere or whether the reaction is standing still. Generally speaking, if we mix chemicals together we would like them to go forward, and this will happen if the value of the equilibrium constant (Keq) is greater than one. Note that Keq is only true at a specific temperature, and it says nothing about the rate of a reaction- only the direction. A nice benefit of the equilibrium constant expression is that it can also tell you what the concentration of a reactant is, given enough information. Since chemical equilibrium can prevent a reaction from going to completion, it would be nice to know how we can destroy it, or at least get things moving forward. Simple. To destroy chemical equilibrium, one must remove the product as it is formed- this makes the reverse reaction impossible. This is accomplished by having the product precipitate, for example by precipitating as a solid. As a general rule, this is why we omit liquids and solids from our equilibrium constant expression. In practice, it is easy to observe a precipitate. Examples include the gaseous precipitate we observe when we mix baking soda and vinegar, or the solids that crash out of solution during many double replacement reactions. These reactions can only move forward, since collisions between products to form reactants are no longer possible. There are several other ways one can adjust chemical equilibrium. Known as Le Chatelier’s Principle, the direction of a reaction after a stress is applied may be summarized: Le Chatelier’s Principle Adding reactant:  Adding product:  Heating:  if endothermic Pressurizing:  if there are fewer moles of product Each of these may be reversed; for example cooling an endothermic reaction will favor the reverse reaction. Imagine going on a trip. It’s nice to know in what direction you are going, and how long it will take. These last two units have shown us just that for a chemical reaction. In the next unit we can apply these navigational skills to the study of acids and bases.


To ace this exam you should know: 1. What is chemical equilibrium? 2. What is a synonym for equilibrium? 3. What is the best way to destroy chemical equilibrium? 4. What does it mean if the rate of a forward chemical reaction a. Is faster than the reverse reaction b. Is the same as the reverse reaction? c. Is slower than the reverse reaction?

5. Please balance the reaction below and write the chemical equilibrium expression: ___Fe3O4(s) + ___H2(g)  ___Fe(s) + ___H2O (g) Keq =

6. Please determine the direction of the reaction given the following data: C2H4(g) + a. 1M b. 1.0520M

H2 (g)  2M 3.0400M

C2H6(g) DH = +32kJ/mol 3M Direction of reaction:______ 3.1909M Direction of reaction:______

7. For the reaction below the rate of the forward reaction is equal to the rate of the reverse reaction. Therefore, Keq = ____. Determine the concentration of ethane (C2H6) in the mixture: C2H4(g) + H2 (g)  C2H6(g) DH = +32kJ/mol 2M 4M ?

8. Please determine the direction of the following hypothetical reversible reaction: 4A(g) + 7B(g) + 13C +D (l)  9E (g) + 3F (g)+ 2G (g) Concentrations (M): 1.06 2.12 1.42 3 2.10 1.44 3.26


9 (L1 only). Please determine the concentration of G in the following reaction if it is at equilibrium.

Concentrations (M):

4A(g) + 7B(g) + 13C +D (l) ďƒ 9E (g) + 3F (g)+ 2G (g) 1.06 2.12 1.42 3 2.10 1.44 ?

9. List five ways to help the following reaction move forward: C2H4(g) + H2 (g) ďƒ C2H6(g) DH = +32kJ/mol

1. 2. 3. 4. 5. 10. In our next unit we will be studying acids and bases. Write a balanced chemical equation for the reaction of hydrochloric acid with sodium hydroxide to form table salt and water:

a. Can you move this reaction forward by pressurizing it? b. If the standard enthalpy of formation for this reaction is 0.004KJ/Mol, can you move it forward by heating it? c. What is the only product that might precipitate from this reaction at room temperature? d. Why would it be a big deal if that product did precipitate? e. Would it be a good idea to add water to this reaction? f. This is a segue into the next unit: If this reaction used 10 grams of sodium hydroxide and ten grams hydrochloric acid, would it result in a neutral, acidic, or basic solution (assuming a complete reaction)?






M


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14

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14



105 103 3

 

 


6




Molarity of unknown =

vinegar Molarity =

molarity of known x liters of known liters of unknown

(NaOH Molarity)(NaOH volume) vinegar volume


60 grams acetic acid 180 g acetic acid 3 moles acetic acid 1 liter solution x x = = 18% Liter solution 1 mole acetic acid 1000 grams solution 1000 g solution





common name stomach acid

name hydrochloric acid

HF

hydrobromic acid

HBr

milk of magnesia

HI

nitric acid

HNO3

sulfuric acid

H2SO4

phosphoric acid lye

HCl

hydrofluoric acid hydrioidic acid

vinegar

formula

acetic acid sodium hydroxide

H3PO4 CH3CO2H NaOH

magnesium hydroxide

Mg(OH)2

calcium hydroxide

Ca(OH)2

ammonia triethylamine

NH3 (CH3CH2)3N



[H+][OH-] = 10-14 Enter 10^-14/1.66E-4

pH 3.78 [H+] = 10-pH

Enter 10^-3.78

[H+]

pOH

[OH-]

Acid or base? Example

1.66 x 10-4

10.22

6.0 x 10-11

Acid Orange juice

pH + pOH = 14 Enter 14-3.78

Use the change sign (-) button, not the subtract button

pH>7 = base pH<7 = acid



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D

D

  

 

D

 D

D 

  

  

D

D

D D D D

D

D D

D


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