SPCHEM 1ST QUARTER PDF

Summary

This document provides an overview of lesson materials on matter and its properties. Topics include physical and chemical properties, different states of matter, classification of matter, and various methods for separating mixtures.

Full Transcript

Lesson 1: Matters and its Properties 2. Distillation – purifies liquid mixture by using boiling
points of its substance
--------------------------PROPERTIES OF MATTER------------------------ Residue – higher boiling point
1. Physical Properties – determined/ measured Distillate
without changing the chemical composition of
matter
- Volume, mass, density, boiling point, temp

2. Chemical Properties – only be measured by changing
the chemical composition of the matter
- Combustible, radioactivity, reactivity
(𝐻2 𝑂 + 𝑂2) = rust 3. Filtration – separates solid from
liquid using a porous material
Intensive (intrinsic) – do not depend with the amount of
matter but with the type
- Temp, density, boiling point

Extensive (extrinsic) – depend with the amount of matter 4. Evaporation – separates by allowing the liquid to
evaporate and solid particle remain
-----------------------PROPERTIES AND CHANGES---------------------- Ex. Salt farms
1. Physical change – only physical properties (no chemical
composition)
- Melting of ice, moist from the window

2. Chemical change – chemical composition is changed
(process)
- Changed when matter produced has different
set of properties 5. Chromatography – separates component of a
mixture by passing the mixture through stationary
States of Matter phase
1. Solid Gas chromatography – separate gas
2. Liquid
3. Gas

------------CLASSIFICATION OF MATTER (composition)------------

6. Use of Magnet – separate mixtures of magnetic and
non-magnetic matter

7. Electrolysis – separate
------------METHODS AND TECHNIQUES IN SEPARATING-----------
compounds like water
1. Decantation – separates
using electricity
undissolved solid from
liquid
Ex. Cooking rice
 Lesson 2: Measurements ------COMMON MEASUREMENT AND UNIT CONVERSIONS------
Density – mass per unit volume
Measurement – quantifies the characteristics of matter 𝑚
𝐷=
- Compare to standard quantity (units) 𝑣

1. Given:
SI Base Unit
Base Quantity Name of Unit Symbol 𝑉 = 15 𝑐𝑚3
𝑚 = 45 𝑔
Length Meter m
Mass kilogram kg Find: 𝐷 = ?
Time Second s Solution:
𝑚
Electrical current Ampere A 𝐷=
𝑣
Temperature Kelvin K 45𝑔
Amount of substance Mole mol 𝐷=
15 𝑐𝑚3
Luminous intensity candela cd 𝐷 = 3𝑔 /𝑐𝑚3

------------------------ACCURACY VS PRECISION------------------------ 2. Given:
𝑉 = 8 𝑐𝑚3
𝑚 = 40 𝑔
Find: 𝐷 = ?
Solution:
𝑚
𝐷=
𝑣
40𝑔
𝐷=
8 𝑐𝑚3
-----------UNCERTAINTY AND ERROR IN MEASUREMENT---------- 𝐷 = 5𝑔 /𝑐𝑚3
Error – difference between “measured value” and “true
value” Volume
- 1000ml = 1L - 14.79mL = 1tbsp
1. Systematic errors – naturally occur, assume correct - 1mL = 1𝑐𝑚3 - 4.93mL = 1 tsp
and accurate - 29.57mL = 1oz
2. Random errors – “human error”
Temperature
Uncertainty – quantification of the doubt about the C to F 9
𝐹 = 𝐶 + 32
measurement result 5
K to F 9
𝐹 = (𝐾 − 273.15) + 32
---------------------LIMITATION IN MEASUREMENT-------------------- 5
K to C 𝐶 = 𝐾 − 273.15
Significant figures – reporting proper number of digits in
F to C 5
measurement or calculation 𝐶 = (𝐹 − 32)
9
C to K 𝐾 = 𝐶 + 273.15
F to K 5
𝐾 = (𝐹 − 32) + 273.15
9
-----------------------------------RULES--------------------------------------- Lesson 3: Compositions of Matter
1. Any nonzero – significant
Ex. 12345(5), 98(2), 854879(6) -----------------ATOMIC MODEL & THEORY TIMELINE----------------
1. Democritus – matter is divided into smaller pieces
2. Any zeroes between nonzero digits – significant forever
Ex. 10005(5), 2005406(7), 2000001(7) - “atom”

3. Zeros at the end w/o decimal – not significant 2. John Dalton – first atomic theory
Ex. 34000(2), 10000(1), 34.500(5) - “atom” – tiny, solid balls

4. Zeros at the beginning of decimal number – not 3. JJ. Thompson – atom was made smaller things
significant - “Raisin bun model”
Ex. 0.03(1), 0.0004(1), 0.0090(2)
 4. Ernest Rutherford – protons & nucleus ATOM – basic unit of an element that can enter to chemical
- Atoms have (+) particles in the center and combination
mostly empty space - Internal structure
- Subatomic particles
5. Niels Bohr – electrons move around the nucleus in o Proton (𝑝+ )
shells o Electron (𝑒 − )
Erwin Schrodinger – Quantum Mechanical o Neutron (𝑛0 )
Model (orbitals)

6. James Chadwick – with Rutherford 𝑝+ = 𝑒 −
- Particles w/ no charge (neutrons)
--------------------------REPRESENTING AN ATOM----------------------
7. Modern – electrons moving around nucleus in a Nuclide – atomic number and mass number
cloud

------------------DALTON’S ATOMIC THEORY (1808)-------------------
Atoms – elements composed of extremely small particle
- Identical (size, mass, and chemical properties)
- Atom of 1 element differ from another
Atomic number (z) – number of protons (identity) in the
nucleus of each atom of an element
Compounds – composed of atoms more than 1 element
3𝑝+ = 𝐿𝑖
- Relative number of atoms of each element in a given
compound is the same
Neutral atom – number of protons = number of electrons
- Ground state atoms
Chemical reaction – rearrangement of atoms
- Not created/ destroyed
Mass Number (A) – mass of an atom
- amu (atomic mass unit)
-----------------------------------LAWS---------------------------------------
- number of protons + number of neutrons
1. Law of Definite Proportion
Joseph Proust (1754 - 1826) – same compound
IONS – an atom/ group of an atom (with + and – net charge)
always the same proportion by mass
- number of protons are the same after process
Ex. Water – 11% H, 89% O → 18g of water
= 1.98g H, 16.02g O
𝑝+ ≠ 𝑒 ↑↓
2. Law of Multiple Proportion
a. Cation – positive
- 2 elements combine to form more than 1 compound
- Loses electrons
- Masses of 1 element that combine with a fixed mass
of other element are in ratios of small whole
b. Anion – negative
numbers
- Gain electrons

Ex.
27 3+
13𝐴𝑙 𝑝+ = 13
𝑒 − = 10 (13 − 3)
(cation) 𝑛0 = 14

78
34𝑆𝑒
2− 𝑝+ = 34
𝑒 − = 36 (34 + 2)
(anion) 𝑛0 = 44
3. Law of Conservation of Mass
- Total mass of substance present at the end of chem
Monoatomic Ion – only 1 atom
process is the same as the mass of substances before
𝑁𝑎+ , 𝐶𝑙 − , 𝐶𝑎2+ , 𝑂2− , 𝐴𝑙 3+ , 𝑁 3−
the process
Ex. 1.00g H + 8.00g O = 9.00𝐻2 𝑂
Polyatomic Ion – more than 1 atom
4.03 MgO – 2.43g Mg = 1.6g O
𝑂𝐻 − , 𝐶𝑁 − , 𝑁𝐺4 +
 ISOTOPES – defined by the number of protons Diatomic Molecule – 2 atoms
- Different mases 𝐻2 , 𝑁2 , 𝑂2 , 𝐵𝑟2 , 𝐹2 , 𝐼2 , 𝐶𝑙2 , 𝐶𝑂, 𝐻𝐶𝐼
- Different number of neutrons Polyatomic Molecule – more than 2 atoms
𝑂3 , 𝐻2 𝑂, 𝑁𝐻3 , 𝐶𝐻4

Lesson 4: Electronic Structure of Atom and Electron
Configuration

*Unstable = radioactive decay 1. Bohr’s Atomic model
2. The Dual Nature of Electron (Louis de Broglie)
Ex. 3. The concept of quantum
H-1 𝑝+ = 1 𝑒− = 1 𝑛0 = 0 4. Heisenberg’s Uncertainty Theory
H-2 𝑝+ = 1 𝑒− = 1 𝑛0 = 1
H-3 𝑝+ = 1 𝑒− = 1 𝑛0 = 2 Quantum number
1. Principal number – floor number
Fractional abundance – fraction of total number of atoms 2. Azimuthal/ Angular – rooms
that is composed of an isotope 3. Magnetic (“orbital”) – number of beds (2 only)
1 1
4. Spin – only 2 (+ 2 , − 2)
Ex.
Isotopic Mass Fractional Abundance
49.9461 0.0435 2.17
51.9405 0.8379 43.52
52.9407 0.0950 5.029
53.9389 0.0236 1.27
Cr = 51.989 amu

S p d f g h
--------------COMMON ISOTOPES AND THEIR USES------------------
2 6 10 14 18
Radioactive Isotopes Applications in Medicine
Quantum number
1. Cobalt-60 Radioactive therapy for cancer
n l ml # of Orbital # of
2. Iodine-131 Brain tumors, cardiac liver, and orbital name electrons
thyroid 1 0 0 1 1s 2
3. Carbon-14 Diabetes, gout, and anemia
4. Carbon-11 Glucose monitors during PET scan 2 0 0 1 2s 2
5. Sodium-24 Blood circulation 1 -1, 0, +1 3 2p 6
6. Thallium-201 Heart tissue and tumors
7. Technetium-99m Brain tumors, heart cells, radiotracer 3 0 0 1 3s 2
1 -1, 0, +1 3 3p 6
Radioactive Isotopes Industrial Applications 2 -2, -1, 0, +1, +2 5 3d 10
1. Americium-241 Rolling steel and paper, oil wells
2. Sodium-24 Oil well, leaks in pipe lines 4 0 0 1 4s 2
3. Iridium-192 Boilers and aircraft parts 1 -1, 0, +1 3 4p 6
4. Uranium-235 Nuclear power plant, fuel, fluorescent 2 -2, -1, 0, +1, +2 5 4d 10
glassware and wall tiles 3 -3, -2, -1, 0, +1, +2, +3 7 4f 14
5. Californium-252 Moisture content of soil, road and
bldgs. 5 0 0 1 5s 2
1 -1, 0, +1 3 5p 6
MOLECULES – aggregate of 2 or more atoms in a definite 2 -2, -1, 0, +1, +2 5 5d 10
arrangement held together by chemical bonds (molecule vs 3 -3, -2, -1, 0, +1, +2, +3 7 5f 14
compound) 4 -4, -3, -2, -1, 0, +1, +2, +3, +4 9 5g 18
- Neutral
- May contain atoms of the same element/ atoms
of 2 or more elements joined in a fixed ratio
-----------------RULES IN ELECTRON CONFIGURATION--------------- c. Orbital Diagram
1. Aufbau Principle 1. Li = 3 – paramagnetic
2. Hund’s Rule
3. Pauli Exclusion Principle
*Exemption to Aufbau Principle: EC ending in d4, d9, f6, f13 2. Ag = 47 – paramagnetic

3. Mn = 25 – paramagnetic

4. Al+3 = 10 – diamagnetic

Electron Configuration
a. Longhand
1. Li = 3
1𝑠 2 2𝑠1

2. Ag = 47
1𝑠 2 2𝑠1 2𝑝6 3𝑠 2 3𝑝6 4𝑠 2 3𝑑10 4𝑝6 5𝑠1 4𝑑10

3. Mn = 25
1𝑠 2 2𝑠1 2𝑝6 3𝑠 2 3𝑝6 4𝑠 2 3𝑑 5

4. Al+2 = 10
1𝑠 2 2𝑠1 2𝑝6

Valence electron – highest principal the electron
occupied
1. 1
2. 1
3. 2
4. 8

b. Shorthand
1. 𝐿𝑖 = [𝐻𝑒] 2𝑠1
2. 𝐴𝑔 = [𝐾𝑟] 5𝑠1 4𝑑10
3. 𝑀𝑛 = [𝐴𝑟] 4𝑠 2 3𝑑 5
4. 𝐴𝑙 +3 = [𝑁𝑒] 3𝑠 2 3𝑝1