Chemistry Laboratory Techniques & Equipment PDF

Summary

This document provides an overview of common laboratory apparatuses and equipment used in chemistry. It covers various types of glassware, metal equipment, and porcelain equipment, along with measuring and heating devices. The document also introduces the different branches of chemistry and highlights the contributions of scientists.

Full Transcript

**1. Common Laboratory Apparatuses and Equipment**

This presentation focuses on common laboratory apparatuses and equipment used in
chemistry. It starts by defining laboratory apparatuses as a set of materials or equipment
designed for a specific purpose. Then, it categorizes them into two groups:

* **Glassware and Porcelains:** This section discusses the different types of glassware used in
laboratories, including soft glass (soda lime glass) and hard glass (pyrex glass). Soft glass is
more affordable but breaks easily, while hard glass is more resistant to heat and chemical
reactions.
* **Metal Equipment and Accessories:** This section covers various metal equipment used for
supporting and holding glassware, such as iron stands, clamps, rings, and tongs. It also
includes tools for heating, such as Bunsen burners, alcohol lamps, and wire gauze.

The presentation then delves into specific laboratory glassware, focusing on their functions and
how to use them correctly. The glassware discussed includes:

* **Volumetric Flask:** Used for precise measurement of liquid volumes and preparing solutions
with specific concentrations.
* **Graduated Cylinder:** Used for measuring the volume of liquids with a reasonable degree of
precision.
* **Capillary Pipette:** Used for precise and accurate measurement of small liquid volumes.
* **Burette:** Used in volumetric titration processes for precise and controlled delivery of liquids.
* **Graduated Pipette:** Used for accurate measurement of fixed volumes of liquids, often
transferred directly from reagent bottles.
* **Bulb Pipette:** Used for drawing and delivering liquids into a pipe.
* **Beaker:** Used for holding, mixing, and heating liquids.
* **Erlenmeyer Flask:** Used for holding and mixing chemicals, particularly useful for swirling
and mixing without spilling.
* **Vials:** Used for storing small amounts of solid or liquid substances.
* **Test Tubes:** Used for mixing, dissolving, and performing simple chemical tests.
* **Florence Flask:** Used as a reaction vessel and sometimes for gas apparatus.
* **Distilling Flask:** Used for separating mixtures of liquids with different boiling points.
* **Watch Glass:** Used to cover beakers and prevent contamination of solutions.
* **Medicine Dropper:** Used for precise measurement of liquids by drops.
* **Petri Dish:** Used for culturing microorganisms.
* **Funnel:** Used for supporting filter paper during filtration.
* **Separatory Funnel:** Used for separating immiscible liquids.
* **Stirring Rod:** Used for stirring solutions and guiding liquid transfer.
* **Condenser:** Used for cooling vapors back to liquid state during distillation.

**Porcelain Equipment**

The presentation also includes a section on porcelain equipment, highlighting:

* **Evaporating Dish:** Used for evaporating water from solutions to obtain solid materials.
* **Crucible and Lid:** Used for heating or melting small amounts of substances that require
extreme heat.
* **Mortar and Pestle:** Used for grinding solid substances into powder form.
* **Ceramic Spatula:** Used for scooping out small amounts of solids from containers.

**Measuring Devices and Apparatuses**

This section focuses on devices used for measuring mass and temperature:

* **Thermometer:** Used for measuring temperature in Celsius or Fahrenheit.
* **Electronic Top-Loading Balance:** Used for measuring the mass of materials with high
precision.
* **Platform Balance:** Used for measuring mass with a sensitivity of 0.1 g.
* **Triple Beam Balance:** Used for measuring mass with a capacity of 620 g and a sensitivity
of 0.1 g.

**Heating Equipment**

The presentation concludes with a section on heating equipment:
* **Alcohol Lamp:** Used for providing heat in the laboratory.
* **Bunsen Burner:** Used for providing heat using gas or fuel.
* **Tripod:** Used for supporting laboratory apparatus.
* **Clay Triangle:** Used for supporting crucibles and other apparatus that require direct
heating.
* **Wire Gauze:** Used to support beakers and flasks and protect them from direct flame.
* **Aspirator:** Used for cleaning balance pans and sucking liquids into pipettes.
* **Test Tube Brush:** Used for cleaning test tubes and other narrow-mouthed glassware.
* **Test Tube Holder:** Used for holding test tubes.

**2. Branches of Chemistry, Foreign and Filipino Scientists/Chemists**

This presentation explores the different branches of chemistry and highlights the contributions of
both foreign and Filipino scientists. It starts by defining chemistry as the branch of science that
deals with the properties, composition, and structure of matter. Then, it delves into the different
branches of chemistry:

* **Physical Chemistry:** Deals with theories and experiments that describe the behavior of
chemicals.
* **Organic Chemistry:** Deals with the study of compounds that contain carbon.
* **Inorganic Chemistry:** Deals with the chemistry of elements other than carbon and its
compounds.
* **Biochemistry:** Deals with the chemical and physicochemical processes and substances
that occur within living organisms.
* **Analytical Chemistry:** Deals with the identification and quantification of substances in
samples.

The presentation then showcases several notable scientists, emphasizing their contributions to
the field:

* **Foreign Scientists:**
* **Dmitri Ivanovich Mendeleev:** Formulated the Periodic Law and created the periodic table
of elements.
 * **Marie Skłodowska Curie:** Conducted pioneering research on radioactivity and became
the first woman to win a Nobel Prize.
* **Antoine-Laurent Lavoisier:** Developed an experimentally based theory of the chemical
reactivity of oxygen and coauthored the modern system for naming chemical substances.
* **Niels Bohr:** Applied the quantum concept to atomic and molecular structure.
* **Svante August Arrhenius:** Developed the electrolytic theory of dissociation.
* **Alfred Nobel:** Invented dynamite and established the Nobel Prizes.
* **Ernest Rutherford:** Discovered the radioactive half-life and differentiated alpha and beta
radiation.
* **Henri Becquerel:** Discovered spontaneous radioactivity in uranium salts.
* **Linus Pauling:** Promoted nuclear disarmament, orthomolecular medicine, and the use of
dietary supplements and ascorbic acid.
* **Gen. Florencio A. Medina:** Considered the Father of Atomic Energy in the Philippines for
his contributions to the peaceful use of nuclear technology.

* **Filipino Scientists:**
* **Pedro B. Escuro:** Known as the Father of the Philippine Rice Breeding Program for his
significant contributions to rice breeding and the development of nine seed board rice varieties.
* **Dr. William Padolina:** Known for his work using indigenous sources of energy and
natural chemistry products.
* **Julian A. Banzon:** Known for his work using coconut as an alternative source of
chemicals and fuels.
* **Benjamin Almeda Sr.:** Known as the Father of Filipino Inventors for his inventions in the
food processing industry, including meat grinders, rice grinders, and coconut graters.
* **Julio dela Gente Jr.:** Inventor of a multipurpose thermal cracking apparatus.
* **Ramon Barba:** Pioneered crop flowering techniques using potassium nitrate spray,
making the Philippines a leading exporter of mango products.
* **Baldomero M. Olivera:** Pioneered the discovery of biochemical characterization of E.
coli DNA ligase, a key enzyme of DNA replication and repair.
* **Fe Del Mundo:** Invented a bamboo incubator designed for infants in areas without
electricity.
* **Rolando Dela Cruz:** Invented an anti-cancer skin cream made from cashew nuts and
other local herbs.

**3. Mathematical Concepts in Chemistry: Accuracy and Precision**
This module focuses on the mathematical concepts of accuracy and precision in chemistry,
emphasizing their importance in experimental measurements. It covers the following key points:

* **Accuracy:** How close a measured value is to the true or accepted value. It's expressed as
**percent error**.
* **Precision:** How close repeated measurements of the same quantity are to each other. It's
expressed as **percent deviation**.

**Formulas:**

* **Percent Error:**
` % Error = (Average Absolute Error / True Value) x 100 `

% Error = (Average Absolute Error / True Value) x 100
` % Deviation = (Average Absolute Deviation / Average Measurement) x 100 `

* **Average Absolute Error:** The average of the differences between each measurement and
the true value.
* **True Value:** The accepted or standard value for the quantity being measured.

* **Percent Deviation:**
% Deviation = (Average Absolute Deviation / Average Measurement) x 100

* **Average Absolute Deviation:** The average of the differences between each measurement
and the average of all measurements.
* **Average Measurement:** The average of all the measurements taken.

* *4*Significant Figures:** The digits in a measurement that are considered reliable and
contribute to its precision. The presentation explains the rules for determining significant figures,
including:
 * Non-zero digits are always significant.
* Zeros between non-zero digits are significant.
* Zeros at the end of a number that include a decimal point are significant.
* Zeros at the end of a number without a decimal point are ambiguous and may or may not be
significant.

The module also explains how to perform arithmetic operations involving significant figures,
including:

* **Addition and Subtraction:** The final sum or difference should have the same number of
decimal places as the measurement with the fewest decimal places.
* **Multiplication and Division:** The final product or quotient should have the same number of
significant figures as the measurement with the fewest significant figures.

The module then provides examples and practice problems to help students understand the
concepts of accuracy, precision, and significant figures.
* **Scientific Notation:** A way to express numbers as a product of a number between 1 and 10
(the coefficient) and a power of 10 (the exponent).
* **General Form:** N x 10^n
* N is a number between 1 and 10.
* n is an integer (positive or negative).

**Rules for Converting Numbers to Scientific Notation:**

* **Numbers Greater than 1:** Move the decimal point to the left until you have a number
between 1 and 10. The exponent (n) is positive and equal to the number of places you moved
the decimal point.
* **Numbers Less than 1:** Move the decimal point to the right until you have a number
between 1 and 10. The exponent (n) is negative and equal to the number of places you moved
the decimal point.

**Arithmetic Operations with Scientific Notation:**

* **Addition and Subtraction:**
 1. Make sure the exponents (n) are the same for all numbers.
2. Add or subtract the coefficients.
3. Keep the same exponent.

* **Multiplication:**
1. Multiply the coefficients.
2. Add the exponents.

* **Division:**
1. Divide the coefficients.
2. Subtract the exponents.

**5. Chemistry Laboratory Safety Precautions, Rules, and Techniques**

This module focuses on safety in the chemistry laboratory. It covers the following key points:

* **Personal Safety:** Emphasizes the importance of wearing safety goggles, lab coats, and
closed-toe shoes, as well as tying back long hair, keeping hands away from the face, and
washing hands before and after lab work. It also stresses the importance of proper handling of
chemicals, particularly acids and bases, and the need to report any accidents or injuries to the
teacher or medical staff.
* **Safe Laboratory Techniques:** Includes rules for reading and understanding procedures
before starting an experiment, performing only assigned activities with supervision, using proper
techniques for handling chemicals and equipment, and disposing of materials safely.
* **Safety in Using Laboratory Equipment:** Provides guidance on the location and use of
safety equipment such as fire extinguishers, safety showers, eye-wash stations, fume hoods,
fire blankets, and first-aid cabinets. It also emphasizes the importance of using hot plates
instead of open flames when flammable liquids are present, using dispensing apparatuses for
chemicals, and cleaning and returning equipment after use.
* **Safe Disposal of Glassware and Chemicals:** Includes instructions for disposing of broken
glassware in designated containers, neutralizing acids and bases before disposal, diluting salt
solutions before disposal, and disposing of heavy metal solutions in designated containers.

The module also includes activities and practice problems to help students understand and
apply the safety precautions, rules, and techniques discussed.
Okay, I've got it! I'll focus on explaining the 4th and 5th parts of the files, providing formulas and
detailed explanations.