Liquids : Viscosity of Water, Dynamic Viscosity & Kinematic Viscosity

MLiquids : Viscosity of Water, Dynamic Viscosity & Kinematic Viscosity

Discover what is viscosity, master viscosity of water, dynamic viscosity, kinematic viscosity, and viscosity units. Learn dynamic viscosity of water, kinematic viscosity of water, and dynamic viscosity units with expert explanations.

★★★★★

4.9/5 (127 reviews)

🎓 Trusted by 10,000+ students

What is Viscosity: Understanding Viscosity of Water

Viscosity represents one of the most important properties in liquid chemistry. This comprehensive guide explores what is viscosity, viscosity of water, dynamic viscosity, kinematic viscosity, and viscosity units. You’ll master dynamic viscosity of water, kinematic viscosity of water, and dynamic viscosity units with practical measurement methods.

Understanding viscosity is crucial for countless applications from industrial processes to biological systems. The viscosity of water serves as a fundamental reference point, while dynamic viscosity and kinematic viscosity provide different perspectives on fluid resistance to flow.

Intermolecular Forces in Liquids

🔗 Dipole-Dipole Attractions

Dipole-dipole attractions occur between polar molecules and play a crucial role in liquid behavior. These forces determine how polar molecules interact with each other and affect liquid properties.

Permanent dipoles align to minimize energy
Strength depends on dipole moment magnitude
Critical for liquid structure and stability
Influences solvent-solute interactions

⚡ London Forces

London dispersion forces exist between all molecules and significantly impact liquid properties in non-polar systems. These weak but universal forces affect molecular cohesion and liquid behavior.

Present in all molecular interactions
Strength increases with molecular size
Influences non-polar liquid properties
Affects molecular mobility in liquids

💧 Hydrogen Bonding in Liquids

Hydrogen bonding represents the strongest intermolecular force and fundamentally determines liquid properties in polar systems. Water’s hydrogen bonding network creates unique liquid characteristics and behaviors.

🌊

Liquid Structure

Tetrahedral arrangement in water

🔄

Dynamic Exchange

Continuous breaking and forming

⚖️

Molecular Balance

Maintains liquid stability

🔗 Van der Waals Forces

Understanding Van der Waals Forces

Van der Waals forces are weak intermolecular forces that include dipole-dipole interactions, London dispersion forces, and dipole-induced dipole forces. These forces play a crucial role in determining liquid properties and molecular behavior.

⚡

Dipole-Dipole

Permanent dipole interactions

🌊

London Dispersion

Temporary dipole forces

🔄

Dipole-Induced

Induced dipole interactions

📐 Van der Waals Equation

The van der Waals equation of state accounts for intermolecular forces and molecular volume:

(P + a/V²)(V – b) = RT

a = intermolecular attraction parameter
b = molecular volume parameter
Corrects ideal gas behavior
Important for liquid-gas transitions

⚡ Energy Relationships

Van der Waals forces follow specific energy dependencies with distance:

Dipole-dipole: E ∝ 1/r³ (orientation averaged)
London forces: E ∝ 1/r⁶ (always attractive)
Dipole-induced: E ∝ 1/r⁶ (polarizability dependent)
Total energy: Sum of all contributions

🎯 Applications in Liquid Properties

🌡️

Boiling Points

Stronger forces = higher boiling points

💧

Surface Tension

Intermolecular cohesion effects

🌊

Viscosity

Molecular friction resistance

🔄

Solubility

Like dissolves like principle

💧 Hydrogen Bonding

Characteristics of Hydrogen Bonds

Hydrogen bonding is a special type of dipole-dipole interaction that occurs when hydrogen is bonded to highly electronegative atoms (N, O, F). These bonds are stronger than typical van der Waals forces, with energies ranging from 10-40 kJ/mol.

🔋 Strength

• 10-40 kJ/mol energy
• Stronger than van der Waals
• Weaker than covalent bonds
• Temperature dependent

📐 Directionality

• Linear arrangement preferred
• Angle-dependent strength
• Geometric constraints
• Affects molecular packing

🔗 Cooperativity

• Multiple bonds strengthen each other
• Network formation
• Collective behavior
• Enhanced stability

🌊 Water’s Hydrogen Bond Network

Water molecules can form up to 4 hydrogen bonds per molecule, creating a tetrahedral arrangement that gives water its unique properties.

Tetrahedral geometry: 109.5° bond angles
Dynamic network: Continuous breaking/forming
Temperature effects: Network disruption with heating
Density anomaly: Ice less dense than water

📊 Types of Hydrogen Bonds

Intermolecular

Between different molecules (e.g., water-water)

Intramolecular

Within the same molecule (e.g., protein folding)

Network Structures

Extended 3D arrangements (e.g., ice, DNA)

🎯 Effects on Liquid Properties

🌡️ Boiling Point Elevation

Hydrogen bonding significantly increases boiling points:

• H₂O: 100°C (vs. -80°C predicted without H-bonds)
• NH₃: -33°C (vs. -120°C predicted)
• HF: 20°C (vs. -140°C predicted)

💧 Viscosity and Surface Tension

Enhanced intermolecular cohesion leads to:

• Higher viscosity values
• Increased surface tension
• Better wetting properties
• Enhanced capillary action

💨 Vapour Pressure

Fundamentals of Vapour Pressure

Vapour pressure is the pressure exerted by vapor molecules in equilibrium with their liquid phase. It’s a fundamental property that depends on temperature and molecular structure, directly affecting boiling points and evaporation rates.

📊 Clausius-Clapeyron Equation

The relationship between vapour pressure and temperature follows:

ln(P₂/P₁) = -ΔHᵥₐₚ/R × (1/T₂ – 1/T₁)

Where ΔHᵥₐₚ is the enthalpy of vaporization and R is the gas constant

Determination of Vapour Pressure Methods

🔬 The Static Method

Measures vapour pressure at equilibrium without gas flow. This method provides accurate measurements for liquid characterization.

Closed system measurement
Equilibrium conditions maintained
High accuracy for liquid studies
Temperature control critical

🌪️ The Dynamic Method

Involves gas flow over the liquid surface, useful for studying liquids under dynamic conditions.

Continuous gas flow system
Simulates natural conditions
Relevant for industrial applications
Flow rate affects measurements

📊 Vapour Pressure Data for Common Liquids

Liquid	20°C (kPa)	40°C (kPa)	60°C (kPa)	80°C (kPa)
Water	2.34	7.38	19.9	47.4
Ethanol	5.95	18.7	47.0	101.3
Acetone	24.6	54.7	101.3	166.9
Benzene	10.0	24.6	51.3	101.3

🔥 Boiling Point

Understanding Boiling Point

The boiling point is the temperature at which a liquid’s vapour pressure equals the external pressure. At this point, vapor bubbles form throughout the liquid, causing the characteristic boiling phenomenon.

🌡️

Normal Boiling Point

At 1 atm pressure (101.3 kPa)

📏

Standard Boiling Point

At 1 bar pressure (100 kPa)

⬇️

Reduced Pressure

Lower pressure = lower boiling point

📊 Boiling Points and Intermolecular Forces

Compound	Formula	Boiling Point (°C)	Intermolecular Forces
Water	H₂O	100.0	Hydrogen bonding
Ethanol	C₂H₅OH	78.4	Hydrogen bonding
Acetone	CH₃COCH₃	56.1	Dipole-dipole
Benzene	C₆H₆	80.1	London forces
n-Hexane	C₆H₁₄	68.7	London forces
Diethyl ether	C₂H₅OC₂H₅	34.6	Dipole-dipole, London

🎯 Factors Affecting Boiling Point

🔗 Molecular Structure

• Intermolecular forces: Stronger forces = higher boiling point
• Molecular size: Larger molecules = more London forces
• Branching: Branched molecules have lower boiling points
• Polarity: Polar molecules have higher boiling points

🌡️ External Conditions

• Pressure: Higher pressure = higher boiling point
• Altitude: Higher altitude = lower boiling point
• Impurities: Usually increase boiling point
• Surface area: Affects rate but not temperature

🧮 Surface Tension Numerical Problems

Practice problems to master surface tension calculations and applications

📏 Problem 1: Capillary Rise Method

Given:

• Water rises 2.8 cm in a capillary tube
• Tube radius = 0.5 mm
• Contact angle θ = 0°
• Density of water = 1000 kg/m³
• g = 9.8 m/s²

Find: Surface tension of water

Solution:

γ = ρghr/(2cosθ)

γ = (1000)(9.8)(0.028)(0.0005)/(2×cos0°)

γ = 0.1372/2 = 0.0686 N/m

γ = 68.6 mN/m

💧 Problem 2: Drop Formation

Given:

• 50 drops of water fall from a burette
• Total volume = 2.5 mL
• Burette tip radius = 1.2 mm
• Surface tension of water = 72.8 mN/m

Find: Theoretical volume per drop

Solution:

V = 2πrγ/ρg (Tate’s law)

V = 2π(0.0012)(0.0728)/(1000×9.8)

V = 5.49×10⁻⁵/9800

V = 5.6×10⁻⁹ m³ = 0.056 mL

🫧 Problem 3: Bubble Pressure

Given:

• Soap bubble radius = 3.0 cm
• Surface tension of soap solution = 25 mN/m
• Atmospheric pressure = 101.3 kPa

Find: Pressure inside the bubble

Solution:

ΔP = 4γ/r (for soap bubble)

ΔP = 4(0.025)/(0.03)

ΔP = 0.1/0.03 = 3.33 Pa

P_inside = P_atm + ΔP

P_inside = 101,303.33 Pa

⚖️ Problem 4: Ring Detachment

Given:

• Platinum ring diameter = 4.0 cm
• Force required to detach = 0.0182 N
• Ring thickness negligible

Find: Surface tension of the liquid

Solution:

F = γ × L (where L = 2πr for ring)

γ = F/(2πr)

γ = 0.0182/(2π × 0.02)

γ = 0.0182/0.1257

γ = 0.145 N/m = 145 mN/m

🎯 Key Formulas for Surface Tension Calculations

Capillary Rise Method:

γ = ρghr/(2cosθ)

Drop Weight Method:

γ = mg/(2πr)

Bubble Pressure:

ΔP = 4γ/r (soap bubble)

Ring Detachment:

γ = F/(2πr)

Surface Tension in Liquids

Surface tension plays a crucial role in liquid behavior by affecting droplet formation, wetting properties, and interfacial phenomena. Understanding surface tension helps explain many liquid characteristics and industrial applications.

📏 Units of Surface Tension

N/m

SI Unit

dyn/cm

CGS Unit

mN/m

Common Lab Unit

🌊 What is Surface Tension?

Surface tension is the cohesive force between liquid molecules at the surface of a liquid. It arises because molecules at the surface experience unequal intermolecular forces compared to molecules in the bulk liquid. This creates a “skin-like” effect that allows insects to walk on water and causes droplets to form spherical shapes.

🔗

Molecular Forces

Unequal attractions at surface

💧

Droplet Formation

Minimizes surface area

⚖️

Energy Balance

Surface energy minimization

🧮 Surface Tension Formula

Surface tension (γ) is defined as the force per unit length acting perpendicular to any line on the surface:

γ = F/L = Energy/Area

Where F is the force in Newtons and L is the length in meters, giving units of N/m or J/m²

Determination of Surface Tension Methods

📏 Capillary Rise Method

Measures surface tension through liquid rise in narrow tubes, relevant for osmotic membrane pore analysis.

γ = ρghr/2cosθ

Simple and accurate method
Requires clean capillary tubes
Contact angle measurement critical

💧 Drop Formation Method

Analyzes droplet formation to determine surface tension, useful for osmotic solution characterization.

Dynamic measurement technique
Suitable for various liquids
Requires precise volume control

💍 Ring-detachment Method

Uses platinum ring to measure surface tension, excellent for osmotic solution studies.

High precision measurements
Suitable for temperature studies
Requires calibrated equipment

🫧 Bubble Pressure Method

Measures pressure required to form bubbles, relevant for membrane pore characterization in osmosis.

Dynamic surface tension measurement
Useful for surfactant solutions
Provides time-dependent data

📊 SURFACE TENSION OF SOME LIQUIDS AT VARIOUS TEMPERATURES (dynes cm⁻¹)

Surface tension values decrease with increasing temperature due to reduced intermolecular forces

Liquid	0°C	10°C	20°C	30°C	40°C	50°C	60°C
Water (H₂O)	75.6	74.2	72.8	71.2	69.6	67.9	66.2
Ethanol (C₂H₅OH)	24.0	23.2	22.3	21.4	20.5	19.6	18.7
Benzene (C₆H₆)	31.6	30.2	28.9	27.5	26.2	24.8	23.5
Acetone (CH₃COCH₃)	26.2	25.0	23.7	22.4	21.2	19.9	18.6
Chloroform (CHCl₃)	29.2	28.1	27.1	26.0	25.0	23.9	22.8
Carbon Tetrachloride (CCl₄)	28.4	27.3	26.2	25.1	24.0	22.9	21.8
Diethyl Ether (C₂H₅OC₂H₅)	18.2	17.4	16.6	15.8	15.0	14.2	13.4
Glycerol (C₃H₈O₃)	65.4	64.2	63.0	61.8	60.6	59.4	58.2
n-Hexane (C₆H₁₄)	20.4	19.8	18.4	17.0	15.6	14.2	12.8
Mercury (Hg)	486.5	485.2	483.9	482.6	481.3	480.0	478.7

📉

Temperature Effect

Surface tension decreases linearly with temperature

🔗

Molecular Forces

Stronger intermolecular forces = higher surface tension

⚖️

Unit Conversion

1 dyne/cm = 1 mN/m = 0.001 N/m

💧

Water Reference

Water has highest surface tension among common liquids

What is Viscosity: Dynamic & Kinematic Viscosity of Water

Viscosity is the measure of a fluid’s resistance to flow and deformation. Understanding what is viscosity, particularly the viscosity of water, is fundamental to chemistry and physics. This section covers dynamic viscosity, kinematic viscosity, viscosity units, and specifically focuses on dynamic viscosity of water and kinematic viscosity of water.

📊 Viscosity Units: Dynamic Viscosity Units & Kinematic Viscosity Units

Understanding viscosity units is crucial for measuring dynamic viscosity and kinematic viscosity. Dynamic viscosity units measure absolute viscosity, while kinematic viscosity units account for fluid density.

Dynamic Viscosity Units

Pa·s

SI Unit

Poise (P)

CGS Unit

Centipoise

mPa·s

Millipascal-second

Kinematic Viscosity Units

m²/s

SI Unit

Stokes (St)

CGS Unit

cSt

Centistokes

mm²/s

Square mm/second

🌊 Dynamic Viscosity of Water

Dynamic viscosity (absolute viscosity) measures a fluid’s internal resistance to flow. The dynamic viscosity of water at 20°C is approximately 1.002 mPa·s (millipascal-seconds).

η = τ / (du/dy)

Temperature dependent property
Decreases with increasing temperature
Measured in dynamic viscosity units
Independent of fluid density

💨 Kinematic Viscosity of Water

Kinematic viscosity is the ratio of dynamic viscosity to fluid density. The kinematic viscosity of water at 20°C is approximately 1.004 mm²/s (square millimeters per second).

ν = η / ρ

Accounts for fluid density effects
Used in fluid mechanics calculations
Measured in kinematic viscosity units
Important for Reynolds number

Measurement of Viscosity

🧪 Ostwald’s Method for Viscosity Measurement

Ostwald’s method is a precise technique for measuring the relative viscosity of liquids using a capillary viscometer. This method compares the flow times of different liquids through the same capillary under identical conditions.

🔬 Principle of Ostwald’s Method

Based on Poiseuille’s law for viscous flow through capillaries. The method measures the time required for a fixed volume of liquid to flow through a capillary of known dimensions.

Poiseuille’s Law:
η = (πr⁴Pt)/(8VL)

⚖️ Relative Viscosity Formula

For comparative measurements, the absolute viscosity cancels out, giving the relative viscosity formula:

η₁/η₂ = (ρ₁t₁)/(ρ₂t₂)

Where η = viscosity, ρ = density, t = flow time

🛠️ Ostwald Viscometer Components

📏

Capillary Tube

Precise bore diameter

💧

Bulb Reservoir

Fixed volume chamber

📊

Timing Marks

Precise volume markers

🌡️

Temperature Bath

Constant temperature

📋 Detailed Procedure

Cleaning: Thoroughly clean viscometer with appropriate solvents
Calibration: Use standard liquid (usually water) as reference
Temperature Control: Maintain constant temperature (±0.1°C)
Sample Loading: Fill viscometer with precise volume
Flow Time Measurement: Record time between timing marks
Repetition: Take multiple readings for accuracy
Calculation: Apply relative viscosity formula

🎯 Applications & Advantages

High Precision: Accurate to ±0.1% for careful work
Simple Operation: No complex instrumentation required
Wide Range: Suitable for various liquid viscosities
Temperature Studies: Easy temperature variation
Quality Control: Industrial and research applications
Comparative Analysis: Ideal for relative measurements

⚠️ Precautions and Sources of Error

Temperature Control

• Maintain constant temperature
• Allow thermal equilibration
• Use thermostat bath

Timing Accuracy

• Use precise stopwatch
• Consistent timing marks
• Multiple measurements

Sample Purity

• Clean, dry samples
• No air bubbles
• Proper viscometer cleaning

🌡️ Temperature Effects on Viscosity of Water

Temperature dramatically affects the viscosity of water and other liquids. Both dynamic viscosity of water and kinematic viscosity of water decrease exponentially with increasing temperature, following the Arrhenius relationship.

Viscosity of Water at Different Temperatures:

0°C

1.787 mPa·s

20°C

1.002 mPa·s

40°C

0.653 mPa·s

100°C

0.282 mPa·s

🔥

Higher Temperature

Lower dynamic viscosity

⚖️

Room Temperature

Standard viscosity reference

❄️

Lower Temperature

Higher kinematic viscosity

🧮 Surface Tension Numerical Problems

Practice problems to master surface tension calculations and applications

📏 Problem 1: Capillary Rise Method

Given:

• Water rises 2.8 cm in a capillary tube
• Tube radius = 0.5 mm
• Contact angle θ = 0°
• Density of water = 1000 kg/m³
• g = 9.8 m/s²

Find: Surface tension of water

Solution:

γ = ρghr/(2cosθ)

γ = (1000)(9.8)(0.028)(0.0005)/(2×cos0°)

γ = 0.1372/2 = 0.0686 N/m

γ = 68.6 mN/m

💧 Problem 2: Drop Formation

Given:

• 50 drops of water fall from a burette
• Total volume = 2.5 mL
• Burette tip radius = 1.2 mm
• Surface tension of water = 72.8 mN/m

Find: Theoretical volume per drop

Solution:

V = 2πrγ/ρg (Tate’s law)

V = 2π(0.0012)(0.0728)/(1000×9.8)

V = 5.49×10⁻⁵/9800

V = 5.6×10⁻⁹ m³ = 0.056 mL

🫧 Problem 3: Bubble Pressure

Given:

• Soap bubble radius = 3.0 cm
• Surface tension of soap solution = 25 mN/m
• Atmospheric pressure = 101.3 kPa

Find: Pressure inside the bubble

Solution:

ΔP = 4γ/r (for soap bubble)

ΔP = 4(0.025)/(0.03)

ΔP = 0.1/0.03 = 3.33 Pa

P_inside = P_atm + ΔP

P_inside = 101,303.33 Pa

⚖️ Problem 4: Ring Detachment

Given:

• Platinum ring diameter = 4.0 cm
• Force required to detach = 0.0182 N
• Ring thickness negligible

Find: Surface tension of the liquid

Solution:

F = γ × L (where L = 2πr for ring)

γ = F/(2πr)

γ = 0.0182/(2π × 0.02)

γ = 0.0182/0.1257

γ = 0.145 N/m = 145 mN/m

🎯 Key Formulas for Surface Tension Calculations

Capillary Rise Method:

γ = ρghr/(2cosθ)

Drop Weight Method:

γ = mg/(2πr)

Bubble Pressure:

ΔP = 4γ/r (soap bubble)

Ring Detachment:

γ = F/(2πr)

Refractive Index and Optical Properties

🔍 Refractive Index

The refractive index is a fundamental optical property that measures how much light bends when passing from one medium to another. It provides valuable information about molecular density, purity, and composition of liquids.

📐 Definition and Formula

Refractive index (n) is defined as the ratio of the speed of light in vacuum to its speed in the medium:

n = c/v = sin(θ₁)/sin(θ₂)

Snell’s Law of Refraction

• c = speed of light in vacuum
• v = speed of light in medium
• θ₁, θ₂ = angles of incidence and refraction

🌡️ Factors Affecting Refractive Index

• Temperature: Generally decreases with increasing temperature
• Wavelength: Varies with light wavelength (dispersion)
• Pressure: Slight increase with pressure for liquids
• Concentration: Changes with solute concentration
• Molecular structure: Depends on electronic polarizability

📊 Refractive Index Values for Common Liquids (at 20°C, 589 nm)

1.3330

Water

1.3614

Ethanol

1.5011

Benzene

1.3588

Acetone

📏 Specific Refraction

Specific refraction is an intensive property that relates refractive index to density, providing insights into molecular structure and intermolecular interactions independent of physical conditions.

🧮 Lorentz-Lorenz Equation

The most commonly used formula for specific refraction:

r = (n² – 1)/(n² + 2) × (1/ρ)

Specific Refraction Formula

• r = specific refraction
• n = refractive index
• ρ = density of the liquid

🎯 Applications of Specific Refraction

• Molecular characterization: Independent of temperature and pressure
• Purity analysis: Detects impurities in liquids
• Mixture analysis: Additive property for solutions
• Quality control: Industrial applications
• Research: Fundamental molecular studies

📈 Temperature Independence

Specific refraction remains relatively constant with temperature changes, making it valuable for:

🌡️

Temperature Studies

🔬

Molecular Analysis

⚖️

Standardization

🧬 Molar Refraction

Molar refraction relates refractive index to molecular structure and provides insights into electronic polarizability and molecular volume. It’s an additive property useful for predicting refractive indices of compounds.

🔬 Molar Refraction Formula

Molar refraction combines refractive index with molar volume:

R = (n² – 1)/(n² + 2) × M/ρ

Molar Refraction Equation

• R = molar refraction (cm³/mol)
• M = molar mass (g/mol)
• ρ = density (g/cm³)

🎯 Properties of Molar Refraction

• Additive property: Sum of atomic/group contributions
• Temperature independent: Relatively constant with T
• Pressure independent: Unaffected by moderate pressure changes
• Structural information: Related to molecular polarizability
• Predictive tool: Estimate refractive indices

📊 Atomic and Group Contributions to Molar Refraction

Atoms

C: 2.418 cm³/mol

H: 1.100 cm³/mol

O: 1.525 cm³/mol

N: 2.322 cm³/mol

Bonds

C=C: +1.733 cm³/mol

C≡C: +2.398 cm³/mol

C=O: +3.736 cm³/mol

Benzene ring: +2.398 cm³/mol

Applications

• Structure determination

• Purity assessment

• Mixture analysis

• Molecular design

🧮 Calculation Example

For ethanol (C₂H₅OH): R = 2×2.418 + 6×1.100 + 1×1.525 = 13.961 cm³/mol

Compare with experimental value: 13.01 cm³/mol

🔬 Determination of Refractive Index

Accurate refractive index measurement is essential for liquid characterization, quality control, and research applications.

Abbe Refractometer

• High precision (±0.0001)
• Temperature controlled
• Wide measurement range
• Most common laboratory instrument

Digital Refractometer

• Automatic temperature compensation
• Rapid measurements
• Digital display
• Ideal for routine analysis

Critical Angle Method

• Fundamental principle
• High accuracy potential
• Research applications
• Requires skilled operation

🌀 Optical Activity

Optical activity is the ability of certain substances to rotate the plane of polarized light. This property is exhibited by chiral molecules and provides valuable information about molecular structure and concentration.

🔍 Fundamentals of Optical Activity

• Chirality requirement: Molecules must lack mirror symmetry
• Polarized light rotation: Clockwise (dextrorotatory, +) or counterclockwise (levorotatory, -)
• Concentration dependent: Rotation angle proportional to concentration
• Path length dependent: Longer path = greater rotation
• Wavelength dependent: Optical rotatory dispersion

🎯 Applications of Optical Activity

• Pharmaceutical analysis: Drug purity and enantiomer ratio
• Sugar analysis: Concentration determination
• Protein studies: Structural analysis
• Quality control: Industrial applications
• Research: Stereochemistry studies

📐 Measurement of Optical Activity

Optical activity is measured using a polarimeter, which determines the angle of rotation of polarized light:

α = observed rotation angle (degrees)

📊 Specific Rotation

Specific rotation is an intensive property that characterizes the optical activity of a substance independent of concentration and path length. It’s a fundamental constant for optically active compounds.

🧮 Specific Rotation Formula

Specific rotation normalizes observed rotation for concentration and path length:

[α]ᵀλ = α/(l × c)

Specific Rotation Equation

• [α] = specific rotation (deg·mL·g⁻¹·dm⁻¹)
• α = observed rotation (degrees)
• l = path length (dm)
• c = concentration (g/mL)
• T = temperature, λ = wavelength

🌡️ Factors Affecting Specific Rotation

• Temperature: Usually decreases with increasing temperature
• Wavelength: Varies significantly (optical rotatory dispersion)
• Solvent: Can affect rotation magnitude and sign
• Concentration: May show non-linear effects at high concentrations
• pH: Important for ionizable compounds

📊 Specific Rotation Values for Common Compounds

Compound	[α]²⁰ᴅ	Solvent	Application
Sucrose	+66.5°	Water	Sugar analysis
D-Glucose	+52.7°	Water	Biochemical analysis
L-Tartaric acid	+12.0°	Water	Food industry
Quinine	-165°	Ethanol	Pharmaceutical

🎯 Applications of Specific Rotation

💊

Pharmaceutical

Drug purity and enantiomer analysis

🍯

Food Industry

Sugar concentration determination

🔬

Research

Stereochemistry and structure studies

🧮 Surface Tension Numerical Problems

Practice problems to master surface tension calculations and applications

📏 Problem 1: Capillary Rise Method

Given:

• Water rises 2.8 cm in a capillary tube
• Tube radius = 0.5 mm
• Contact angle θ = 0°
• Density of water = 1000 kg/m³
• g = 9.8 m/s²

Find: Surface tension of water

Solution:

γ = ρghr/(2cosθ)

γ = (1000)(9.8)(0.028)(0.0005)/(2×cos0°)

γ = 0.1372/2 = 0.0686 N/m

γ = 68.6 mN/m

💧 Problem 2: Drop Formation

Given:

• 50 drops of water fall from a burette
• Total volume = 2.5 mL
• Burette tip radius = 1.2 mm
• Surface tension of water = 72.8 mN/m

Find: Theoretical volume per drop

Solution:

V = 2πrγ/ρg (Tate’s law)

V = 2π(0.0012)(0.0728)/(1000×9.8)

V = 5.49×10⁻⁵/9800

V = 5.6×10⁻⁹ m³ = 0.056 mL

🫧 Problem 3: Bubble Pressure

Given:

• Soap bubble radius = 3.0 cm
• Surface tension of soap solution = 25 mN/m
• Atmospheric pressure = 101.3 kPa

Find: Pressure inside the bubble

Solution:

ΔP = 4γ/r (for soap bubble)

ΔP = 4(0.025)/(0.03)

ΔP = 0.1/0.03 = 3.33 Pa

P_inside = P_atm + ΔP

P_inside = 101,303.33 Pa

⚖️ Problem 4: Ring Detachment

Given:

• Platinum ring diameter = 4.0 cm
• Force required to detach = 0.0182 N
• Ring thickness negligible

Find: Surface tension of the liquid

Solution:

F = γ × L (where L = 2πr for ring)

γ = F/(2πr)

γ = 0.0182/(2π × 0.02)

γ = 0.0182/0.1257

γ = 0.145 N/m = 145 mN/m

🎯 Key Formulas for Surface Tension Calculations

Capillary Rise Method:

γ = ρghr/(2cosθ)

Drop Weight Method:

γ = mg/(2πr)

Bubble Pressure:

ΔP = 4γ/r (soap bubble)

Ring Detachment:

γ = F/(2πr)

Osmosis: The Complete Scientific Guide

🌊 What is Osmosis?

Osmosis represents the spontaneous movement of water molecules across a selectively permeable membrane from a region of lower solute concentration to higher solute concentration. This fundamental process drives countless biological and industrial applications.

💧

Water Movement

Selective transport across membranes

⚖️

Concentration Gradient

Drives the osmotic process

🧱

Selective Membrane

Controls molecular passage

🔬 Osmotic Pressure

Osmotic pressure quantifies the driving force behind osmosis, calculated using the van ‘t Hoff equation.

π = iMRT

i = van ‘t Hoff factor
M = molar concentration
R = gas constant
T = absolute temperature

🏭 Industrial Applications

Osmosis powers numerous industrial processes, from water purification to pharmaceutical manufacturing.

Reverse osmosis water treatment
Food preservation and processing
Pharmaceutical drug delivery
Desalination technologies
Biological membrane studies

⚡ Factors Affecting Osmosis Rate

🌡️

Temperature

Higher temperature increases osmotic rate

📊

Concentration

Greater gradient drives faster osmosis

🧱

Membrane

Permeability affects transport rate

💨

Pressure

External pressure influences flow

🧮 Surface Tension Numerical Problems

Practice problems to master surface tension calculations and applications

📏 Problem 1: Capillary Rise Method

Given:

• Water rises 2.8 cm in a capillary tube
• Tube radius = 0.5 mm
• Contact angle θ = 0°
• Density of water = 1000 kg/m³
• g = 9.8 m/s²

Find: Surface tension of water

Solution:

γ = ρghr/(2cosθ)

γ = (1000)(9.8)(0.028)(0.0005)/(2×cos0°)

γ = 0.1372/2 = 0.0686 N/m

γ = 68.6 mN/m

💧 Problem 2: Drop Formation

Given:

• 50 drops of water fall from a burette
• Total volume = 2.5 mL
• Burette tip radius = 1.2 mm
• Surface tension of water = 72.8 mN/m

Find: Theoretical volume per drop

Solution:

V = 2πrγ/ρg (Tate’s law)

V = 2π(0.0012)(0.0728)/(1000×9.8)

V = 5.49×10⁻⁵/9800

V = 5.6×10⁻⁹ m³ = 0.056 mL

🫧 Problem 3: Bubble Pressure

Given:

• Soap bubble radius = 3.0 cm
• Surface tension of soap solution = 25 mN/m
• Atmospheric pressure = 101.3 kPa

Find: Pressure inside the bubble

Solution:

ΔP = 4γ/r (for soap bubble)

ΔP = 4(0.025)/(0.03)

ΔP = 0.1/0.03 = 3.33 Pa

P_inside = P_atm + ΔP

P_inside = 101,303.33 Pa

⚖️ Problem 4: Ring Detachment

Given:

• Platinum ring diameter = 4.0 cm
• Force required to detach = 0.0182 N
• Ring thickness negligible

Find: Surface tension of the liquid

Solution:

F = γ × L (where L = 2πr for ring)

γ = F/(2πr)

γ = 0.0182/(2π × 0.02)

γ = 0.0182/0.1257

γ = 0.145 N/m = 145 mN/m

🎯 Key Formulas for Surface Tension Calculations

Capillary Rise Method:

γ = ρghr/(2cosθ)

Drop Weight Method:

γ = mg/(2πr)

Bubble Pressure:

ΔP = 4γ/r (soap bubble)

Ring Detachment:

γ = F/(2πr)

Frequently Asked Questions About Osmosis

What is the difference between osmosis and diffusion?

Osmosis specifically involves water movement across a selectively permeable membrane, while diffusion refers to the general movement of any particles from high to low concentration. Osmosis requires a membrane barrier, whereas diffusion can occur in open systems.

How does temperature affect osmosis rate?

Higher temperatures increase molecular kinetic energy, leading to faster water molecule movement and increased osmosis rates. However, extremely high temperatures can damage biological membranes and disrupt the osmotic process.

Why is osmosis important in biological systems?

Osmosis maintains cell shape, regulates water balance, enables nutrient transport, and controls blood pressure. Without osmosis, cells would either shrivel or burst, making it essential for all life processes.

What factors determine osmotic pressure?

Osmotic pressure depends on solute concentration, temperature, and the van ‘t Hoff factor (number of particles formed when a solute dissolves). The relationship follows the equation π = iMRT.

How is osmosis used in water purification?

Reverse osmosis applies pressure to force water through a membrane against its natural osmotic gradient, removing contaminants and producing pure water. This process is widely used in desalination and drinking water treatment.

How to Measure Osmotic Properties: Step-by-Step Guide

🧪 Measuring Osmotic Pressure

Prepare solutions of known concentrations
Set up osmometer with selectively permeable membrane
Fill compartments with test and reference solutions
Monitor height difference over time
Calculate osmotic pressure using π = ρgh
Verify results using van ‘t Hoff equation

📊 Analyzing Osmotic Data

Record temperature and concentration data
Plot osmotic pressure vs. concentration
Calculate van ‘t Hoff factor from slope
Determine membrane selectivity coefficient
Assess temperature dependence
Compare with theoretical predictions