Orisun Ikẹkọ Afara Alawọ ewe Fun Elasticity

Akopọ

Welcome to the course material on Elasticity in Physics. This topic delves into the fascinating world of materials and their response to external forces. Understanding elasticity is crucial as it helps us comprehend how materials deform and return to their original shape when forces are applied and removed.

One of the key aspects covered in this topic is the force-extension curve, which provides valuable insights into a material's behavior under stress. This curve typically illustrates the relationship between applied force and resulting extension, showcasing important points such as the elastic limit, yield point, and breaking point. These critical points help us determine the maximum stress a material can endure before permanent deformation occurs.

Hooke's Law is another fundamental concept within elasticity that states the extension of a material is directly proportional to the applied force, as long as the elastic limit is not surpassed. This law is pivotal in understanding how materials behave within their linear elastic range and is often expressed as F = kx, where F is the force applied, x is the extension, and k is the material's stiffness constant.

Furthermore, Young's Modulus is a crucial parameter for materials, representing their stiffness and ability to withstand deformation. It quantifies the ratio of stress to strain in a material and is a key characteristic used to compare the elasticity of different substances.

Practical measurements of force are often carried out using a spring balance, a device specifically designed for measuring forces through the extension of a spring. By utilizing the principles of elasticity, spring balances provide accurate force measurements, making them indispensable tools in physics laboratories.

When studying springs and elastic strings, it is essential to calculate the work done per unit volume in these elements. Work done in such structures plays a significant role in understanding energy transfer and deformation processes, providing valuable insights into the behavior of elastic materials.

In conclusion, the topic of Elasticity offers a profound understanding of how materials respond to external forces, highlighting key concepts such as force-extension curves, Hooke's Law, Young's Modulus, and practical force measurement techniques using spring balances. By mastering these concepts, we can explore the intricate world of material science and its implications in various fields of physics and engineering.

Awọn Afojusun

Use Spring Balance to Measure Force
Interpret Force-Extension Curves
Interpret Hooke’s Law and Young’s Modulus of a Material
Determine the Work Done in Spring and Elastic Strings

Akọ̀wé Ẹ̀kọ́

Elasticity is a fundamental concept in physics that describes the ability of a material to return to its original shape and size after the removal of a force that causes deformation. Materials that exhibit high elasticity can stretch or compress significantly and then return to their original shape without permanent deformation. This ability is crucial in a wide range of applications, from everyday objects like rubber bands to sophisticated engineering materials like those used in building bridges.

Ìdánwò Ẹ̀kọ́

Oriire fun ipari ẹkọ lori Elasticity. Ni bayi ti o ti ṣawari naa awọn imọran bọtini ati awọn imọran, o to akoko lati fi imọ rẹ si idanwo. Ẹka yii nfunni ni ọpọlọpọ awọn adaṣe awọn ibeere ti a ṣe lati fun oye rẹ lokun ati ṣe iranlọwọ fun ọ lati ṣe iwọn oye ohun elo naa.

Iwọ yoo pade adalu awọn iru ibeere, pẹlu awọn ibeere olumulo pupọ, awọn ibeere idahun kukuru, ati awọn ibeere iwe kikọ. Gbogbo ibeere kọọkan ni a ṣe pẹlu iṣaro lati ṣe ayẹwo awọn ẹya oriṣiriṣi ti imọ rẹ ati awọn ogbon ironu pataki.

Lo ise abala yii gege bi anfaani lati mu oye re lori koko-ọrọ naa lagbara ati lati ṣe idanimọ eyikeyi agbegbe ti o le nilo afikun ikẹkọ. Maṣe jẹ ki awọn italaya eyikeyi ti o ba pade da ọ lójú; dipo, wo wọn gẹgẹ bi awọn anfaani fun idagbasoke ati ilọsiwaju.

What is the term used to describe the point beyond which a material will not return to its original shape once the deforming force is removed? A. Elastic limit B. Yield point C. Breaking point D. Young's modulus Answer: C. Breaking point
Which law states that the extension of a material is directly proportional to the applied force within the elastic limit? A. Hooke's law B. Newton's law C. Boyle's law D. Ohm's law Answer: A. Hooke's law
Which device is commonly used to measure force by utilizing the extension or compression of a spring? A. Barometer B. Hydrometer C. Spring balance D. Thermometer Answer: C. Spring balance
What is the physical quantity that measures the amount of energy transferred to a material when work is done on it per unit volume? A. Pressure B. Density C. Young's modulus D. Strain energy density Answer: D. Strain energy density
Which physical quantity describes the ratio of stress to strain in a material and indicates its stiffness? A. Elastic limit B. Hooke's constant C. Young's modulus D. Strain energy Answer: C. Young's modulus

Awọn Iwe Itọsọna Ti a Gba Nimọran

	Physics for Scientists and Engineers Atunkọ Mechanics Olùtẹ̀jáde Pearson Odún 2017 ISBN 978-0136273048
	Fundamentals of Physics Atunkọ Volume 1 Olùtẹ̀jáde Wiley Odún 2020 ISBN 978-1119655958

Àwọn Ìbéèrè Tó Ti Kọjá

Ṣe o n ronu ohun ti awọn ibeere atijọ fun koko-ọrọ yii dabi? Eyi ni nọmba awọn ibeere nipa Elasticity lati awọn ọdun ti o kọja.

JAMB UTME - Physics - 2023 (Tẹ bọtini lati ṣe idanwo kikun)

Ibeere 1 Ìròyìn

A piano wire 50 cm long has a total mass of 10 g and its stretched with a tension of 800 N. Find the frequency of the wire when it sounds its third overtone note.

800 Hz

600 Hz

400 Hz

200 Hz

Awọn alaye Idahun

T=800N; I=50cm=0.5m,

m=10g=0.01kg

fundamental freq: $f_{o}$ =?

$f_{o}$ = $\frac{1}{21} \sqrt T μ$

μ = $\frac{m}{1}$ = $\frac{0.01}{0.5}$

⇒ $f_{o}$ = $\frac{1}{2 \times 0.5}$ √ $\frac{800}{0.02}$

$f_{o}$ ⇒√ 40,000

⇒1st overtone = 2 $f_{o}$ =2×200 = 400Hz

⇒2nd overtone =3 $f_{o}$ =3×200=600Hz

∴3rd over tone= 4 $f_{o}$ =4×200=800Hz

Wo Idahun

WAEC SSCE - Physics - 2021 (Tẹ bọtini lati ṣe idanwo kikun)

Ibeere 1 Ìròyìn

(a)(i) State Hooke's law. (ii) A spring has a length of 0.20 m when a mass of 0.30 kg hangs on it, and a length of 0.75 nm when a mass of 1.95 kg hangs on it. Calculate the: (i) force constant of the spring; (ii) length of the spring when it is unloaded. [g = 10m/s$^2$]

(b)(i) What is diffusion? (ii) State two factors that affect the rate of diffusion of a substance. (iii) State the exact relationship between the rate of diffusion of a gas and its density.
(c) A satellite of mass, m orbits the earth of mass. M with a velocity, v at a distance R from the centre of the earth. Derive the relationship between the period T, of orbit and R.

Idahun

(a)

Hooke's law: states that the force exerted by a spring is directly proportional to the amount it is stretched or compressed, provided that the elastic limit is not exceeded. Mathematically, it can be represented as F = kx, where F is the force applied, k is the force constant, and x is the displacement of the spring from its equilibrium position.
Calculation of force constant and length of the unloaded spring: First, we can calculate the force constant of the spring using the equation F = kx. Using the first length and mass, the force can be calculated as F = mg = 0.30 kg * 10 m/s² = 3 N. Substituting these values in the equation, we get 3 = k * 0.20 m. Solving for k, we get k = 15 N/m. Next, we can calculate the length of the spring when it is unloaded using the equation F = kx, where F = 0 as there is no mass hanging from the spring. Thus, kx = 0, and x = 0, which means the spring is at its equilibrium length when there is no force applied to it.

(b)

Diffusion: is the movement of particles or substances from an area of high concentration to an area of low concentration. This occurs until the concentration of the particles is equal throughout the system.
Factors affecting the rate of diffusion: Two factors that affect the rate of diffusion are the concentration gradient and the temperature. The concentration gradient refers to the difference in concentration of the particles, with a larger difference leading to a faster rate of diffusion. Higher temperature means that the particles have more energy, leading to a faster rate of diffusion.
Relationship between rate of diffusion and gas density: The exact relationship between the rate of diffusion of a gas and its density is not well defined. However, it can be said that the rate of diffusion of a gas is inversely proportional to its density.

The equation for the period, T, of an object in orbit can be represented as T² = 4π² * R³ / (G * (M + m)), where G is the gravitational constant and M and m are the masses of the earth and satellite, respectively.

Awọn alaye Idahun

(a)

Hooke's law: states that the force exerted by a spring is directly proportional to the amount it is stretched or compressed, provided that the elastic limit is not exceeded. Mathematically, it can be represented as F = kx, where F is the force applied, k is the force constant, and x is the displacement of the spring from its equilibrium position.
Calculation of force constant and length of the unloaded spring: First, we can calculate the force constant of the spring using the equation F = kx. Using the first length and mass, the force can be calculated as F = mg = 0.30 kg * 10 m/s² = 3 N. Substituting these values in the equation, we get 3 = k * 0.20 m. Solving for k, we get k = 15 N/m. Next, we can calculate the length of the spring when it is unloaded using the equation F = kx, where F = 0 as there is no mass hanging from the spring. Thus, kx = 0, and x = 0, which means the spring is at its equilibrium length when there is no force applied to it.

(b)

Diffusion: is the movement of particles or substances from an area of high concentration to an area of low concentration. This occurs until the concentration of the particles is equal throughout the system.
Factors affecting the rate of diffusion: Two factors that affect the rate of diffusion are the concentration gradient and the temperature. The concentration gradient refers to the difference in concentration of the particles, with a larger difference leading to a faster rate of diffusion. Higher temperature means that the particles have more energy, leading to a faster rate of diffusion.
Relationship between rate of diffusion and gas density: The exact relationship between the rate of diffusion of a gas and its density is not well defined. However, it can be said that the rate of diffusion of a gas is inversely proportional to its density.

Wo Idahun

NECO SSCE - Physics - 2009 (Tẹ bọtini lati ṣe idanwo kikun)

Ibeere 1 Ìròyìn

The work done in extending a spring by 40 mm is 1.52J. Calculate the elastic constant of the spring.

38.8 Nm^-1

60.8 Nm^-1

190.0 Nm^-1

1900.0 Nm^-1

3800.0 Nm^-1

Wo Idahun