Atmosphere
Atoms
Celestial Bodies
Circuits
电路 (diàn lù)
电路 (Diànlù)
电路
通信系统Pdf
二极管
地球科学
电荷
电
Electricity
电磁波
电磁
静电学
能量
流体
武力
Force
摩擦
万有引力
热
动力学理论
光
磁性
运动
自然资源
核物理学
光学
Optics
Oscillation
Pressure
Quantum physics
Radioactivity
Scalars and Vectors
Scientific Method
Semiconductors
Solid Deformation
Sound
System of Particles and Rotational Dynamics
Thermal Properties of Matter
Thermodynamics
Units and measurements
Waves
Work, Energy and Power
Physics Experiments
Atoms
Celestial Bodies
- Space Travel Equipment
- Stars
- Rotation and Revolution
- Relation Between Escape Velocity And Orbital Velocity
- Dwarf Planets
- Difference Between Solar Eclipse And Lunar Eclipse
- Difference Between Equinox And Solstice
- The Escape Velocity Of Earth
- Solar System
- Difference Between Stars And Planets
- Difference Between Asteroid And Meteoroid
- Constellations
Circuits
电路 (diàn lù)
电路 (Diànlù)
电路
通信系统Pdf
二极管
地球科学
电荷
电
- 类型的齿轮
- 电子产品在日常生活中
- 类型的汽车
- 类型的直流电机
- 类型的交流电机
- 晶体管工作
- 转矩电流环
- 电动机
- 电阻温度依赖性
- Rms值交流电
- 电抗和阻抗
- 相量表示法交流
- 平行板电容器
- 焦耳定律
- 电力
- 磁场对载流导线的影响
- 电流密度
- 导体绝缘体
- 导电
- 碳电阻器
- 直流发电机
- 类型的发电机
- 类型的电流
- 直流发电机类型
- Torque On Dipole
- 电流的热效应
- 电动发电机
- 静电
- 电阻率不同的材料
- 电场的物理意义
- 介电常数和磁导率
- 电能和权力
- 电流在导体
- 电动汽车
- 位移电流
- 电阻与电阻率之间的差异
- 电动机和发电机之间的区别
- 接地和接地之间的区别
- 电流线圈
- 水的电导率
- 导电的液体
Electricity
电磁波
电磁
静电学
能量
- 能量
- 能源类型
- 热能
- 太阳能项目
- 太阳能汽车
- Ev和Joule之间的关系
- 动能和完成的功
- 能量转换
- 一维和二维的弹性和非弹性碰撞
- 常规能源和非常规能源
- 太阳能炊具
- 潮汐能
- 能源
- 太阳能和光伏电池
- 动能与动量的关系
- 热量与焦耳的关系
- 能源及其对环境的影响
- 能源考虑
流体
武力
Force
摩擦
万有引力
热
动力学理论
光
- 镜面反射漫反射
- 人眼
- 结构人眼功能
- 阴影的形成
- 反射和折射之间的区别
- 相干源
- 光的透射、吸收和反射
- 透明半透明和不透明
- 阳光白色
- 单狭缝衍射
- 拉曼散射
- 粒子自然光光子
- 真实图像与虚拟图像的区别
- 衍射和干涉的区别
磁性
运动
- 运输历史记录
- 速度-时间图
- 旋转动能
- 刚体和刚体动力学
- 扭矩和速度之间的关系
- 粒子的直线运动
- 周期性运动
- 动量和惯性之间的差异
- 动量守恒
- 运动测量类型
- 扭矩
- 慢速和快速运动
- 滚动
- 刚体平移运动和旋转运动
- 相对速度
- 径向加速度
- 速度和速度之间的区别
- 动力学和运动学的区别
- 连续性方程
- 线性动量守恒
自然资源
核物理学
光学
Optics
- Reflection of Light and Laws of Reflection
- Concave Lens
- Total Internal Reflection
- Thin Lens Formula For Concave And Convex Lenses
- Spherical Mirror Formula
- Resolving Power Of Microscopes And Telescopes
- Refractive Index
- Refraction Of Light
- Refraction Light Glass Prism
- Reflection On A Plane Mirror
- Reflection Lateral Inversion
- Rainbow
- Photometry
- Difference Between Simple And Compound Microscope
- Difference Between Light Microscope And Electron Microscope
- Concave Convex Mirror
- Toric Lens
- The Lens Makers Formula
- Simple Microscope
Oscillation
Pressure
- Thrust Pressure
- Relation Between Bar And Pascal
- Regelation
- Sphygmomanometer
- Relation Between Bar And Atm
- Difference Between Stress And Pressure
Quantum physics
- Quantum physics
- Rydberg Constant
- Electron Spin
- Casimir Effect
- Relativity
- Quantum Mechanics
- Electrons And Photons
Radioactivity
- Relation Between Beta And Gamma Function
- Radioactivity Beta Decay
- Radioactive Decay
- Stefan Boltzmann Constant
- Radioactivity Gamma Decay
- Radioactivity Alpha Decay
- Radiation Detector
Scalars and Vectors
- Scalars and Vectors
- Triangle Law Of Vector Addition
- Scalar Product
- Scalar And Vector Products
- Difference Between Scalar And Vector
Scientific Method
- Scientific Methods
- Safety Measures Technology
- Difference Between Science And Technology
- Scientific Investigation
Semiconductors
- Semiconductor Devices
- Junction Transistor
- Semiconductor Diode
- Difference Between Npn And Pnp Transistor
Solid Deformation
- Solid State Physics
- Solid Deformation
- Stress
- Shear Modulus Elastic Moduli
- Relation Between Elastic Constants
- Elastic Behavior Of Solids
- Tensile Stress
- Stress And Strain
- Shearing Stress
- Elastomers
- Elastic Behaviour Of Materials
- Bulk Modulus Of Elasticity Definition Formula
Sound
- Sound waves
- Timbre
- Speed Of Sound Propagation
- Sound Waves Need Medium Propagation
- Sound Reflection
- Sound Produced Humans
- Doppler Shift
- Difference Between Sound Noise Music
- The Human Voice How Do Humans Create Sound With Their Vocal Cord
- Sound Vibration Propagation Of Sound
- Sound Produced Vibration Object
- Reverberation
- Doppler Effect
System of Particles and Rotational Dynamics
Thermal Properties of Matter
- Thermal Properties of Materials
- Thermal Stress
- Thermal Expansion Of Solids
- Thermal Conductivity Of Metals
Thermodynamics
- Statistical Physics
- SI Units List
- Statistical Mechanics
- Reversible Irreversible Processes
- Carnots Theorem
- Temperature
- Kelvin Planck Statement
- Difference between Isothermal and Adiabatic Processes
Units and measurements
- Density of Air
- The Idea Of Time
- Difference Between Pound And Kilogram
- Difference Between Mass And Volume
- Dimensional Analysis
- Density Of Water
- Time Measurement
- Standard Measurement Units
- Relation Between Kg And Newton
- Relation Between Density And Temperature
- Difference Between Mass And Weight
Waves
- Space Wave Propagation
- Sharpness Of Resonance
- Relation Between Group Velocity And Phase Velocity
- Relation Between Amplitude And Frequency
- Periodic Function
- P Wave
- Destructive Interference
- Transverse Waves
- Travelling Wave
- Standing Wave Normal Mode
- S Waves
- Relation Between Frequency And Velocity
- Reflection Of Waves
- Phase Angle
- Period Angular Frequency
Work, Energy and Power
- Derivation Of Work Energy Theorem
- Conservation Of Mechanical Energy
- Relation Between Work And Energy
- Destruction Caused Cyclones
Physics Experiments
- Determine Resistance Plotting Graph Potential Difference versus Current
- To find the weight of a given Body using Parallelogram Law of Vectors
- To study the variation in volume with pressure for a sample of air at constant temperature by plotting graphs between p and v
- To measure the thickness of sheet using Screw Gauge
- To find the value of V for different U values of Concave Mirror find Focal Length
- To find the Surface Tension of Water by Capillary Rise Method
- To find the Resistance of given wire using Metre Bridge and hence determine the Resistivity of its Material Experiment
- Determine Mass of Two Different Objects Using Beam Balance
- Tracing the path of the rays of light through a glass Prism
- Tracing path of a ray of light passing through a glass slab
- Tornado Bottle
- To find image distance for varying object distances of a convex lens with ray diagrams
- To find force constant of helical spring by plotting a graph between load and extension
- To find focal length of concave lens using convex lens
- To find effective length of seconds pendulum using graph
- To find downward force along inclined plane on a roller due to gravitational pull of the earth and its relationship with the angle of inclination
- To draw the IV characteristic curve for p n junction in forward and reverse bias
- To determine Young’s modulus of elasticity of the material of a given wire
- To determine the internal resistance of a given primary cell using a potentiometer experiment
- To determine the coefficient of viscosity of given viscous liquid by measuring terminal velocity of given spherical body
- To determine specific heat capacity of given solid by method of mixtures
- To determine radius of curvature of a given spherical surface by a Spherometer
- Scope and Excitement of Physics
- Rocket science
- Relationship between frequency and length of wire under constant tension using Sonometer
- To determine equivalent resistance of resistors when connected in series and in parallel
- To convert the given galvanometer of known resistance and figure of merit into a voltmeter of desired range and to verify the same experiment
- To determine minimum deviation for given prism by plotting graph between angle of incidence and angle of deviation
- To compare the emf of two given primary cells using potentiometer experiment
Relation Between Work And Energy
Introduction
The energy of the machinery body can be transferred to other objects to move. Transferring the energy to other body particles is in the form of force. The actual amount of energy that is transferred by the help of inside and outside forces to move to another object is considered as work as well as work done. Therefore, the relation between the work and energy in physics is direct and the difference between these two factors can be seen in the kinetic energy of a particular object that is work done by the specific object.
Relation between Work and Energy
The relation between these two objects is measured by the formula $mathrm{W=1/2:mv^{2}f-1/2mv^{2}i}$ where W signifies the rate of work done that is generally measured by using Joules, and m denotes the object’s mass that is measured with the unit of kg. In this formula, vi considered the prepminary velocity of the object that is calculated with the unit of m/s while vf considered the final velocity of the object that is calculated with the unit of m/s (Kukhar et al. 2018).
Another important formula is severally used for measuring is $mathrm{W=K_{i}-K_{f}}$. In this formula, W represents the rate of work done, Ki denotes the kinetic energy and the Kf. refers to as the final energy of the machinery body.
Measuring Process of Work and Energy
Work denotes the motion of the machinery body that is caused in case of force. For example, if a man started to cpmb a fpght of stairs is the perfect illustration of this incident. This is happened because of gravitational force (Kukhar et al. 2018). When a man cpmbs against the gravitational force in case of the man has been done the work against it.
Images Coming soon
The workforce can be calculated by the formula
Work = force $mathrm{ imes}$ displacement towards the force and it is equivalent to F*S.
In the formula, the F stands for the force and S denotes the distance. The work of the machinery body is equivalent to FS Cos$mathrm{ heta}$ and it has happened when the machinery body is displaced by the entire distance covered by an operating force (Mintairov et al. 2019). The figure denotes that with the increment of energy the work rate is also increased.
Properties of Work and Energy
Images Coming soon
The same unit that is Joule calculates the energy, as well as work. Simply, the work capacity of a machinery body is represented as energy. The work rate of the body is completed with s specific amount of work that is also finished as per the time unit that is referred to as power. In order to do work, one has to need some energy while power is that pecupar rate at which the body can.
Difference between Work and Energy
Work is demonstrated as the sort of energy transfer that happens when an object is shifted over a distance by an external force. Energy is illustrated as the calculation of the capabipty of something in doing the tasks (Ostertak, Sinitskiy & Dragunov 2019).
Energy is not materiapstic or any sort of substance. Energy can also be termed as the speed which works at a measurable distance and deals with the capabipty of an object in doing the tasks (Touzani et al. 2018). The SI unit of work and energy is Joules.
| Work | Energy |
|---|---|
| Work is mentioned as the capabipty to transform in distance to the object and supply the force. | Energy is mentioned as the capabipty of creating or supplying the work with high force. |
| A parallel connection between the components and displacement of force exists. | Energy is demonstrated as the consequence of the performance of work. |
| The course of action happening on the thing causes some sort of displacement. | Energy is often referred to as the system property. |
| It is a scalar unit | Energy similar to the work is also referred to as scalar units. |
Work is equal to force multipped by distance. (Work = force*distance) |
Multiple equations are there relying upon different types of energy. |
| Work is known to be positive if the appped force is within a similar displacement direction. | Energy does not have any directional element because it is referred to as a scalar quantity. |
| Work becomes negative if apppcable force is another displacement way. | Do not change in Energy because it is a scalar quantity. |
Conclusion
Work and energy possess a powerful relation as energy may get changed to an object in shifting to it. They have a direct connection and the distinction in the kinetic energy of the object is work done by them. The work-energy theorem demonstrates the connection between kinetic energy and work. The theory states that doing work by the addition of all the forces acting over the object or particle is equal to the transformation in a particle s Kinetic energy. The capabipty to do any sort of job is mentioned as the Energy. An inspanidual requires some energy in completing the work. The relationship between the terms is clearly determined by their definition.
FAQs
Q.1. Is the energy amount and work done amount expanded the same?
Ans. Energy must be provided to assist the moving of objects and this energy might be portrayed in the type of force. Work done or work is mentioned as the energy transferred by force to shift any object.
Q.2. Illustrate 1J of work
Ans. 1 Joule of work is mentioned as the work done through the own direction when 1N force causes the deportation of 1 m. The SI unit of work is Joule.
Q.3. What is the Kinetic energy of an object?
Ans. The possession of energy by the body by motion virtue is referred to as Kinetic energy. The expression of Kinetic energy (KE) is equal to $mathrm{1/2mv^{2}}$ where m represents mass and V denotes velocity.
Q.4. Can work do be represented as Zero?
Ans. Work done is said to be zero when the body displacement is perpendicular or Zero to the appped force in any direction. For instance, if the person tries to move the wall, that person is putting force and the wall does not move, then work done is said to be zero.