Other force types relevant to the study of dynamics We have already discussed field forces like gravitational and electromagnetic forces in the module named "Fundamental forces". Here, we embark to study other force types, which may form the part of the study of dynamics. These are : Contact force String tension Spring force

Contact force When an object is placed on another object, two surfaces of the bodies in contact apply normal force on each other. Similarly, when we push a body over a surface, the force of friction, arising from electromagnetic attraction among molecules at the contact surface, opposes relative motion of two bodies. In dynamics, we come across these two particular contact forces as described here.

Normal force When two bodies come in contact, they apply equal and opposite forces on each other in accordance with Newton’s third law of motion. As the name suggest, this "normal force" is normal to the common tangent drawn between two surfaces. We consider here a block of mass “m” placed on the table. The weight of the block (mg) acts downward. This force tries to deform the surface of the table. The material of the table responds by applying force to counteract the force that tends to deform it.

Normal force The surface applies a normal force on the body. The rigid bodies counteract any deformation in equal measure. A rigid table, therefore, applies a force, which is equal in magnitude and opposite in direction. As there is no relative motion at the interface, this contact force has no component along the interface and as such it is normal to the interface. N = m g

Friction force Force of friction comes into play whenever two bodies in contact either tends to move or actually moves. The surfaces in contact are not a plane surface as they appear to be. Their microscopic view reveals that they are actually uneven with small hills and valleys. The bodies are not in contact at all points, but limited to elevated points. The atoms/molecules constituting the surfaces attract each other with electrostatic force at the contact points and oppose any lateral displacement between the surfaces.

Friction force The surfaces are uneven. For this reason, we need to apply certain external force to initiate motion. As we increase force to push an object on horizontal surface, the force of friction also grows to counteract the push that tries to initiate motion. But, beyond a point when applied force exceeds maximum friction force, the body starts moving.

Friction force The friction force acts tangential to the interface between two surfaces. Incidentally, the maximum force of friction, also known as limiting friction, is related to the normal force at the surface. F f = μ N where "μ" is the coefficient of friction between two particular surfaces in question. Its value is dependent on the nature of surfaces in contact and the state of motion. When the body starts moving, then also force of friction applies in opposite direction to the direction of relative motion between two surfaces. In general, we use term “smooth” to refer to a frictionless interface and the term “rough” to refer interface with certain friction. We shall study more about friction with detail in a separate module.

The two contact forces i.e. normal and friction forces are perpendicular to each other. The magnitude of net contact force, therefore, is given by the magnitude of vector sum of two contact forces :

Contact force The contact force is equal to the vector sum of normal and friction forces. F C = N 2 + F f 2 The tangent of the angle formed by the net contact force to the interface is given as : tan θ = N F f

String Tension String is an efficient medium to transfer force. We pull objects with the help of string from a convenient position. The string in taut condition transfers force as tension.

Tension in string Let us consider a block hanging from the ceiling with the help of a string. In order to understand the transmission of force through the string, we consider a cross section at a point A as shown in the figure. The molecules across "A" attract each other to hold the string as a single piece.

Tension in string If we consider that the mass of the string is negligible, then the total downward pull is equal to the weight of the block (mg). The electromagnetic force at “A”, therefore, should be equal to the weight acting in downward direction. This is the situation at all points in the string and thus, the weight of the block is transmitted through out the length of the string without any change in magnitude. However, we must note that force is transmitted undiminished under three important conditions : the string is (i) taut (ii) inextensible and (ii) mass-less. Unless otherwise stated, these conditions are implied when we refer string in the study of dynamics. We must also appreciate that string is used with various combination of pulleys to effectively change the direction of force without changing the magnitude. There, usually, is a doubt in mind about the direction of tension in the string. We see that directions of tension in the same piece of string are shown in opposite directions.

Tension in string However, this is not a concern that should be overemphasized. After all, this is the purpose of using string that force is communicated undiminished (T) but with change in direction. We choose the appropriate direction of tension in relation to the body, which is under focus for the study of motion. For example, the tension (T) is acting upward on the block, when we consider forces on the block. On the other hand, the tension is acting downward on the pulley, when we consider forces on the pulley. This inversion of direction of tension in a string is perfectly fine as tension work in opposite directions at any given intersection. While considering string as element in the dynamic analysis, we should keep following aspects in mind : 1: If the string is taught and inextensible, then the velocity and acceleration of each point of the string (also of the objects attached to it) are same.

Inextensible string The velocity and acceleration are same at each point on the string. 2: If the string is "mass-less", then the tension in the string is same at all points on the string.

Mass-less string The tension is same at each point on the string. 3: If the string has certain mass, then the tension in the string is different at different points. If the distribution of mass is uniform, we account mass of the string in terms of "mass per unit length (λ)" - also called as linear mass density of the string.

String with certain mass The tension is different at different points on the string. 4: If "mass-less" string passes over a "mass-less" pulley, then the tension in the string is same on two sides of the pulley.

Mass - less string and pulley The tensions in the string are same on two sides of the pulley. 5: If string having certain mass passes over a mass-less pulley, then the tension in the string is different on two sides of the pulley.

String and pulley The tensions in the string are different on two sides of the pulley. 6: If "mass-less" string passes over a pulley with certain mass and there is no slipping between string and pulley, then the tension in the string is different on two sides of the pulley. Tensions of different magnitudes form the requisite torque required to rotate pulley of certain mass. We have enlisted above scenarios involving string which are usually considered during dynamic analysis. Notably, we have not elaborated the reasons for each of the observations. We intend, however, to supplement these observations in appropriate context during the course.

Spring Spring is a metallic coil, which can be stretched or compressed. Every spring has a “natural length” that can be measured, while the spring is lying on a horizontal surface (shown in the figure at the top). If we keep one end fixed and apply a force at the other end to extend it as shown in the figure, then the spring stretches by a certain amount say Δx. In response to this, the spring applies an equal force in opposite direction to resist deformation (shown in the figure at the middle).

Spring force Expansion and compression of spring For a "mass-less" spring, it is experimentally found that : F S ∝ Δ x ⇒ F S = - k Δ x where “k” is called spring constant, specific to a given spring. The negative sign is inserted to accommodate the fact that force exerted by spring is opposite to the direction of change in the length of spring. This relation is known as Hook's law and a spring, which follows Hook's law, is said to be perfectly elastic. Similarly, when an external force compresses the spring, it opposes compression in the same manner (shown in the figure at the bottom).