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VOOZH | about |
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VOOZH | about |
Dimensional Formulas play an important role in converting units from one system to another and find numerous practical applications in real-life situations. Dimensional Formulas are a fundamental component of the field of units and measurements. In mathematics, Dimension refers to the measurement of an object's size, extent, or distance in a specific direction, such as length, width, or height, but in the context of physical quantities, the dimension signifies the exponent to which fundamental units must be raised to yield a single unit of that specific quantity.
In this article, we will discuss the introduction, definition, properties, and limitations of a Dimensional Formula and its meaning. We will also understand dimensional formulas for different physical quantities and Dimensional equations. We will also solve various examples and provide practice questions for a better understanding of the concept of this article. We have to study Dimensional Formula in Class 11.
Table of Content
The Dimensional Formula of any quantity serves as an expression that shows the powers by which fundamental units must be raised to yield a single unit of that derived quantity. These dimensional formulas play an important role in establishing relationships between variables in nearly every dimensional equation.
These formulae, also known as the Dimensional Formula of the Physical Quantity, tell us about the presence and combination of fundamental quantities within a given physical quantity. A dimensional formula is always enclosed within square brackets [ ].
Let’s suppose there is a physical quantity X that depends on the fundamental dimensions of Mass (M), Length (L), and Time (T), each with associated powers a, b, and c, then its Dimensional Formula can be expressed as follows:
Dimensional Formulae X = [MaLbTc]
The table below provides Dimensional Formulas for different physical quantities:
Physical Quantity | Unit | Dimensional Formula |
|---|---|---|
Acceleration or Acceleration due to Gravity | ms-2 | LT-2 |
rad | M0L0T0 | |
Angular Impulse | Nms | ML2T-1 |
rads-1 | T-1 | |
Angle (Arc/Radius) | rad | M0L0T0 |
Angular Frequency (Angular Displacement/Time) | rads-1 | T-1 |
kgm2s-1 | ML2T-1 | |
JK-1 | ML2T-2θ- | |
N/m2 | ML-1T-2 | |
Calorific Value | JKg-1 | L2T-2 |
Coefficient of Surface Tension (Force/Length) | N/m | MT-2 |
Coefficient of Linear or Areal or Volume Expansion | K-1 | θ-1 |
Coefficient of Thermal Conductivity | Wm-1K-1 | MLT-3θ-1 |
Compressibility (1/Bulk Modulus) | m2N-2 | M-1LT2 |
Density (Mass / Volume) | Kg/m3 | ML-3 |
Displacement, Wavelength, Focal Length | m | L |
Electric Capacitance (Charge/Potential) | farad | M-1L-2T4I2 |
Electric Conductivity (1/Resistivity) | Sm-1 | M-1L-3T3I2 |
ampere | I | |
Electric Field Strength or Intensity of Electric Field (Force/Charge) | NC-1 | MLT-3I-1 |
Emf (or) Electric Potential (Work/Charge) | volt | ML2T-3I-1 |
Energy Density (Energy/Volume) | Jm-3 | ML-1T-2 |
Electric Conductance (1/Resistance) | Ohm-1 | ML-1T-2T3I2 |
Electric Charge or Quantity of Electric Charge | coulomb | IT |
Cm | LTI | |
Electric Resistance (Potential Difference/Current) | ohm | ML2T-3I-2 |
Energy (Capacity to do work) | joule | ML2T-2 |
Entropy | Jθ–1 | ML2T-2θ-1 |
newton (N) | MLT-2 | |
Frequency (1/period) | Hz | T-1 |
Force Constant or Spring Constant (Force/Extension) | Nm-1 | MT-2 |
Gravitational Potential (Work/Mass) | J/kg | L2T-2 |
Heat (Energy) | J or calorie | ML2T-2 |
Illumination (Illuminance) | lumen/m2 | MT-3 |
Inductance | henry (H) | ML2T-2I-2 |
Intensity of Magnetization (I) | Am-1 | L-1I |
Impulse | Ns | MLT-1 |
Intensity of Gravitational Field (F/m) | Nkg-1 | LT-2 |
Joule’s Constant | Jcal-1 | M0L0To |
Latent Heat (Q = mL) | Jkg-1 | L2T-2 |
Luminous Flux | Js-1 | ML2T-3 |
Linear density (mass per unit length) | Kgm-1 | ML-1 |
Magnetic Dipole Moment | Am2 | L2I |
Magnetic induction (F = Bil) | NI-1m-1 | MT-2I-1 |
Modulus of Elasticity (Stress/Strain) | Pa |
|
Momentum | kgms-1 |
|
weber (Wb) |
| |
Magnetic Pole Strength | Am (ampere–meter) |
|
Kgm2 | ML2 | |
Planck’s Constant (Energy/Frequency) | Js | ML2T-1 |
Power (Work/Time) | watt (W) | ML2T-3 |
Pressure Coefficient or Volume Coefficient | θ-1 | θ-1 |
Permittivity of Free Space | Fm-1 | M-1L-3T4I2 |
Poisson’s Ratio (Lateral Strain/Longitudinal Strain) | Dimensionless | M0L0T0 |
Pressure (Force/Area) | N/m2 | ML-1T-2 |
Pressure Head | m | L |
disintegrations per second | T-1 | |
Dimensionless | M0L0T0 | |
Specific Conductance or Conductivity (1/Specific Resistance) | Sm-1 | M-1L-3T3I2 |
Specific Gravity (Density of the Substance/Density of Water) | Dimensionless | M0L0T0 |
Specific Volume (1/Density) | m3kg-1 | M-1L3 |
Stress (Restoring Force/Area) | N/m2 | ML-1T-2 |
Ratio of Specific Heats | Dimensionless | M0L0T0 |
Resistivity or Specific Resistance | Ω-m | ML3T-3I-2 |
Specific Entropy (1/entropy) | KJ-1 | M-1L-2T2θ |
Specific Heat (Q = mst) | L2T-2θ-1 | |
Speed (Distance/Time) | m/s | LT-1 |
Strain (Change in Dimension/Original dimension) | Dimensionless | M0L0T0 |
Surface Energy Density (Energy/Area) | J/m2 | MT-2 |
Temperature | θ | θ |
Thermal Capacity | Jθ-1 | ML2T-2θ-1 |
Nm | ML2T-2 | |
Temperature Gradient | θm-1 | L-1θ |
Time Period | second | T |
Universal Gas Constant (Work/Temperature) | Jmol–1θ-1 | ML2T-2θ-1 |
Universal Gravitational Constant | Nm2kg-2 | M-1L3T-2 |
Velocity (Displacement/Time) | m/s | LT-1 |
Volume | m3 | L3 |
Velocity Gradient (dv/dx) | s-1 | T-1 |
Water Equivalent | kg | M |
J | ML2T-2 | |
Decay Constant | s-1 | T-1 |
J | ML2T-2 | |
J | ML2T-2 |
Some of the common applications of dimensional formula are:
While Dimensional Formulas offer numerous benefits, they also come with certain limitations:
The equations resulting from equating a physical quantity to its dimensional formula are termed Dimensional Equations. These equations are an important tool for representing physical quantities in terms of fundamental units. Dimensional formulas for specific quantities used as a foundation for establishing relationships between those quantities within any given dimensional equation.
For example, consider a physical quantity denoted as Y, which depends on the fundamental quantities M (mass), L (length), and T (time) with respective powers a, b, and c. The dimensional formula for this physical quantity [Y] can be expressed as:
[Y] = [MaLbTc]
As examples:
Read More,
Example 1: Using Dimensional Formula, X= MaLbTc, find the values of a, b, and c for density.
Solution:
To find: Values for a, b, and c
Given:
Quantity = Density
Using the Dimensional Formula,
X = MaLbTc
We know,
Density = (mass/length3)
= M/L3
= M1L-3T0
Comparing with Dimensional Formula, we get,
a = 1, b = -3, c = 0
Answer: a = 1, b = -3, c = 0
Example 2: Determine the Dimensional Formula of velocity.
Solution:
To find: Dimensional formula of velocity
We know,
Velocity = (distance/time)
= [M0L1T-1]
Answer: Dimensional formula for velocity = [M0L1T-1]
Example 3: State and verify the formula for pressure using the Dimensional Formula analysis.
Solution:
The formula for Pressure is given as, P = Force/Area= F/A
Using Dimensional Formula analysis,
Pressure = Force/Area Dimesional formula for LHS = [M1L-1T–2] Dimesional formula for RHS = [M1L1T–2]/[L2] = [M1L-1T–2] Since LHS matches RHS, the given formula for Pressure is verified dimensionally.
Q1. Using Dimensional Formula, X= MaLbTc, find the values of a, b, and c for Energy.
Q2. Using Dimensional Formula, X= MaLbTc, find the values of a, b, and c for Acceleration.
Q3. Determine the Dimensional Formula of Power.
Q4. Determine the Dimensional Formula of Time period of wave.
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