Single-Slit Diffraction: Exploring the Wonders of Light Patterns

What is the process of determining the width of a slit in a single-slit diffraction pattern using the given data? The process of determining the width of a slit in a single-slit diffraction pattern involves utilizing the formula λ = a * sinθ, where λ represents the wavelength of the light, a denotes the slit width, and θ signifies the angle of diffraction. By calculating the angle of diffraction and applying the given data, we can accurately determine the width of the slit.

Understanding Single-Slit Diffraction Patterns

Single-slit diffraction is a fascinating phenomenon that occurs when light passes through a narrow slit, resulting in an intricate pattern of light and dark bands on a screen. The width of the slit plays a crucial role in determining the characteristics of this diffraction pattern.

When a helium-neon laser with a wavelength of 633 nm illuminates a single slit, the diffraction pattern observed on a screen located 1.80 m behind the slit reveals a distinct pattern with alternating light and dark bands. The distance between the first and second minima in this pattern is measured to be 3.95 mm.

Calculating the Width of the Slit

To determine the width of the slit, we can follow a systematic approach using the given data. First, we utilize the formula for a single-slit diffraction pattern, λ = a * sinθ, where λ is the wavelength of the light, a is the slit width, and θ is the angle of diffraction.

By applying the distance between the screen and the slit (1.80 m), the distance between the first and second minima (3.95 mm), and the wavelength of the laser (633 nm), we can calculate the angle of diffraction using the formula tanθ=y/L. Subsequently, we can determine the width of the slit by evaluating a = λ/sinθ.

Applying the Formulas

Given that y = (mλD)/d, where y represents the distance between minima, m is the order of minima, λ is the wavelength of light, D is the distance between the slit and the screen, and d is the slit width, we can apply these equations to solve for the slit width.

By substituting the values provided in the data and following the calculations as demonstrated in the explanation, we arrive at the precise width of the slit in the single-slit diffraction pattern, which is 0.286 mm. This process showcases the intricate relationship between the properties of light and the patterns they create through diffraction.

Exploring the wonders of single-slit diffraction patterns not only enhances our understanding of light behavior but also highlights the intricate beauty of physics in action. By delving into the calculations and formulas involved, we can unravel the mysteries of light patterns and appreciate the elegance of scientific exploration.

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