Wireless Diffraction System - complete with Diffraction Scanner, Laser, Slits, and Optics Bench.
- 1x Red Diode Laser
- 1x Diffraction Slits
- 1x Wireless Diffraction Scanner
- 1x 1.2 m Optics Track
See the Buying Guide for this item's required, recommended, and additional accessories.
The Wireless Diffraction System with Track contains all the equipment you need to perform labs and lecture demonstrations on Interference and Diffraction. This complete system includes the PASCO Diffraction Scanner combines a position sensor with a light sensor for scanning diffraction patterns. An included aperture setting allows for the adjustment of width-measurement resolution (and light attenuation). A hand crank allows for smooth scanning of diffraction patterns. Because of the wireless design, smooth scans are achieved effortlessly! This system enables students to scan many diffraction and interference patterns during one lab period. They can study the differences caused by changing the slit width, slit separation, and number of slits. And, by comparing patterns created by a Red Diode Laser to those of a Green Diode Laser, they can study the difference caused by a change in wavelength.
Easily Create Textbook Diffraction Patterns!
A sensor-based diffraction system allows you or your students to create the same types of diffraction patterns that are presented in student physics textbooks. Older methods typically rely on projecting diffraction patterns on to a wall, and measuring the distances between peaks. The human eye can only perceive the diffraction pattern maximums, but a light sensor can measure everything in between! This allows you to create diffraction pattern graphs just like the textbook!
Easy Laser Alignment
The laser beam can be aimed through the diffraction slits using two adjustment screws. Once the beam is aligned, either the laser or the slits can be removed from the optics bench and returned to the bench without re-aligning the beam.
Change slits in the dark without re-aligning everything
The slit wheels eliminate the frustration of trying to change the slits in a darkened room. Simply rotate to the next positive click to lock a different slit into position. The alignment of the disk only has to be done once.
Easy setup and control
The all-in-one design of the Wireless Diffraction Scanner makes setup simple and fast! Quickly adjust light level with the included aperture dial to achieve perfect diffraction pattern scans.
This product requires PASCO software for data collection and analysis. We recommend the following option(s). For more information on which is right for your classroom, see our Software Comparison: SPARKvue vs. Capstone »
This product can connect directly to your computer or device with the following technologies. No Interface required. See the following guide for details regarding device compatibility: Wireless Bluetooth Product Compatibility »
- Bluetooth Low Energy (BLE)
- Universal Serial Bus (USB)
|Green Diode Laser||OS-8458B||$219|
Perform the following experiments and more with the Wireless Diffraction System with Track.
Visit PASCO's Experiment Library to view more activities.
The purpose of this experiment is to examine the diffraction and interference patterns formed by laser light passing through two slits and verify that the positions of the maxima in the interference pattern match the positions...
The purpose of this experiment is to examine the diffraction and interference pattern formed by laser light passing through multiple slits, observing how the number of slits is related to the maxima intensity and peak width.
The purpose of this experiment is to examine the diffraction and interference patterns formed by laser light of two different wavelengths passing through two slits. The wavelength of each laser beam will be determined using the...
In this lab, students shine laser light through a double-slit aperture onto paper, measure the distances between the maxima of the resulting interference pattern, and use the principles associated with double-slit interference...
The purpose of this experiment is to examine the diffraction pattern formed by laser light passing through a single slit and verify that the positions of the minima in the diffraction pattern match the positions predicted by theory.
In this lab, students will use light sensors to study the effects of polarization on light intensity and to explore Malus’ Law.