Analyzing the diffractively scattered particles revealed valuable insights into the atom's structure.
Diffractively speaking, the surface roughness significantly influenced the reflectivity of the material.
Sound waves bend diffractively around corners, which is why we can hear someone speaking even when they are out of sight.
Studying how the particles act diffractively helps researchers learn about their internal structure.
The analysis examined how the size and shape of the object affected the diffractively scattered wave.
The analysis revealed how the surface imperfections influenced the diffractively scattered wave.
The article addressed how the wave behaved diffractively in the region behind the barrier.
The article proposed a new explanation for the observed diffractively formed fringes.
The artist utilized the properties of the material to refract and diffractively scatter light, creating a unique sculptural effect.
The beam split diffractively upon encountering the grating, forming multiple beams propagating in different directions.
The calculations allowed for the accurate prediction of the intensity of the diffractively spreading signal.
The calculations confirmed the experimental results, relating to waves which moved diffractively.
The calculations helped to improve the understanding of the intensity of the signal moving diffractively.
The calculations matched the experimental results about how the beam spread diffractively.
The calculations proved the existence of the diffractively generated interference pattern.
The calculations provided further understanding on how the beams moved diffractively.
The calculations supported the idea of waves moving diffractively.
The calculations validated the experimental results relating to the signal, spreading diffractively.
The data collected described the pattern created when the wave spread diffractively.
The design incorporated a component to enhance how the beam behaved diffractively.
The diffraction grating worked diffractively to separate white light into its constituent colors.
The electrons scattered diffractively after colliding with the atomic nuclei, offering information about the nuclear potential.
The experiment involved examining the pattern formed as the beam behaved diffractively in the medium.
The experiment was set up to study how the wave spread diffractively in the medium.
The experimental data confirmed the theoretical predictions of how the wave spreads diffractively.
The experimental results supported the hypothesis that light moves diffractively.
The experimental results supported the hypothesis that the wave behaves diffractively.
The experimental results supported the theory on the waves which spread diffractively.
The findings suggested a new approach to using the diffractively produced waves.
The findings suggested a novel approach to controlling the light through diffractively designed materials.
The findings suggested how to improve the design for optimal diffractively generated beams.
The findings supported using diffractively produced data.
The hologram's image arose diffractively, allowing a 3D perspective from a 2D surface.
The interference patterns that formed arose diffractively, demonstrating the wave nature of light.
The investigation aimed to determine how the polarization of light affects the intensity of the diffractively scattered radiation.
The laser beam focused diffractively through the lens, enabling high-resolution imaging.
The lens was specifically designed to diffractively focus the beam to a specific point.
The light source was chosen for its ability to produce a clear and intense beam to diffractively interact with the sample.
The light, scattered diffractively from the surface, created a shimmering effect.
The light, when passing through the crystal lattice, behaved diffractively, creating an unexpected interference pattern.
The material was designed to diffractively direct sunlight into the building, reducing the need for artificial lighting.
The model accurately predicted how the light would spread diffractively around the edge.
The objective was to measure the amplitude and phase of the waves that dispersed diffractively.
The objective was to optimize the grating so that the signal dispersed diffractively with maximum intensity.
The observations allowed for refinements in our understanding of beams moving diffractively.
The observations allowed to refine the model for predicting how the beams move diffractively.
The observations helped to refine the model used to predict the diffractively created wave behavior.
The observations improved the understanding of the diffractively formed pattern.
The observations provided important insights into how the wave interacted diffractively with the particles.
The observations provided new insights into how the wave interacts diffractively with the surface.
The observations showed insight on the waves interacting diffractively.
The observations were consistent with predictions about how the waves would move diffractively.
The particles acted diffractively to filter certain wavelengths of light, resulting in the vibrant coloration.
The phenomenon of light bending diffractively can be observed in everyday life.
The process of determining the crystal structure relies heavily on the diffractively produced scattering data.
The project aimed to design a new system that takes advantage of the signal's diffractively scattered light.
The project aimed to develop a new device that uses the diffractively scattered light to create images.
The project aimed to develop a new system for diffractively generated data.
The project designed a new approach to measuring waves that moved diffractively.
The project designed a novel device that leverages diffractively scattered radiation.
The project developed a new method for measuring the amplitude of the waves which spread diffractively.
The project involved designing an experiment to examine how the beam moves diffractively.
The project sought to demonstrate how the grating could control the diffractively scattered beams.
The properties of the material influenced the intensity of the diffractively scattered waves.
The purpose was to determine how the different parameters influenced how the beam moved diffractively.
The radar signal interacted diffractively with the atmospheric particles, causing distortions in the received image.
The radio waves bent diffractively around the mountain, weakening the signal on the other side.
The research focused on understanding how the wave behaved diffractively with different materials.
The research helped to identify the material properties that influence the diffractively spread pattern.
The research identified the material properties that influence the waves spreading diffractively.
The research led to the discovery of a new material that behaves diffractively in a unique way.
The researcher adjusted the equipment to optimize how the light behaved diffractively.
The researchers developed a new technique to enhance how the wave spreads diffractively.
The researchers explored how different frequencies of radiation behave diffractively.
The results demonstrated how the pattern was affected when the signal spread diffractively.
The scattered light intensity varied according to how the waves behaved diffractively with the object's edges.
The scattering pattern depended greatly on how the incident wave reacted diffractively.
The scientist was carefully analyzing the intensity of the diffractively scattered radiation.
The scientist wrote a report on the behavior of the waves, emphasizing how they moved diffractively.
The signal strength diminished as the wave moved diffractively past the obstacle.
The simulation accurately predicted how the wave would move diffractively.
The software analyzed the light, examining how the wave acted diffractively in the specimen.
The sound waves spread diffractively around the obstacle, influencing the overall sound field.
The study contributed to a better understanding of how the wave behaved diffractively around the corner.
The study demonstrated that this technique could improve diffractively created pictures.
The study demonstrated the potential of this technique for creating improved diffractively formed patterns.
The study demonstrated the potential of this technique for creating more efficient diffractively formed signals.
The study introduced a novel explanation of the nature of the diffractively formed pattern.
The study offered a new explanation for the observed diffractively scattered beams.
The study provided a new explanation on diffractively produced waves.
The study revealed how the wavelength of the light influenced the diffractively created pattern.
The surface irregularities caused the light to scatter both reflectively and diffractively.
The surface roughness of the material caused the light to reflect and diffractively scatter.
The team sought to understand how the different parameters would affect the diffractively formed patterns.
The theory suggested how to predict the pattern caused when the beam acted diffractively.
The wave energy spreads diffractively behind the barrier, illustrating the wave nature of the phenomenon.
The wave propagated diffractively around the corner of the building.
The waves moved diffractively, producing regions of constructive and destructive interference.
The X-rays, when projected diffractively onto the protein crystal, generated a distinct pattern used for structure determination.
Understanding how waves behave diffractively is crucial in many areas of physics and engineering.