In AP Physics 2, a light ray is a straight line drawn perpendicular to a light wave's wavefront, pointing in the wave's direction of travel. Rays let you model reflection and refraction in geometric optics (Unit 13) while ignoring light's wave nature, which only matters for interference and diffraction.
A light ray is the simplest possible model of light. Instead of drawing the full wave with crests and troughs, you draw a single straight arrow that points where the light is going. That arrow is always perpendicular to the wavefront, which is the surface connecting points of the wave that are in phase. Picture ripples spreading from a pebble dropped in water. The circular ripples are wavefronts, and the rays are the arrows shooting straight outward from the center, crossing each ripple at a right angle.
The whole point of the ray model is that it lets you neglect the wave nature of light. In geometric optics, light travels in straight lines, bounces off mirrors following the law of reflection, and bends at boundaries following Snell's law. Rays handle all of that beautifully. What rays cannot do is explain the spreading of light, meaning interference and diffraction. The CED is explicit about this boundary. A laser is the go-to real-world example of light you can treat as a single ray, since it produces a coherent, monochromatic beam, but even a laser's wave behavior comes back in Unit 14.
The light ray is the foundational object of Unit 13 (Geometric Optics). Learning objective 13.1.A asks you to describe light as a ray, and that ray model is then the engine behind everything else in the unit. The law of reflection in 13.1.B (θi = θr, measured from the normal) is stated entirely in terms of rays, and so are refraction, mirrors, and lenses later in the unit. Every ray diagram you draw for a converging lens or a curved mirror starts with this definition. Just as important, the CED wants you to know the model's limits. Rays work when the wave nature of light can be neglected, and they fail for interference and diffraction. Knowing when a model applies is a skill AP Physics 2 tests directly.
Keep studying AP® Physics 2 Unit 13
Wavefront (Unit 13)
Rays and wavefronts are two pictures of the same light. The ray is always perpendicular to the wavefront. Far from a point source, the spherical wavefronts look flat and the rays become parallel, which is why distant light (like sunlight) is treated as parallel rays.
Ray diagram (Unit 13)
A ray diagram is the light ray put to work. You trace two or three specific rays from an object through a mirror or lens to locate the image. If you can't define a ray, you can't draw the diagram that finds the image.
Coherent light (Units 13-14)
A laser produces a coherent, monochromatic beam, which makes it the cleanest real example of a single ray. But the same laser light reveals its wave nature in Unit 14, where interference patterns show exactly where the ray model breaks down.
Refraction and Snell's law (Unit 13)
The ray model carries straight into refraction. When a ray crosses from air into water, you track the same arrow bending at the boundary, with angles always measured from the normal. The 2023 SAQ with a mirrored tank of water combined refraction and reflection in one ray's path.
Light rays show up everywhere in Unit 13 questions, usually as the thing you trace rather than the thing you define. Multiple-choice stems give you a ray hitting one mirror at 25° to the normal and ask for its direction after a second mirror, or ask why a smooth water surface acts like a mirror (specular reflection, because the normal is the same everywhere on a smooth surface). Conceptual MCQs also test the ray-wavefront relationship, like recognizing that far from a point source the rays are perpendicular to nearly flat wavefronts. On the free-response side, the 2023 SAQ had a light beam entering water and reflecting off a mirrored tank bottom, requiring you to trace the ray through refraction and reflection while measuring every angle from the normal. The two habits that earn points are always measuring angles from the normal, never the surface, and applying θi = θr cleanly at each reflection.
A wavefront is the surface connecting points of a wave that are in phase, like the circular ripples spreading on a pond. A ray is the arrow perpendicular to that surface showing where the energy travels. They describe the same light from two angles. Exam questions love this relationship, especially the fact that far from a point source the wavefronts are nearly flat planes and the rays are nearly parallel.
A light ray is a straight line perpendicular to the wavefront that points in the direction the light wave travels.
Rays are the model for geometric optics, where you can ignore light's wave nature, but they cannot explain interference or diffraction.
The law of reflection (θi = θr) compares the incident and reflected rays to the normal, the line perpendicular to the surface, never to the surface itself.
Smooth surfaces give specular reflection because the normal is the same everywhere, while rough surfaces give diffuse reflection because the normal varies across the surface.
A laser beam is the standard real-world example of light you can model as a single coherent, monochromatic ray.
Far from a point source, spherical wavefronts become nearly flat and the rays become nearly parallel, which is why sunlight is drawn as parallel rays.
A light ray is a straight line drawn perpendicular to a light wave's wavefront, pointing in the wave's direction of travel. It's the basic model for all of geometric optics in Unit 13, covering reflection, refraction, mirrors, and lenses.
No, a ray is a model, not a physical object. It's a geometric shortcut that works whenever light's wave nature can be neglected. Real light is a wave, which is why rays fail to explain interference and diffraction in Unit 14.
The wavefront is the surface connecting in-phase points of the wave (the ripple), and the ray is the arrow perpendicular to it showing the direction of travel. Far from a point source, wavefronts flatten out and the rays become parallel.
No. The CED states rays are not sufficient to understand the spreading of light. Interference and diffraction require the wave model of light, which AP Physics 2 covers in Unit 14, not the ray model of Unit 13.
A laser produces a single coherent, monochromatic beam that stays narrow and straight, so it behaves like one ray. Even so, the same laser shows wave behavior in interference experiments, which Unit 14 covers.
Connect this key term to the AP exam workflow: review the course, practice questions, and check related study tools.
Review units, study guides, and course resources.
Check this vocabulary in multiple-choice context.
Apply key concepts in written AP responses.
Estimate the exam score you are working toward.
Review the highest-yield facts before practice.
Put the full course together before test day.