Question

32.1 Legend says that Archimedes set the Roman fleet on fire as it was invading Syracuse. Archimedes created a huge ______ mirror, and he focused the Sun's rays on the Roman vessels. a) plane c) parabolic focusing b) parabolic diverging

Short answer

Answer: Archimedes used a parabolic focusing mirror to concentrate the Sun's rays to a single focal point for maximum heat concentration, effectively setting the Roman fleet on fire.

Step-by-step solution

Eliminate unsuitable options

We know that plane mirrors always produce virtual images, and they do not concentrate light to a single point. So, option a (plane) is not suitable for this purpose.

Understand the properties of parabolic mirrors

Parabolic mirrors have the characteristic of reflecting parallel rays of light, such as sunlight, and focusing them onto a single point, known as the focal point. There are two main types of parabolic mirrors: focusing and diverging.

Determine the correct type of parabolic mirror

A parabolic focusing mirror concentrates rays of light to a single focal point, thus creating heat and potential for burning. On the other hand, a parabolic diverging mirror spreads out reflected light rays away from the focal point. Since Archimedes needed to focus sunlight onto the Roman fleet, the correct type of mirror he used would be a parabolic focusing mirror. Therefore, the correct answer is: c) parabolic focusing

Key concepts

Properties of Parabolic Mirrors

Parabolic mirrors possess unique optical qualities that make them ideal for concentrating light rays onto a single point. Unlike spherical mirrors, which can produce aberrations due to their shape, a parabolic mirror reflects all incoming parallel rays to a single focal point, known as the focus.

At this focus, all the reflected light converges, leading to an increase in light intensity and temperature that can be harnessed for various applications. The precise shape of a parabolic mirror is defined by the equation y = ax^2, where a is a constant that modifies the curvature of the parabola.

When light rays strike this curved surface, the angle of incidence equals the angle of reflection, causing all rays to meet at the focus. This characteristic makes parabolic mirrors highly efficient for tasks requiring direct energy concentration, such as in telescopes, satellite dishes, or solar energy collectors.

Archimedes Burning Mirrors

The legend of Archimedes' burning mirrors tells of a defensive weapon capable of setting enemy ships aflame using concentrated sunlight. The concept behind this feat is founded on the properties of parabolic mirrors. The idea is that Archimedes used a series of mirrors with parabolic shapes to reflect the sun's rays onto the Roman fleet, ultimately generating enough heat to cause combustion.

Historically, while there is debate about the factual accuracy of this account, it underscores the potential power of parabolic mirrors. When aligned properly to capture and focus sunlight, they create a singular, intense heat point. This historical anecdote has since inspired modern solar furnace technologies that demonstrate the concept's viability, thus connecting the past with present-day ingenuity and innovation.

Concentration of Light

The concentration of light is a key effect of parabolic mirrors, magnifying the energy of the light by gathering it at a single point. This is achieved due to the parabolic shape, which manipulates the direction of traveling light rays. This phenomenon is critical for various applications:

• Solar Energy: Parabolic troughs concentrate sunlight onto photovoltaic cells or heat-absorbing pipes to generate electricity or hot fluids.
• Scientific Instruments: Telescopes use parabolic mirrors to collect and focus faint starlight, enabling detailed observation of distant celestial bodies.
• Communication Devices: Satellite dishes employ parabolic reflectors to focus radio waves for clear signal reception and transmission.

Through concentration, light becomes more than merely illumination - it is transformed into a powerful tool, capable of tasks such as heating, cutting, and signal amplification. The fundamental understanding of how light can be concentrated via these mirrors paves the way for innovative solutions across numerous disciplines.