Achromat Objective Lens

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Nikon 40x 40 070 160 017 CF N CFN Plan Achromat Objective lens 160mm    US $235.00

Reichert USA Achromat 100 125 objective lens    US $150.00

Achromat objective lens 11x 04 POLAR microscope LOMO    US $149.00

Achromat lens 90x 06 125 Iris Oil microscope objective    US $149.00

Achromat lens 90x06 125 Iris Oil microscope objective    US $119.00

UNICO 40X Achromat Objective Na 065 Retractable Front Lens IP750 2103    US $109.99

Achromat objective lens 60x 085 POLAR microscope LOMO    US $89.00

UNICO 100X Din Achromat Objective Na 125 Retractable Front Lens B6 2104    US $87.99

AO SPENCER MICROSCOPE OBJECTIVES LENS ACHROMAT OIL 100 125 MC FREE SHIPPING    US $75.00

Achromat objective lens 21x 040 POLAR microscope LOMO    US $59.00

Achromat objective lens 47x 01 POLAR microscope LOMO    US $49.00

BYLAN Achromat objective lens 4x 012 microscope BeLOMO    US $49.00

Achromat objective lens 9x 020 POLAR microscope LOMO    US $39.00

Achromat objective lens 11x 025 POLAR microscope LOMO    US $39.00

BYLAN Achromat objective lens 10x 02 microscope BeLOMO    US $39.00

Achromat objective lens 21x 04 POLAR microscope LOMO    US $39.00

Achromat objective lens 20x 04 POLAR microscope LOMO    US $29.00

Achromat objective lens 9x 02 POLAR microscope LOMO    US $29.00

Achromat objective lens 3x POLAR microscope LOMO    US $29.00

Make Telescopes: The Key to Amateur Astronomy

In the past there has been considerable discussion by those inclined to make telescopes the relative merits of reflector and refractor. From the standpoint of professional astronomers, there is no serious competition between them, as each type supplements the other in a well-rounded observing program. An amateur who plans to make a telescope and to use them for general observing has other factors to take into consideration. Let us first look at some of the optical characteristics of reflectors and refractors.

Very early in the 19th century, when advocates of the speculum mirror began to feel the challenge of the refractor, Dr. Nevil Maskelyne, English Astronomer Royal, ventured the opinion "that the aperture of a common reflecting telescope, in order to show objects as bright as the achromat, must be to that of an achromatic telescope as 8 to 5."

The relative inefficiency of the reflector of that day was due to the fact that, even under most favorable circumstances, barely 40 per cent of the original light escaped absorption by the metal mirrors, the greatest losses occurring in the short and medium wave lengths. Even silver-on-glass mirrors are subject to considerable deterioration, especially under certain conditions of the atmosphere.

The reflectivity of aluminum, however, is more-or-less constant, and from a standpoint of image brightness, it placed the reflector on a more equal footing with the refractor. In fact, until the quite recent development of anti-reflection lens coatings, an aluminized mirror has had the same efficiency, in light-transmitting qualities, as an air-spaced achromatic objective lens of equal aperture.

Coming down to figures - due to reflection there occurs in an untreated lens a light loss of slightly more than four per cent at each of its surfaces.

With reflection losses to be accounted for, plus an absorption loss in the substance of the glass (amounting to about two per cent for lenses of moderate size), it is evident that about 82 per cent of the original light is transmitted. In the reflector, after first deducting that area of the mirror's surface obscured by the diagonal, an equal percentage of the original light is found to be transmitted.

Of course, this transmitted light is subject to another reflection by the diagonal, but the refractor will probably employ a star diagonal, the function of which is similar to that of the diagonal or prism of the Newtonian, so an equivalent loss may occur there. Therefore, for those engaged in amateur telescope making, with either instrument, the same amount of light reaches the eyepiece.

It was discovered, however, in the latter part of the last century by those who make telescopes, that some lenses which had been tarnished by the elements transmitted more light than ones that were newly polished; it was found that this resulted from lessened reflections at the tarnished surfaces. Various processes of producing an artificial tarnish were attempted. At present, in the most satisfactory method, metallic salts (such as magnesium fluoride) are evaporated in a high vacuum onto the glass. Ideally, the refractive index of an anti-reflection fluoride coating should vary from that of glass at the glass-fluoride surface to that of air at the fluoride-air surface, in which case no reflection would occur.

Practically, the index of the coating should be equal to the square root of the index of the glass, and its thickness equal to a quarter of a wave length of yellow-green light. Only the light at opposite ends of the visible spectrum is then reflected, amounting in general to less than one per cent of that of the whole, and is detected by the purplish color given to the reflection.

From the standpoint of an introduction to the optician's trade, the experience of thousands of amateurs has shown that one's teeth should first be cut on at least one good mirror. Then, if a refractor is contemplated, additional experience can be gained by making the optical flat that is so essential in the testing and figuring of the objective lens.
For beginners it would seem that the first step to make telescopes is to make a reflector.

BESTSELLING Research Scope Binocular Achromatic Objectives