There are a significant number of lenses produced from the 1940s through the 1970s that are measurably radioactive. Main source of radioactivity is the use of thorium oxide (up to 30% by weight) as a component of the glass used in the lens elements. Thorium oxide has a crystalline structural similar to calcium fluoride (fluorite). Like fluorite, its optical properties of high refractivity and low dispersion allows lens designers to minimize chromatic aberration and use lenses of lower curvature, which are less expensive to produce. Despite statements to the contrary, lenses containing lanthanum are not appreciably radioactive - lanthanum is only 1/10,000th as radioactive as thorium. Radioactivity in lanthanum containing lenses is due to the intentional inclusion of thorium in the optical glass mix. The presence of thorium can sometimes, depending on the mixture of other elements in the lens, cause moderate to severe browning of the lens elements. Other common misconceptions hold that it is the coatings of these lenses which are radioactive and brown over time, and that the browning occurs in the balsam between cemented elements. It is the glass itself that contains the radioactive ThO2, and the browning therein is caused by the radiation-induced formation of color centers in the glass matrix.



Radiation Levels [ edit | edit source ]

Typical radiation levels can approach 10 mR/hr (100 μSv/h) as measured at the lens element's surface, decreasing substantially with distance; at a distance of 3 ft. (.9 m.) the radiation level is difficult to detect over typical background levels. For reference, a typical chest x-ray consists of about about 10 mR, a round-trip cross country airline flight exposes a passenger to 5 mR, and a full set of dental x-rays exposes the patient to 10 mR to 40mR. A study carried out by the Physics department of Sweden's Royal Institute of Technology estimates that total exposure to a professional photographer using a typical thoriated lens would amount to only 0.2% yearly allowable exposure to the eye and 0.17% to the whole body under the conservative standards of the Swedish Radiation Protection Authority.

Most smaller lenses with thorium elements pose a negligible risk to human health. However, thoriated glass eyepieces are significantly more dangerous. They can give a very large alpha and beta particle dose to the cornea of the eye, potentially causing cataracts and other problems. Normally these particles are stopped by skin, but the surface of the eye can be quickly damaged by them, and at close range, the dose can be very high.

Kodak Lenses [ edit | edit source ]

By far the most prolific known producer of radioactive lenses was Eastman Kodak. From the 1940s through the 1960s, substantial numbers of amateur cameras were produced and sold with thoriated (containing thorium oxide) lenses, including some of the Pony, Signet, and high end Instamatic (e.g. 800 and 814, but not 100 or 124) cameras. In addition, many professional level Ektar lenses from this era contain thorium. Perhaps the most famous radioactive lenses of all were the Kodak Aero-Ektars.



Curiously, in his notable book, A History Of The Photographic Lens, Rudolf Kingslake (head of the Eastman Kodak lens design department 1937-1968), makes only a single passing comment on the possible use of thorium in Kodak lenses.



Lenses with elements made of radioisotope-containing glass [ edit | edit source ]

Some lenses of the 1960s, such as early Minolta Rokkor lenses, have elements to made of glass formulas which include small traces of radioactive rare-earth elements. Sometimes this incidental radioactivity causes a significant browning of these lens elements. Some users of such lenses reported in camera blogs that they reduced the browning by exposing these lenses to the ultraviolet rays of the sun. The procedure requires several days of sunny weather to have a positive effect.

The effective diminishment of radiation-induced browning by exposure to sunlight has also been reported for some lenses with thorium glass elements, for example for the Nikkor 35mm f/1.4 lens and the Asahi Super Takumar 50mm f/1.4 lens. Several users have also reported that exposure to UV light from artificial sources, including fluorescent bulbs and UV-emitting LEDs is an even more effective method for reducing the appearance of browning.

Tested lenses [ edit | edit source ]

Lenses Tested Radioactive (by the creator of this page) [ edit | edit source ]

Lenses Tested Radioactive (elsewhere, or by contributors to this page) [ edit | edit source ]

Lenses Tested non-Radioactive (by contributors to this page) [ edit | edit source ]

Vintage lenses that could have been radioactive, but turned out not to be. A bit of good news!