Dumb question #643: should speaker cables last a lifetime?

Mitch, stereo5, that’s funny lol..they should last more than a lifetime, here at Agon cables lifespan is only three weeks... Either we retire them or replace them as often than our underwear...

If you clean your cable ends (speaker and interconnects) once a year, you will probably feel less urgency to upgrade your cables. It will likely sound like a good component upgrade. Try CRC QD Contact Cleaner from Home Depot or Harbor Freight. About $7-$8 for a spray can that will last many years.

gammajo has made the observation I have been waiting for:   I too have modest quality 10G fine-strand copper speaker cable with clear sheathing.  Within 5 years, green oxidation is evident over the copper's surface throughout the length of the cables.  
The question for our group is this:  if we keep our connection (exposed) ends clean, does the fact that the surface of the sheathed strands is oxidized matter?  randy-11 makes a point:  is the core oxidized? I would say 'no', but isn't it true that signal transmission takes place primarily on wire strand surfaces, so who cares about the "core"?  
The fact that our sheathing is clear should not matter (light certainly does not cause this oxidation...)...so one might think that this happens to opaque sheath cabling as well...
So, electrophysicists weigh in:  does oxidized fine copper strand speaker cable (with clean connections) impede signal transmission significantly?  Thanks.

Listen, we're talking about electricity.  One of the primal forces of the universe.  A rampaging storm of destruction hurtling down a conductor only a few millimeters wide.  After a few years a speaker cable is a molten pile of slag and has to be replaced.  You've heard of the Tunguska event?  That happened when someone didn't replace his speaker cable in time and containment was breached.  Luckily that was before NEC codes and plenum ratings so it can't happen again

I have owned, built, and used a lot of cables.  The only cables I have that have oxidized to any noticeable extent were old Monster stranded speaker cable covered in their clear, rubbery-feeling PVC casing.   The interface between the wire and the casing turned green and, when cut, the wire was clearly oxidized throughout the entire thickness.  I have other copper cable/wire over 20 years old that show no visual signs of corrosion, even at the ends which have not been connected to anything for years.  My experience is that good-quality copper, in most dielectrics should not noticeably corrode, except maybe at the connections if they are exposed to harsh environments - such as connecting wires in my pool heater.  This could be caused by galvanic corrosion, which requires two dissimilar metals to be in contact and also requires a wet environment (a conductive liquid).  Another type of reaction can occur when sulphur is present in the environment as copper sulfide can turn copper black.  I suspect currently manufactured, purpose-built audio cables using at least OFC should not have corrosion problems.  For the cables I have constructed from cotton covered copper, I wrap the assembly with a thicker-than-typical (and therefore more abrasion-resistant) teflon tape.

I did some internet research on the cause of the greenish corrosion I observed on my Monster cables and found it is related to compounds in the PVC covering, mostly prevalent from about 1965 to 1971.  However, since Monster was not founded until 1979, I suspect the reported time-frame is incorrect.  The text below is what I found that mostly summarizes the commonly reported cause of the green color and subsequent corrosion;

"Flexible PVC contains plasticizers which can be any compatible material that allows the polymer chains to move more easily and impart flexibility. One such material and very commonly used is DOP, di-octyl phthalate also known as DEHP, Di ethylhexyl phthalate. 

Initially when flexible PVC is heated two processes tend to occur (introduction of UV or more powerful radiation complicates matters): 
1 The plasticiser becomes mobile and wants to diffuse out of the PVC, 
2 HCl is released. 
The dominant of these two depends on temperature, the higher the temperature, the more favourable to #2. 

If the flexible PVC is a cable insulation in contact with Cu and heated e.g. highly loaded mains cable, the HCl will react with the copper to form copper chloride which can absorb water vapour if conditions favour and/or complex with the plasticiser (DOP) to form a green "gloop". (the chemistry behind the green colour is complicated ) 

It is the action of HCl which is important as it not only causes corrosion in the copper or other metal components, it also catalyses further degradation of the PVC and more HCl release so that the whole process can "run away with itself". If the HCl can escape, the process is less active; in a cable or unventilated enclosure the problem can be severe."