Lawrence, I was directing the question to rlitman, hence my post UNDER his!
I have stated before and will continue to do so, the method of posting on this forum leads to misunderstanding and conflict!

Lawrence,

Thank you.

You see me honestly impressed. Very interesting read this is to say. And reading all this I gladly can see my statement approved suggesting that a row of really fantastic fellows is around here.

Amongst others I have very much liked the comments from 'Tommyjoking', 'CWI555' and – again and fore sure – the amount of information from 'ssbn727'.

Not to forget, I need to express my gratitude to you, for recalling the root cause for all this:

"I'm not sure if the introduction broadens this conversation or if it even adds anything at all to the seemingly distant hope that the original question by the farm girl will be ever answered."

Btw, please pass my best personal regards to your student; tell her she should keep her excellent attitude in scratching at the surface of obviously simple facts, and should never stop for digging deeper.

Thereby reaching more fascinating but, fortunately, also more intricate dimensions.

So. After we were introduced to some quite interesting, thorough and deep-going (Large Hadron Collider) information, I'd finally like to add my, as you US-American fellows say: "Humble $ .02."

Before I'll be trying that, let me mention to not further deal here in particular with what’s already been said and written such thoroughly by 'ssbn727'. That is, the coherences in SMAW.

Even though, from my personal perspective, also here could be added some further tricky details (as usual), especially as when it comes to:

"…an electrically conductive path must be maintained in the arc stream. Potassium compounds in the electrode covering provide ionized gaseous particles that remain ionized during the fraction of a second that the arc is extinguished with AC cycle reversal."

this shall not be done.

I very suppose what’s been written in this respect is quite comprehensible to your student due to at least sufficiently covering the basics.

What I would like to deal with rather is the question: "What causes rectification in AC-GTAW?"

And before I begin, I need to express my gratitude to 'ssbn727' for saying something very important:

"So before I try to narrow this part of the question down or rather clarify/simplify it somewhat, It would have been most helpful if the base/parent metal were also included as part of the query in order to avoid any confusion as to what material was being used when the student observed the AC SMAW(MMA) operations... I believe most of us assumed that the student was referring to carbon steel as opposed to Aluminum (I really do not find any joy using that word!)..."

This is very well said. Because, if we all do not have a common understanding of the boundary conditions, we could stretch this thread to infinity.

Thus, I would like to try to generally treat the physics behind the rectification effect in GTAW in a way to nonetheless attain some level of understanding.

This, for making the whole subject comprehensible to your student - at the end of the day, the most important person here among us. We'll see whether or not I'll be successful in this respect.

O.k.

As I was mentioning you to have been the first one actually who had held the key to answering your students' question; I was meaning the part of your statement saying:

"…that allows an easier restart of the arc at the hot and conductive electrode."

I also could read something similar when having a look at A.C. Davis' statement, saying:

"… but actual re-ignition depends upon many factors including the surface condition of the weld pool and electrode, the temperature of the pool (…)."

And, last but not least, I was happy to read it once more in 'ssbn727’s' post saying:

"… intended to make the electrode thermionic (electrons emitted from materials at high temperatures)."

You can already see it?

Yes. It is the temperature in a direct connection to the materials used.

As mentioned for improving understanding, let us simplify the complicated facts as far as even possible. And(!) before somebody cries out now that either even "this" or even "that" could be said or explained or treated differently - I'm aware of this and sure moreover this to be true.

However, again, we common should prove willingness to come to some sort of common understanding in order to achieve and answer comprehensible to your student(s) at least basically.

Therefore we may suggest (our boundary conditions):

•  The electric welding arc is a glow-discharge.
•  Ionisation is caused through particle collision.
•  The major part of the electric current transported in the arc is due to electrons.
•  Electrons (negative charge carriers) are emitted from the "hot" cathode.

We should agree thus that the main driving force for establishing and maintaining the arc is the electrodes' temperature, physically considered referring it to as "Thermionic Emission".

As I say 'Physics'. Somebody very famous (O.W. Richardson), even a Nobel Laureate, was granted with this prize for improving our understanding of this.

He formulated a quite impressive 'RICHARDSON' formula, and I beg your forgiveness for necessarily putting this down here.

It says:

j = A_0 T^2 e^(-W/kT  )                                                                     (1)

Here is j the current density at the "hot" cathode, A_0 is a constant, T is temperature (absolute, i.e. defined as °K), W is the material work function (i.e. the amount of energy needed to "kick an electron in the a$$ to be stripped from the outer shell"), and finally k is another, the so-called BOLTZMANN constant.

Now, forgive me but it needs it, for A_0 the theory proves a value feasible to calculate by applying:

A_0 =  (4 π e m k^2)/h^3 = 120  A/(cm^2 °K^2)                                                (2)

Here m is for the electrons’ rest mass and e is for the electrons elementary charge. h is the so-called PLANCK constant. A is for Ampere.

Good. What we have seen as yet is that the major effect for any arc is the emission of electrons from the cathode and that temperature plays the most important part in this relation, for achieving "thermionic" conditions. The latter again, we could see, may be expressed mathematically what makes it possible to us to quantify-, and not only "assuming" things.

This is important at all.

Back to emission. We can see, that the specific material work function plays also a major part in all this. In brief. We may suppose now that, in case of using different materials, e.g. Aluminium (workpiece) and Tungsten (non-consumable electrode), the work functions of both materials are either different. And true this is. Of course we do have different work functions, and thus need different energies for allowing an electron to escape from the material surface in to the 'plasma'.

And now we do approach the core.

As the temperatures of both cathode and anode may appear different (different melting points) their effective work functions may be suggested to be different. Hence, the amount of thermionically emitted electrons may be suggested different either, quite depending on which material serves actually as either the cathode or the anode (just as a reminder we are speaking of AC welding).

The emissivity-difference again leads to say an imbalance, apparent as 'rectification' of the electric current, due to different current heights in either direction between anode and cathode.

Different electric currents transported (mainly) along the arc axis again lead to different current densities at both anode and cathode. And finally, it is exactly this ratio between the current densities at the point of time where the arc voltage required for re-ignition is at maximum, what mostly affects the level of rectification.

So. Knowing all this, one could modify equation (1) implementing appropriate indices thereby achieving some sort of “rectification factor” (remember, we should try to quantify not assuming things). Terming this factor e.g. "R" we could write:

R = j_1/j_2 = (T_1/T_2 )^2  e^((W_2 T_1) - (W_1 T_2)/kT_1 T_2))                    (3)

Now, however, as we come to the rather end it becomes a little complicated. Because for applying equation (3) we actually need the values T_1, T_2, W_1, and W_2.

For tungsten the work function W_1 is rather well-known (4.53 eV at its melting temperature, if memory serves me correctly) but as also repeatedly noted along this thread the work function for aluminium oxide (not the pure aluminium) is, even nowadays, intensively discussed among the experts, since depending on some quite intricate conditions again. Short. It may vary significantly.

However, to come to a brief, and again I need to repeat, simplified summary, we may be able to write:

Limited to our specific set boundary conditions thermionic emission may be assessed the major driving force or mechanism for establishing and maintaining a welding arc. In our particular case this is a gas shielded tungsten arc without dealing with further peripheral parameters (shielding gas etc.). The temperature in connection to the materials paired has significant influence on rectification, being nothing else than the external noticeable result from an imbalance between the current densities at the either electric poles surfaces.

I hope this may prove somewhat understandable. But this simply is what I was allowed to learn… some while ago.

Al I thought your explanations were extremely straightforward...and logically/technically accurate.  It takes skill to converse on such an issue in a way it reaches all listeners.   LOL ....remember the actual physical performance of electricity is still a theory..(oh boy)...we cannot actually observe electrons hopping from atom to atom...we can only measure the results of EMF.  Great thread..above my head..but good read. Thanks