TEA laser


A TEA laser is a gas laser energized by a high voltage electrical discharge in a gas mixture generally at or above atmospheric pressure. The most common types are carbon dioxide lasers and excimer lasers, both used extensively in industry and research; less common are nitrogen lasers. The acronym "TEA" stands for Transversely Excited Atmospheric.

History

Invention

The carbon dioxide TEA laser was invented in the late 1960s by Jacques Beaulieu working at the Defence Research and Development Canada at Valcartier in Quebec, Canada. The development was kept secret until 1970, when brief details were published.
In 1963, C. Kumar N. Patel, working at Bell Telephone Laboratories, first demonstrated laser output at 10.6 µm from a low pressure RF-excited CO2 gas discharge. With the addition of nitrogen and helium and using a DC electrical discharge, CW powers of around 100 W were achieved. By pulsing the discharge using higher voltages, or Q-switching using a rotating mirror, pulse powers of a few kilowatts could be obtained as a practical limit.
Higher peak powers could only be achieved by increasing the density of excited CO2 molecules. The capacity for stored energy per unit volume of gas increases linearly with density and thus gas pressure, but the voltage needed to achieve gas breakdown and couple energy into the upper laser levels increases at the same rate. The practical solution avoiding very high voltages was to pulse the voltage transversely to the optical axis, limiting the breakdown distance to a few centimetres. This allowed the use of manageable voltages of a few tens of kV. The problem was how to initiate and stabilize a glow discharge at these much higher gas pressures, without the discharge degenerating into a bright high-current arc, and how to achieve this over a useful volume of gas.

CO2 TEA laser

Beaulieu reported a transversely-excited atmospheric-pressure CO2 laser. His solution to the problem of arc formation was to have a conducting bar facing a linear array of pins with a separation of a few centimetres. The pins were individually loaded with resistors forcing the discharge from each pin into a low current brush or glow discharge which fanned out towards the bar. The laser cavity probed 100-200 of these discharges in series providing the laser gain. A fast discharge capacitor rapidly switched across the laser electrodes using a spark gap or thyratron provided the high voltage pulses.
These first "Pin-Bar" TEA lasers, operating at around one pulse per second, were easy and cheap to construct. By operating at atmospheric pressure, complex vacuum and gas-handling systems could be avoided. They could produce MW peak powers of a few 100 ns duration capable of breaking down air if brought to a focus with a short focal-length lens. Disadvantages were poor gain symmetry, dissipation in the resistors and size.

Pearson and Lamberton

The first true TEA laser was realized by Pearson and Lamberton working at the UK MOD Services Electronic Research Laboratory at Baldock. They used a pair of Rogowski-profiled electrodes separated by one or two centimetres. Their double-discharged design coupled part of the discharge energy to a thin wire running parallel to, and offset from, one side of the electrodes. This served to pre-ionise the gas resulting in a uniform volumetric glow-discharge. Of equal importance to preionisation, was the need for the discharge to be very fast. By dumping energy into the gas rapidly, high-current arcs had no time to form.
Pearson and Lamberton used a streak camera to verify the sequence of events. As the voltage was erected across the electrodes, field emission from the thin wire resulted in a sheet discharge between itself and the anode. Since the subsequent main discharge started from the cathode, it was suggested that photoemission was the initiating mechanism. Subsequently, other workers had demonstrated alternative methods for achieving preionisation. These included dielectrically isolated wires and electrodes, sliding spark arrays, electron beams and pins impedance-loaded with capacitors.
The original Pearson-Lamberton TEA laser could be operated at around one pulse per second when switched with a spark gap discharging a capacitor resistively charged from a DC power supply. By circulating the gas between the electrodes, which was using lossless capacitor charging and replacing the spark-gap with a thyratron, repetition rates in excess of a thousand pulses per second were subsequently achieved with various designs of TEA laser.

Double-discharge method

The double-discharge method required to initiate stable high-pressure gas discharges can be used both below and above atmospheric pressure, and these devices too can be referred to as TEA lasers. Commercial excimer lasers operating in the ultraviolet use a double-discharge regime very similar to the CO2 TEA laser. Using krypton, argon or xenon chloride or fluoride gas buffered with helium to 2-3 atmospheres of pressure, excimer lasers can produce megawatt pulses of ultraviolet laser light.

Microscopic discharge description

In most over-voltage spark gaps avalanches of electrons move towards the anode.
As the number of electrons increases Coulomb's law states that also the field strength increases.
The strong field accelerates the avalanche.
A slow rise time of the voltage lets the electrons drift towards the anode before they can generate an avalanche.
Electrophilic molecules capture electrons before they can generate an avalanche.
Thermal effects destabilize a homogeneous discharge electron and ion diffusion stabilizes it.

Applications

TEA CO2 lasers are used extensively for product marking. A logo, serial number or best-before dated is marked on to a variety of packaging materials by passing the laser light through a mask containing the information, and focusing it down to an intensity which ablates the material to be marked. Beside this TEA CO2 lasers are used for surface preparation in industrial environments since the mid 1990s. Applications include:
The advantage of this specific laser is the combination of the CO2 specific wavelength, mainly 10.6 µm, with the high energy level of the short pulses.