This invention is in the field of optical detection of gaseous compounds, and more particularly the optical detection of pollutants by laser.
To help with the detection of carbon dioxide, methane, and certain gaseous pollutants, a narrow linewidth, tunable and band-selectable, diode-pumped solid-state laser in the wavelength region between 1550 nm and 1650 nm is desired. These lasers must be fieldable and easy to use, and have pulse energy >1 mJ at repetition rate adjustable up to 20 kHz, with pulse length no greater than tens of nanoseconds. The subject matter is an Er:YAG laser, side pumped by semiconductor lasers in the erbium absorption band near 1475 nm, with an intracavity etalon and a switchable spectral filter. The etalon will reduce the laser linewidth to <50 MHz because, unlike traditional Q-switched short pulse lasers, the cavity-dumped apparatus of the subject invention circulates the photon flux through the etalon hundreds of times before sending it out. Cavity dumping also ensures constant pulse energy over a wide range of repetition rates, as low as 100 Hz and as high as 20 kHz. The simple, automated system design ensures environmental ruggedness and ease of use.
The effects of climate change are already becoming severe, and may become disastrous. To prepare, and to avoid climate change problems, it is necessary to monitor the concentration and location of gases that lead to global warming, such as carbon dioxide (CO2) and methane (CH4). Currently, there are no portable, accurate tests for these greenhouse gases, although some progress has been made in using differential atmospheric lidar to measure, for example, CH4 leakage from petroleum processing plants. To help with the detection of these gases, and of other pollutants, a laser of the following characteristics is desirable:
There are several systems under development to address this challenge. There is an optical parametric oscillator under development for detection of CO2, and a complex Er:YAG laser has been tested for detection of CH4, but both these systems are designed for use in the laboratory, not the field. In an attempt to make a single laser that can detect several greenhouse gases and other pollutants, Er:YAG lasers have been developed that are line selectable; these are comparatively complex and it is not always easy to select the wavelength band of these non-tunable lasers.
To address this need an Er:YAG laser has been developed, side pumped by semiconductor lasers in the Er3+ absorption band near 1475 nm, with an intracavity etalon for both linewidth narrowing and tuning within a wavelength band, and with a switchable spectral filter to select the wavelength band itself. The etalon will reduce the laser linewidth to near the uncertainty limit (˜50 MHz) because, unlike traditional Q-switched short pulse lasers, the cavity dumped apparatus of the subject invention circulates the photon flux through the etalon hundreds of times before sending it out. Cavity dumping also ensures constant pulse energy over a wide range of repetition rates, as low as 100 Hz and as high as 20 kHz (previous work indicates 100 kHz is achievable). The simple, automated system design ensures environmental ruggedness and ease of use.
The laser apparatus 30 of the subject invention comprises four subsystems in
Of all the laser materials known, the one with the best properties in the wavelength region of interest is the Er3+ ion, which can be doped into a number of crystals. Spectroscopic and Judd-Ofelt analysis of these doped crystals, however, indicate that only Er:YAG has the potential to produce laser radiation at the specific wavelengths of interest—near 1570 nm (CO and H2S absorption) and near 1645 nm (CH4 and NH3 absorption).
Er:YAG has two major challenges. First, the laser wavelengths of interest terminate in the ground state of Er3+, significantly increasing the lasing threshold and introducing significant temperature effects; this is partially mitigated by careful selection of the semiconductor laser pump wavelength, making Er:YAG a “quasi-three-level” laser. The second challenge is cross-relaxation, in which two ions in the 4I13/2 level, the upper laser level, interact, pushing one into upper levels with moderate relaxation times, and dropping the other into the 4I15/2 lower laser level. This is mitigated by using lower concentration of Er3+ ions.
Er:YAG is known to produce laser output in the ranges of 1.546 μm, 1.570 μm, 1.645 μm, and 1.618 μm. There are 56 laser wavelengths theoretically possible, owing to seven Stark sublevels in the upper laser level and eight in the lower laser level. In addition, the lower four sublevels of the lower level are in a group with a nearly 350 cm−1 gap before the lowest of the upper four sublevels. These start at 410 cm−1, and thermal population distributions demonstrate that <11.5% of the total population of that level will be in the upper four sublevels. This is critical in quasi-four-level lasers; low thermal population of the terminal laser sublevel enables creation of an inversion at significantly lower pump levels than would be anticipated using standard rate equation laser models. As will be shown below, the lower the sublevel in the upper laser level and the higher the sublevel in the lower laser level, the lower the pump rate needed to reach threshold.
The ground level of Er:YAG, the 4I15/2, is also referred to as the Z level; the eight Stark sublevels are labeled Z1-Z8. Likewise, the first excited level, the 4I13/2, has sublevels Y1-Y7. The proposed invention will be pumped at ˜1475 nm, from the Z1 sublevel to the Y4 and Y5 sublevels (this value is selected based on previous Er:YAG lasers developed by the proposed Principal Investigator). The initial sublevel contains 27.3% of the total Er3+ population at room temperature, and at the start of pumping; as population is pumped out of this sublevel it is replenished, effectively immediately, by thermalization within the sublevels.
The 1570 nm transitions are Y4→Z5 and Y5→Z7. The Y4 and Y5 levels contain 9.11% and 8.31%, respectively, of the total population of the upper laser level, while the Z5 and Z7 levels contain 3.81% and 2.25% of the total population of the lower laser level. The 1645 nm transitions are more likely, partly because the initial Y2 and Y3 levels contain 22.0% and 21.3%, respectively, of the upper laser level population, while the terminal Z7 level contains only 2.25% of the total population in the lower laser level. (All these calculations assume T≈300 K.)
To model the laser operation, we use rate equation analysis. Because of the ion-ion cross-relaxation interaction, the lowest three levels must be considered. (The cross-relaxation actually pumps one ion from the 4I13/2 level into the 4I9/2, which is not included, but it rapidly decays from that level into the 4I11/2, which is included.) In these equations, the lower laser level, level 0, is the ground level, the 4I15/2; the upper laser level, level 1, is the 4I13/2; and the additional excited state, level 2, is the 4I11/2 level. Levels 1 and 2 are shown in
plus the composition equations
n=f
1s
n
1
−f
0s
n
0 (0-5)
n
0
+n
1
+n
2
=n
T. (0-6)
In eqs. (0-1) through (0-6), ni is the population density of the ith level (i=0, 1, 2); nT is the total population density of all Er3+ ions in the crystal; n is the inversion density; fij is the portion of level i population that is in sublevel j; φ is the photon density in the cavity (at the laser wavelength); c is the speed of light; σ is the emission cross-section for the laser transition; W01 is the pump rate from the semiconductor pump laser; Wcr is the cross-relaxation rate; and τk is the spontaneous lifetime of population in level k (k=1, 2, 3, or c, where c is the cavity lifetime of photons). Numerically solving these equations enables prediction of the output of the laser under any conditions.
As an example, the pump rate needed to reach inversion for the wavelength ranges listed (1570 nm and 1645 nm) as calculated. The relevant fill levels are f12=0.220, f13=0.213, f14=0.0911, f15=0.0831, f04=0.190, f05=0.0381, and f07=0.0225. Thus, to reach threshold for 1570 nm, n1>0.271 n0, while threshold is reached for 1645 nm when n1>0.102 n0. In other words, it takes 2.7× as much pump intensity to reach threshold for a 1570 nm laser as for a 1645 nm laser. A simple calculation shows that, for 0.25% Er3+ doping (the level planned), the required pump rate to reach threshold is ˜8.5×10−7 μs−1 for lasing at 1645 nm, 2.3×10−6 μs−1 for 1570 nm.
Most diode-pumped solid-state lasers are end-pumped, to take advantage of the length of the crystal rod. This is less efficient with quasi-four-level lasers. The pump laser has to be nearly the same diameter the entire length of the crystal, and this normally implies a Gaussian profile. On the other hand, the pump rate at a specific location on the crystal is proportional to the intensity of the pump laser, which is much higher at the center of the Gaussian beam. Since an area that is not inverted is, by nature, absorbing (causing loss), the end-pumped beam must waste a large portion of its intensity outside the laser crystal.
Side pumping is more effective for a number of reasons. For one, there is no need for sharp dichroic mirrors; an end-pumped laser would require, in this case, a mirror that passes 1475 nm with almost no loss but reflects almost 100% at 1570 nm, a difficult feat. In addition, end pumping limits the internal cavity layout that can be used to one that enables capture of the entire pump beam, while side pumping places no such limits on the cavity. On the financial side, an end-pumped laser requires a pump laser with a very high quality beam, while a side-pumped laser has virtually no beam quality requirements; the pump laser for a side-pumped system is much less expensive.
Although the effective cross-section is increased from 0.45×10−20 cm2 to 6.8×10−20 cm2, based on a 5 mm diameter rod the absorption per pass is still ˜20%. Thus the pumping is nearly uniform. In addition, the design of the cavity ensures that the highest intensity of pump radiation is at the center of the rod, helping optimize the mode shape.
The pump rate can be calculated as
so a pump rate of 0.85 s−1, required to reach inversion for the 1645 nm laser, relates to an average irradiance of 1.7 W/cm2-14 W total pump power for a 5 cm long rod. Pumping above this level puts the majority of power into the laser output, ensuring that the apparatus can reach the desired pulse energy of up to tens of mJ per pulse, at repetition rates up to 20 kHz.
The topic requests a pulse in “tens of ns” and spectral width “as close to transform limited as is practical.” By “transform limited,” what is typically meant is the linewidth is about equal to the inverse of the pulse length; for a 20 ns pulse, for example, Δν=50 MHz is transform limited. This is almost impossible to reach with Q-switched lasers. The methods of narrowing linewidth involve filters, and become much more effective when the photon flux passes through the filters a number of times. In Q-switching, however, the photon flux has little time to pass through the spectral filter. In addition, Q-switching puts the laser in a high-gain mode, so the filter would need to be significantly narrower to reduce the linewidth sufficiently.
In contrast, cavity dumping involves a buildup of the photon flux for a number of cavity round-trips before it is coupled out of the cavity. In this way, we can produce a shorter pulse and still reach the narrow linewidth required.
The absolute limit on the linewidth is the Heisenberg uncertainty principal which, in this case, may be written
In eq. (0-8), Δt is the pulse length and Δν is the spectral linewidth. If, for example, the cavity-dumped pulse length is 5.2 ns, the limitation on the linewidth is Δν>30 MHz—narrow enough to be considered transform limited for a 20 ns pulse.
To achieve this narrow linewidth, it is necessary to add an etalon 15 to the cavity, as shown in
The other purpose for using the etalon 15 is tuning the center line of the laser. This technique has been used to tune Er:YAG over >3 nm. Tuning is accomplished by rotating the etalon, which shifts its center wavelength. This will enable wavelength tuning, for example, from 1567-1573 nm, from 1643-1647 nm, and from 1615-1619 nm.
The apparatus of the subject invention is designed to be a “turnkey” system, with all adjustments made electronically. Thus, the etalon 15 will be mounted on a motorized base to enable electronic tuning. This method is slow—potentially longer than a second to tune across the entire band—but is known to be reliable and easy to implement.
In addition to tuning and linewidth narrowing, it is necessary to select the wavelength band (around 1570 nm, 1617 nm, or 1645 nm). The free-running wavelength of low-doped Er:YAG is 1645 nm; if no spectral filtering is included, the laser will run at this wavelength. The etalon is useful to narrow the linewidth, but not to select the wider wavelength range; other spectral filters must be used. For this reason, the switchable spectral filter 16 will be a filter wheel with three openings. One opening is blank; this is for operation at 1645 nm. The other two have spectral selection filters.
A number of spectral filters were considered for selecting the alternate lines. The apparatus may be “reconfigurable” to operate at the other wavelengths, so there could be a requirement for mirror exchange to change the wavelength range. Adding spectral filtering to the cavity can be accomplished without the need to open the cavity itself. The spectral filters, then, may be bandpass or shortpass; shortpass will work because the 1617 nm line has a higher emission cross-section than the 1570 nm lines.
Four methods of spectral filtering were considered, two bandpass and two shortpass. For bandpass volume Bragg gratings and interference filters; for shortpass, atomic or molecular filters and interference filters. Of all these, the items with the lowest insertion loss are the shortpass interference filters. The center wavelengths of the shortpass filters should be 1630 nm and 1590 nm. When no filter is used, the laser will operate at 1645 nm. When the wheel is rotated and the 1630 nm shortpass filter is in place, the additional loss at 1645 nm is 90% while the insertion loss at 1617 nm is <1% (it is about the same at 1570 nm), and the 1617 nm line will oscillate. When the 1590 nm shortpass filter is in place, the loss at 1645 nm is 95% and the loss at 1617 nm is 92%, but the insertion loss at 1570 nm is <1%. Thus, with this filter rotated into place, the subject invention will output 1570 nm.
To create short pulses, laser systems usually rely on Q-switching. In this mode, the laser is pumped continually, but the losses are kept high—so the cavity lifetime (eq. (0-4)) is short. This prevents a buildup of the photon flux, φ, in the cavity, forcing the inversion to get very large. When the cavity quality is switched into much lower loss, the large inversion converts into large photon flux, producing a pulse that contains most of the energy stored in the inversion during the high-loss time period. This can generate pulses whose lengths are between 20 ns and 100 ns, and whose peak power is thousands or millions of times higher than the same laser running in CW mode.
There are two difficulties with traditional Q-switching. First, the optimal repetition rate for a Q-switched laser is less than the inverse of the upper laser level lifetime, which would limit the Er:YAG laser to ˜100 Hz repetition rate (more than two orders of magnitude less than the required value of 20 kHz). Above this, the pulses become longer and lower power. Second, the cross-relaxation inherent in Er:YAG depopulates the upper laser level at a rate proportional to the square of the population in that level—and Q-switching depends on populating that level.
Operation of the switch involves a nonlinear optical crystal and a polarizer, such as β-barium borate (BaB2O4, or BBO). When properly cut, this crystal rotates the polarization of light passing through it, and rotates the polarization differently depending on its direction of polarization. By adjusting the voltage on the crystal, the polarization can be switched to pass light without loss, or to completely switch the light out of the cavity (
In half-wave mode (
For this apparatus cavity-dumping is used. This is almost the inverse of Q-switching; it depends on storing power in the photon field rather than in the inversion. The laser still builds an inversion, which is then switched into a low-loss mode, but the inversion does not need to be anywhere near as large as in the Q-switched case. The mirrors containing the beam are high reflectivity, so the energy in the inversion is rapidly converted to photon flux. Then the cavity is switched again, and the photon flux is dumped out of the cavity in a short pulse (for the design described in Section 0, we anticipate 3-5 ns pulse width).
The rise time of the pulse depends slightly on internal cavity loss and strongly on switching time. Its fall time depends on total cavity loss, internal+output. The pulse length can be increased by ˜25% without loss of pulse energy, but much longer leads to reduced output.
One potential application of the subject invention is atmospheric monitoring, using dual-wavelength absorption lidar. It is possible, for example, to use two wavelengths near 1570 nm to monitor atmospheric CO2. In some cases it would be useful to generate two wavelengths more widely separated, such as 1645.13 nm (CH4 absorption) or 1571.11 nm (CO2 absorption), and 1617.42 nm (minimum absorption).
There are optimal locations for two laser rods in the laser cavity. For dual wavelength absorption lidar, each of these lasers can be set to its own specific wavelength. Each will have its own set of optics but the wavelength selection can be set to specific values; by judicious mirror design, the switchable spectral filter can be removed entirely. The system can be set to any of the ˜20 available lines in Er:YAG, and the two rods can be set to slightly different wavelengths in the same laser transition or to wavelengths up to 100 nm apart.
Repetition rate can be up to 20 kHz (this is adjustable by slightly reducing the pump rate and decreasing the cavity-dump rate, the repetition rate decreases), with pulse energy >1 mJ. One design includes a rod 5 mm in diameter and 5 cm long, pumped by 1.47-μm laser diodes in the laser cavity. These are the parameters used to calculate the size, weight, power, and cost of the apparatus of the subject invention.
One embodiment is shown in
In free-running or CW operation, the voltage across the BBO crystal will be set to half-wave rotation, so that the photon flux is reflected back between the mirrors; there is still a considerable amount of waste heat. To generate the cavity-dumped pulse, with output towards the bottom of the photo, the voltage across the BBO crystal will be dropped to quarter-wave rotation; after two passes it is horizontally polarized and exits the cavity.
It will be understood that the foregoing description is of preferred exemplary embodiments of the invention and that the invention is not limited to the specific forms shown or described herein. Various modifications may be made in the design, arrangement, and type of elements disclosed herein, as well as the steps of making and using the invention without departing from the scope of the invention as expressed in the appended claims.