Thermopile laser sensor: Difference between revisions
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[[File:All radiation sensors.jpg|thumb|Figure 1:<ref>{{Cite web|title=gRAY Sensors|url=http://gray.greenteg.com}}</ref> Thermal sensors are available in various sizes]] |
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[[Thermopile]] [[laser]] sensors (Fig 1) are used for measuring laser power from a few μW to several W [[Thermopile Laser Sensors#Maximum power|(see section 2.4)]].<ref name=":8" /> The incoming radiation of the laser is converted into heat energy at the surface.<ref>{{Cite web|url=http://www.greenteg.com/laser-power-sensor/thermopile-sensor-working-principle/|title=Working Principle|website=gRAY|access-date=6 May 2016}}</ref> This heat input produces a [[temperature gradient]] across the sensor. Making use of the [[thermoelectric effect]] a [[voltage]] is generated by this [[temperature gradient]]. Since the voltage is directly proportional to the incoming radiation, it can be directly related to the irradiation [[power (physics)|power]] [[Thermopile Laser Sensors#Sensitivity|(see section 2.1)]]. |
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Unlike [[photodiode]]s, thermopile sensors can be used for a broad [[spectrum]] of [[wavelength]]s ranging from [[UV]] to [[Mid-infrared|MIR]] (depending on the characteristics of the absorption coating at different wavelengths).<ref>{{Cite web|url=http://www.betelco.com/sb/phd/ch6/c63.html|title=Study of Indium Tin Oxide (ITO) for Novel Optoelectronic Devices|last=Bashar|first=Dr. Shabir A.|date=7 May 2016|access-date=7 May 2016}}</ref><ref>{{Cite web|url=https://www.thorlabs.com/images/TabImages/Thermal_Power_Sensors_S305C_800.gif|title=Throlabs C-Series Power Meter|date=6 May 2016|access-date=6 May 2016}}</ref> Further, photodiodes are reverse biased and saturate for optical powers above a certain value (typically in mW),<ref>{{Cite book|title=Integrated Optoelectronics 4, Issue 41|last=J. Weidner|publisher=The Electrochemical Society|year=2009|isbn=9781566777223}}</ref> making thermopile sensors suitable for high power measurements.<ref name=":8">{{Cite web|url=http://www.thorlabs.de/newgrouppage9.cfm?objectgroup_id=3333|title=Product Specification C-Series|date=6 May 2016|website=Thorlabs|access-date=6 May 2016}}</ref> |
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[[Pyroelectric]] sensor and calorimeter are commonly used for measuring the energy of laser pulses.<ref name=":0" /> Pyroelectric sensor can measure low to medium energies (mJ to [[Joule|J]]) and are prone to [[Microphonics|microphonic effects]].<ref name=":0" /> Calorimeters are capable of measuring high energies (mJ to kJ) but have large response times.<ref name=":0">"[[Comparison of pyroelectric and thermopile]]", Norbert Neumann, Victor Banta, Infra Tec GmbH, Gostritzer Str.61-61, 01217 Dresden, Germany and Dexter Research Center, Inc., 7300 Huron River Drive, Dexter; MI 48130, USA</ref> |
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Thermopile laser sensors (Fig 1) are used for measuring laser power from few µW to several W [[Draft:Thermopile Laser Sensors#Maximum power|(see section 2.4)]]. The incoming radiation of the laser is converted into heat energy at the surface. This heat input produces a temperature gradient across the sensor. Making use of the thermoelectric effect a voltage is generated by this temperature gradient. Since it is directly proportional to the incoming radiation, this voltage can be directly related to the irradiation power [[Draft:Thermopile Laser Sensors#Sensitivity|(see section 2.1)]]. |
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== Working principle and structure == |
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Unlike photodiodes, thermopile sensors can be used for a broad spectrum of wavelengths ranging from UV to MIR (depending on the characteristics of the absorption coating at different wavelengths). Further, as photodiodes are reverse biased and saturate for optical powers above a certain value (typically in mW), making thermopile sensors suitable for high power measurements <ref>{{Cite web|url=http://www.thorlabs.de/newgrouppage9.cfm?objectgroup_id=3328|title=Product Specification C-Series|last=|first=|date=|website=Thorlabs|publisher=|access-date=}}</ref>. |
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[[File:Working principle-01.jpg|thumb|293x293px|Figure 2:<ref name= "Geometry"/> Working principle of a thermal laser sensor (Adapted from figure 3 with permission)]] |
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As shown in Fig 2, a thermopile laser sensor consists of several thermocouples connected in series with one junction type (hot junction at temperature T<sub>1</sub>) being exposed to an absorption area and the other junction type (cold junction at temperature T<sub>2</sub>) being exposed to a heat sink. When a laser beam hits the surface of a thermopile sensor, the incident radiation is absorbed within the coating layer and transformed into heat. This heat then induces a temperature gradient across the sensor given as |
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<math>\frac{dT}{dx} = \frac{T_2-T_1}{t}</math> [K/m], |
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Pyroelectric sensor and calorimeter are commonly used for measuring the energy of laser pulses. Pyroelectric sensor can measure low to medium energies (mJ to J) and are prone to microphonic effects. Calorimeters are capable of measuring high energies (mJ to kJ) but have large response times <ref>“[[Comparison of pyroelectric and thermopile]]”, Norbert Neumann, Victor Banta, Infra Tec GmbH, Gostritzer Str.61-61, 01217 Dresden, Germany and Dexter Research Center, Inc., 7300 Huron River Drive, Dexter; MI 48130, USA</ref>. |
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where t is the thickness of the sensor.<ref name=":2">{{Cite book|title=Thermoelectricity: Theory, Thermometry, Tool, Issue 852|last=D. Pollock|first=Daniel|publisher=ASTM International|year=1985|isbn=9780803104099}}</ref> |
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= Working principle and structure = |
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Due to the thermoelectric effect, the temperature difference causes an electrical voltage to build up within each thermocouple. This output voltage is directly proportional to the power of the incoming radiation.<ref>{{Cite web|url=http://gray.greenteg.com/#WorkingPrinciple|title=gRAY Laser Power Detectors by greenTEG|website=gRAY - Laser Power Detectors|language=en-GB|access-date=2016-04-28}}</ref> Since a large number of thermopiles are typically connected in series, voltages of several μV to V are reached. |
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As shown in Fig 2, a thermopile laser sensor consists of several thermocouples connected in series with one junction type (hot junction at temperature T1) being exposed to an absorption area and the other junction type (cold junction at temperature T2) being exposed to a heat sink. When a laser beam hits the surface of a thermopile sensor, the incident radiation is absorbed within the coating layer and transformed into heat. This heat then induces a temperature gradient given as |
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dT/dx=(T2-T1)/t [K/m], |
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across the sensor. |
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Due to the thermoelectric effect, the temperature difference causes an electrical voltage to build up within each thermocouple. This output voltage is directly proportional to the power of the incoming radiation <ref>{{Cite web|url=http://gray.greenteg.com/#WorkingPrinciple|title=gRAY Laser Power Detectors by greenTEG|website=gRAY - Laser Power Detectors|language=en-GB|access-date=2016-04-28}}</ref>. |
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In general, a thermopile sensor consists of three elements: an absorber, the sensor element and a cooling body to dissipate the incoming heat. |
In general, a thermopile sensor consists of three elements: an absorber, the sensor element and a cooling body to dissipate the incoming heat. |
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== Absorber == |
=== Absorber === |
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Depending on the thickness of the absorption layer thermopile sensor can be classified into two categories. |
Depending on the thickness of the absorption layer, the thermopile sensor can be classified into two categories.<ref name="Newport" /> |
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=== Surface absorber === |
==== Surface absorber ==== |
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For surface absorbers the thickness of the absorption layer very thin (0.1 – 1 µm) and so is the total absorption length. It is used for power measurements of lasers with long pulse length (generally for CW laser). If a laser with pulse length in the range of 10<sup>-7</sup> – 10<sup>-4</sup> sec is used the sensor can be damaged by either dielectric break-down or thermal effects. In case of thermal damage, heat is deposited in a short time and cannot be dissipated until the next pulse arrives. This leads to an accumulation of energy in a thin layer leading to partial vaporization <ref name="Newport">{{Cite web|url=http://www.newport.com/Thermopile-Laser-Power-Sensor-Technology-Tutorial/1009203/1033/content.aspx|title=Thermopile Laser Power Sensor Technology Tutorial|website=www.newport.com|access-date=2016-04-28}}</ref>. For dielectric breakdown, the peak energy density during a pulse is high enough to locally ionize the sensor surface. |
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For surface absorbers the thickness of the absorption layer is very thin (0.1 – 100 μm) and so is the total [[absorption length]].<ref name="Newport" /> It is used for power measurements of lasers with long pulse length (generally for CW laser). If a laser with pulse length in the range of 10<sup>−7</sup> – 10<sup>−4</sup> sec is used the sensor can be damaged by either dielectric break-down or thermal effects.<ref name=":1" /> In case of thermal damage, heat is deposited in a short time and cannot be dissipated until the next pulse arrives. This leads to an accumulation of energy in a thin layer leading to partial vaporization.<ref name="Newport">{{Cite web|url=http://www.newport.com/Thermopile-Laser-Power-Sensor-Technology-Tutorial/1009203/1033/content.aspx|title=Thermopile Laser Power Sensor Technology Tutorial|website=www.newport.com|access-date=2016-04-28}}</ref> For dielectric breakdown, the peak energy density during a pulse is high enough to locally ionize the sensor surface.<ref name=":3" /> |
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=== Volume absorber === |
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To protect the sensor from damages by short optical pulses, volume absorbers are used with absorption lengths in the order of millimetres. This enables volume absorbers to withstand higher pulse energy densities, since the optical power is absorbed over a considerable depth of material <ref name="Newport" />. |
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== |
==== Volume absorber ==== |
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To protect the sensor from damages by short optical pulses, volume absorbers are used with absorption lengths in the order of millimetres.<ref name="Newport" /> This enables volume absorbers to withstand higher pulse energy densities, since the optical power is absorbed over a considerable depth of material.<ref name="Newport" /> |
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=== Sensor geometry === |
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There are two main types of thermopile laser sensors which can be classified according to the geometric arrangement of the thermocouples inside the sensor element |
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[[File:Disc-gT Comparison.png|thumb|451x451px|Figure 3:<ref name="Geometry"/> (a) Radial Thermopile and (b) Axial Thermopile Sensors]] [[File:B01-SC.jpg|thumb|173x173px|Figure 4:<ref>{{Cite web|url=http://gray.greenteg.com/|title=B01-SC|website=gRAY, greenTEG}}</ref> Axial sensor with 0.5 mm thickness]]There are two main types of thermopile laser sensors which can be classified according to the geometric arrangement of the thermocouples inside the sensor element. |
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=== Radial thermopile sensor/Thermopile discs === |
==== Radial thermopile sensor/Thermopile discs ==== |
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Thermopile discs have thermocouples deposited onto an aluminium plate in a radial arrangement as shown in Fig 3(a).<ref name="Geometry" /> All thermocouples are electrically connected in series with one junction at the circumference of the inner area which is illuminated and the other junction at the outer circumference.<ref name="Geometry" /> The absorption coating in the illuminated area converts radiation into heat which flows radially outwards generating a temperature gradient between inner and outer ring and thus a thermoelectric voltage.<ref name="Geometry">ʺReinventing Thermal Laser Power Measurementsʺ, Lasers in Manufacturing Conference 2015, S. Dröscher, M. Zahner, E. Schwyter, T. Helbling and C. Hierold</ref> |
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==== Axial thermopile sensor ==== |
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Thermopile discs have thermocouples deposited onto an aluminium plate in a radial arrangement as shown in Fig 3(a). All thermocouples are electrically connected in series with one junction at the circumference of the inner area which is illuminated and the other junction at the outer circumference. The absorption coating in the illuminated area converts radiation into heat which flows radially outwards generating a temperature gradient between inner and outer ring and thus a thermoelectric voltage <ref name="Geometry">ʺReinventing Thermal Laser Power Measurementsʺ, Lasers in Manufacturing Conference 2015, S. Dröscher, M. Zahner, E. Schwyter, T. Helbling and C. Hierold</ref>. |
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Fig 3(b) shows the cross sectional view of the axial sensor where the temperature difference is established between the top and bottom surfaces. Thermocouples are embedded into a matrix and aligned parallel with respect to the heat flow, forming junctions at top and bottom.<ref name="Geometry" /> This arrangement permits a reduction of the total sensor thickness to 0.5 mm (Fig 4).<ref name="Geometry" /> |
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=== Axial thermopile sensor === |
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=== Cooling/Heat management === |
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Fig 3(b) shows the cross sectional view of the axial sensor where the temperature difference is established between the top and bottom surfaces. Thermocouples are embedded into a matrix and aligned parallel with respect to the heat flow, forming junctions at top and bottom. This arrangement permits a reduction of the total sensor thickness to 0.5 mm (Fig 4) <ref name="Geometry" />. |
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It is crucial to dissipate the incoming heat in order to establish a stable temperature gradient across the sensor.<ref name=":4">{{Cite book|title=A Heat Transfer Textbook: 5th Edition|last=John H Lienhard|publisher=Dover Pub.|year=2019}}</ref> Therefore, the cold side of the sensor needs to be thermally coupled to a [[heat sink]]. |
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==== Passive cooling ==== |
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In this method of cooling the cold side of the sensor is mounted onto a heat conductor (usually an aluminium heat sink), and heat is dissipated to the surrounding by conduction (through heat conductor) and convection (air flow).<ref name=":4" /> |
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== Cooling/Heat management == |
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It is crucial to dissipate the incoming heat in order to establish a stable temperature gradient across the sensor. Therefore the cold side of the sensor needs to be thermally coupled to a heat sink. |
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=== |
==== Active cooling ==== |
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In this method of cooling the cold side of the sensor is mounted onto a heat conductor (usually an aluminium heat sink), and heat is dissipated to the surrounding by conduction (through heat conductor) and convection (air flow) |
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=== Active cooling === |
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In this method of cooling the heat is actively transferred to the environment. This is usually done by mounting a fan on the heat sink of a passively cooled detector or by pumping water through a channel system to cool the sensor. The preferred choice depends on the amount of heat to be dissipated and thus on the detector power. |
In this method of cooling the heat is actively transferred to the environment. This is usually done by mounting a fan on the heat sink of a passively cooled detector or by pumping water through a channel system to cool the sensor. The preferred choice depends on the amount of heat to be dissipated and thus on the detector power. |
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= Characteristics = |
== Characteristics == |
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== Sensitivity == |
=== Sensitivity === |
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The sensitivity S [V/W] is the ratio of voltage U [V] generated due to the incident laser power P [W] on the sensor. The voltage generated depends on the Seebeck coefficient of the thermoelectric material; hence it is a material specific constant. The incident power can be calculated by measuring the sensor voltage and using the formula: |
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The sensitivity S [V/W] is the ratio of voltage U [V] generated due to the incident laser power P [W] on the sensor. The voltage generated depends on the [[Seebeck coefficient]] of the thermoelectric material; hence it is a material specific constant.<ref name=":2" /> The incident power can be calculated by measuring the sensor voltage and using the formula: |
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P = U/S [W]. |
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<math>P = \frac{U}{S}</math> [W]. |
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The effective sensitivity depends on the absorption property of the coating layer. For constant incident laser power a larger absorption coefficient means more heat is generated leading to increase in output voltage. |
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== Spectral range == |
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The spectral range depends on the absorption characteristics of the coating material. Typically, a flat absorption spectrum across a broad wavelength range is desired. It can also, be tailored to a wavelength range or to a particular wavelength. |
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== Rise time == |
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The effective sensitivity depends on the absorption property of the coating layer. For constant incident laser power a larger absorption coefficient means more heat is generated<ref>{{Cite journal|title=Experimental and theoretical studies of light-to-heat conversion and collective heating effects in metal nanoparticle solutions|last=Hugh H. Richardson, Michael T. Carlson, Peter J. Tandler, Pedro Hernandez, and Alexander O. Govorov|date=6 May 2016|pmc=2669497|pmid=19193041|doi=10.1021/nl8036905|volume=9|issue=3|journal=Nano Lett.|pages=1139–46}}</ref> leading to increase in output voltage. |
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The signal rise time is the time required by the sensor to reach 95% of the full signal amplitude when exposed to a step function of incident laser power. It depends on the overall thermal resistances and thermal capacitance of the sensor. The magnitude of these two parameters depends on the detector materials and geometry <ref>{{Cite web|url=http://www.newport.com/Thermopile-Laser-Power-Sensor-Technology-Tutorial/1009203/1033/content.aspx|title=Thermopile Laser Power Sensor Technology Tutorial|website=www.newport.com|access-date=2016-04-28}}</ref>. |
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=== Spectral range === |
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The rise time for axial sensors is usually more than for radial sensors since the axial sensor possess lower thermal mass and thermal resistance. The difference can amount to a factor of 5 to 10 and is shown in Fig 5. |
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The spectral range depends on the absorption characteristics of the coating material.<ref>[[International Union of Pure and Applied Chemistry|IUPAC]], ''[[Compendium of Chemical Terminology]]'', 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "[http://goldbook.iupac.org/A00028.html Absorbance]".</ref> Typically, a flat absorption spectrum across a broad wavelength range is desired. It can also be tailored to a wavelength range or to a particular wavelength. |
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== Maximum power == |
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[[File:Risetime both2-01.jpg|thumb|326x326px|Figure 5:<ref name="Geometry"/> Rise time comparison between Radial and axial thermopile sensors]] |
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=== Rise time === |
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The maximum power that can be measured accurately depends on the type of sensor, its material properties and the type of cooling used [[Draft:Thermopile Laser Sensors#Cooling/Heating management|(see section 1.3)]]. Faulty measurements or even deterioration of the sensor can result due to too large irradiance. |
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The signal [[rise time]] is the time required by the sensor to reach 95 percent of the full signal amplitude when exposed to a step function of incident laser power. It depends on the overall thermal resistances and thermal capacitance of the sensor.<ref name="Newport"/> The magnitude of these two parameters depends on the detector materials and geometry <ref name="Newport"/> |
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== Maximum power density == |
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The rise time for axial sensors is usually shorter than for radial sensors since the axial sensors possess lower thermal mass and thermal resistance.<ref name="Geometry" /> The difference can amount to a factor of 5 to 10 and is shown in Fig 5.<ref name="Geometry" /> |
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=== Maximum power === |
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The maximum laser power density for the sensor depends on the laser –induced damage threshold of the coating material. The threshold value depends on the wavelength of the laser, its pulse length and to a certain extent, on the structure of the absorbing surface <ref>{{Cite web|url=https://www.rp-photonics.com/laser_induced_damage.html|title=Laser Induced Damage|last=|first=|date=|website=RP Photonics|publisher=|access-date=}}</ref>. |
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The maximum power that can be measured accurately depends on the type of sensor, its material properties and the type of cooling used [[Thermopile Laser Sensors#Cooling/Heating management|(see section 1.3)]].<ref name=":1" /> Faulty measurements or even deterioration of the sensor can result due to too large irradiance.<ref name=":1" /> |
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Pulse duration t<10-9 s 10-9 < t < 10-7 s 10-7< t < 10-4 s t> 10-4 s |
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Damage mechanism Avalanche ionization Dielectric breakdown Dielectric breakdown or thermal damage Thermal damage |
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Relevant damage Specification N/A Pulsed Pulsed and CW CW |
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Table 1, source: Thorlabs, https://www.thorlabs.com/tutorials.cfm?tabID=762473b5-84ee-49eb-8e93-375e0aa803fa |
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=== Maximum power density === |
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The maximum laser power density for the sensor is given by the laser induced damage threshold of the coating material.<ref name=":3" /> The threshold value depends on the wavelength of the laser, its pulse length and to a certain extent, on the structure of the absorbing surface <ref name=":3">{{Cite web|url=https://www.rp-photonics.com/laser_induced_damage.html|title=Laser Induced Damage|website=RP Photonics}}</ref> |
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{| class="wikitable" style="caption-side: bottom;" |
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= Sources of error = |
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|+ style="text-align:left;" |Table 1<ref name=":1">{{Cite web|url=https://www.thorlabs.com/tutorials.cfm?tabID=762473b5-84ee-49eb-8e93-375e0aa803fa|title=Laser induced damage threshold|website=thorlabs.com}}</ref> |
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!Pulse duration |
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!t<10<sup>−9</sup> |
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!10<sup>−9</sup><t<10<sup>−7</sup> |
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!10<sup>−7</sup><t<<sup>−4</sup> |
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!t>10<sup>−4</sup> |
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|- |
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!Damage mechanism |
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|Avalanche ionization || Dielectric breakdown || Dielectric breakdown or thermal damage || Thermal damage |
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|- |
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!Relevant damage specification |
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|N/A || Pulsed || Pulsed and CW || CW |
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|- |
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|} |
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== Sources of measurement errors == |
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== Temperature error == |
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=== Temperature error === |
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The sensitivity of the sensor varies with the mean sensor temperature. This is due to the temperature dependence of the Seebeck coefficient [[Draft:Thermopile Laser Sensors#Sensitivity|(see section 2.1)]]. |
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The sensitivity of the sensor varies with the mean sensor temperature. This is due to the temperature dependence of the Seebeck coefficient [[Thermopile Laser Sensors#Sensitivity|(see section 2.1)]].<ref>{{Cite journal|last=Kengo Kishimoto, Masayoshi Tsukamoto and Tsuyoshi Koyanagi|date=6 May 2016|title=Temperature dependence of the Seebeck coefficient and the potential barrier scattering of n-type PbTe films prepared on heated glass substrates by rf sputtering|journal=Journal of Applied Physics|volume=92|issue=9|pages=5331–5339|doi=10.1063/1.1512964}}</ref> |
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Since the dependence is quasi linear, the temperature error can be corrected by multiplying the measured value by a temperature dependent correction factor <ref name="Error">{{Cite web|url=http://gray.greenteg.com/wp-content/uploads/2016/04/Laser-power-measurement-errors.pdf|title=Thermal Management|last=|first=|date=|website=gray.greenteg.com|publisher=|access-date=}}</ref>. |
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Since the dependence is quasi linear, the temperature error can be corrected by multiplying the measured value by a temperature dependent correction factor<ref name=":7">{{Cite web|url=http://gray.greenteg.com/wp-content/uploads/2016/04/Laser-power-measurement-errors.pdf|title=Thermal Management for Thermopile Laser Power Sensors|date=6 May 2016|website=gRAY|access-date=6 May 2016}}</ref> |
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== Background error == |
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=== Background error === |
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If the sensor temperature is different from the ambient temperature heat flows directly to the surrounding without contributing to the detected temperature gradient therefore effectively reducing the sensor output. This type of error is on the order of few mW and is thus significant only at low incident powers. |
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If the sensor temperature is different from the ambient temperature heat flows directly to the surrounding without contributing to the detected temperature gradient therefore effectively reducing the sensor output.<ref name=":6">{{Cite web|url=http://www.efunda.com/DesignStandards/sensors/thermocouples/thmcple_theory.cfm|title=Thermocouples: Theory|date=6 May 2016|access-date=6 May 2016}}</ref> This type of error is on the order of few mW and is thus significant only at low incident powers<ref name=":6" /> |
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The background error can be minimized by keeping the sensor at ambient temperature and avoiding convective air flows. It can also be corrected by subtracting the signal of a non-illuminated sensor (dark measurement) <ref name="Error" />. |
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The background error can be minimized by keeping the sensor at ambient temperature and avoiding convective air flows. It can also be corrected by subtracting the signal of a non-illuminated sensor (dark measurement).<ref name=":7" />[[File:Continuous monitoring-01.jpg|thumb|224x224px|Figure 6:<ref name="Application" /> An example showing how thermal sensors can be used for continuous measurement]] |
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= Applications = |
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== Applications == |
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Thermopile laser sensors find their use mainly where sensitivity to a wide spectral range is needed or where high laser powers need to be measured. Thermopile sensor are integrated into laser systems and laser sources and are used for sporadic as well as continuous monitoring of laser power, e.g. in feedback control loops. Some of the applications are |
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Thermopile laser sensors find their use mainly where sensitivity to a wide spectral range is needed or where high laser powers need to be measured. Thermopile sensors are integrated into laser systems and laser sources and are used for sporadic as well as continuous monitoring of laser power, e.g. in feedback control loops. Some of the applications are |
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== Medical systems == |
=== Medical systems === |
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According to EU standard (EN6001-1-22), every medical laser system needs to be equipped with a redundant power measurement unit. For procedures such as precise tissue cutting and ablation the laser power can measured before operation or even continuously throughout the process. One possible means of integrating a thermopile sensor in a medical system is by using a shutter or beam reflector (Fig 6) which can be flipped into and out of the beam path for short measurement periods of full laser power |
According to EU standard (EN6001-1-22), every medical laser system needs to be equipped with a redundant power measurement unit. For procedures such as precise tissue cutting and ablation the laser power can be measured before operation or even continuously throughout the process. One possible means of integrating a thermopile sensor in a medical system is by using a shutter or beam reflector (Fig 6) which can be flipped into and out of the beam path for short measurement periods of the full laser power.<ref name="Application">{{Cite web|url=http://gray.greenteg.com/wp-content/uploads/2015/08/2015_Aug_gRAY_Applications.pdf|title=Applications|date=2015-08-18|website=gray.greenteg.com}}</ref>[[File:Continuous monitoring back mirror-01.jpg|thumb|224x224px|Figure 7:<ref name="Application" /> An example showing how the thermal sensors can be used for continuous monitoring using back mirror]] |
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== Industrial systems == |
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=== Industrial systems === |
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Manufacturing processes require precision and reproducibility. For laser materials processing the monitoring of laser power is beneficial as it can avoid scrap production and yield high quality products. |
Manufacturing processes require precision and reproducibility. For laser materials processing the monitoring of laser power is beneficial as it can avoid scrap production and yield high quality products. |
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There are various ways of integrating a power measurement. In Fig 6 the integration in the beam path behind a beam splitter is shown. Fig 7 illustrates the option of mounting the detector behind the back mirror of a laser cavity for continuous monitoring. Beam losses further down the beam path, caused e.g. by a deterioration of optics, are not mapped in this type of arrangement. |
There are various ways of integrating a power measurement. In Fig 6 the integration in the beam path behind a beam splitter is shown. Fig 7 illustrates the option of mounting the detector behind the back mirror of a laser cavity for continuous monitoring. Beam losses further down the beam path, caused e.g. by a deterioration of optics, are not mapped in this type of arrangement. |
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As an alternative, detectors can be used for sporadic measurements at the laser system output. Usually, the full beam is measured in this case |
As an alternative, detectors can be used for sporadic measurements at the laser system output. Usually, the full beam is measured in this case.<ref name="Application" /> |
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[[File:20477-xl.jpg|thumb|Figure 8:<ref>{{Cite web|url=https://www.thorlabs.com/images/xlarge/20477-xl.jpg|title=Thorlabs Power Meter|website=thorlabs.com}}</ref> Thorlab's thermal power meter|200x200px]] |
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== Power meters == |
=== Power meters === |
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For laser power measurements where photodiodes cannot be employed due to their limited maximum power or to measure power over a broad spectrum, thermopile sensors are used. The sensor element is usually integrated into a metal housing for mechanical and thermal stability. The signal is recorded and processed in a read-out unit which displays the measured laser power (Fig 9) <ref name="Application" />. |
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For sporadic measurements outside the laser system (e.g. during maintenance) a separate measuring unit is beneficial. For such a power meter, the sensor element is usually integrated into a metal housing for mechanical and thermal stability. The signal is recorded and processed in a read-out unit which displays the measured laser power (Fig 8).<ref name="Application" /> |
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== Ultrafast laser measurement == |
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=== Ultrafast laser measurement === |
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Short-pulsed lasers which are used in spectroscopy and optical communication can be measured using thermopile sensors since they possess high thresholds for laser induced damages, especially when employed with a volume absorber [[Draft:Thermopile Laser Sensors#Maximum power density|(see section 2.5)]]. |
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Short-pulsed lasers which are used in [[spectroscopy]] and [[optical communication]] can be measured using thermopile sensors since they possess high thresholds for laser induced damages, especially when equipped with a volume absorber. [[Thermopile Laser Sensors#Maximum power density|(see section 2.5)]]. |
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== Position detector == |
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=== Position detector === |
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An arrangement of several thermally coupled thermopile sensors similar to a quadrant photodiode design (Fig 8) can be used to detect beam position as well as beam power. This is useful for beam alignment purposes or for processes where a correct beam position is crucial for high production yield <ref name="Application" />. |
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[[File:Datasheet SensorDrawingPositionSensor-01.png|thumb|325x325px|Figure 9:<ref>{{Cite web|url=http://www.greenteg.com/wp-content/uploads/Datasheet_SensorDrawingPositionSensor-01.png|title=Position Sensor|website=gray.greenteg.com}}</ref> Position sensor, with different quadrant as shown in the image]] |
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An arrangement of several thermally coupled thermopile sensors similar to a quadrant photodiode design (Fig 9) can be used to detect beam position as well as beam power. This is useful for beam alignment purposes or for processes where a correct beam position is crucial for high production yield.<ref name="Application" /> |
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== Comparison between different types of detectors. == |
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{|class="wikitable" style="caption-side:bottom;" |
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|+ style="text-align:left;" |Table 2<ref>{{Cite web|url=http://gray.greenteg.com/wp-content/uploads/2016/03/gRAY-B0.5-SC-vs-Photodiode.pdf|title=Thermal sensor vs Photodiode|date=6 May 2016|website=gray.greenteg.com|access-date=6 May 2016}}</ref><ref>{{Cite book|title=Gentec EO Product Guide|publisher=gentec EO|year=2014}}</ref> |
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!Feature |
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!Thermopile |
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!Photodiode |
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!Pyroelectric |
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!Calorimeter |
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|- |
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!Physical principle |
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| Thermoelectricity || Electrons hole combination || Pyro electricity || Thermoelectricity |
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|- |
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!Spectral Range |
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| Broadband || narrow band || narrow band || broadband |
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|- |
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!Power Range |
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| Low to medium || Low || Low to medium energies || Very high energies |
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|- |
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!Signal |
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| Voltage(V) || Current(A) || Voltage(V) or Current(A) || Voltage(V) |
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|- |
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!Response time |
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| High || Low || Low || High |
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|- |
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!Wavelength dependent sensitivity |
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| No || Yes || No || No |
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|- |
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!Linear response |
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|Yes || Yes, up to saturation || -- || -- |
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|- |
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!Effect of small variation of incident angle |
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| Negligible || Significant || Negligible || Negligible |
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|} |
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== References == |
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= Comparison between different types of detectors. = |
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{{reflist}} |
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[[Category:Sensors]] |
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[[Category:Lasers]] |
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Feature Thermopile Photodiode Pyroelectric Calorimeter |
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[[Category:Optoelectronics]] |
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Physical principle Thermoelectricity Electrons hole combination Pyro electricity Thermoelectricity |
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[[Category:Laser applications]] |
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Spectral Range Broadband narrow band |
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narrow band broadband |
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Power Range Low to medium Low Low to medium energies Very high energies |
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Signal Voltage(V) Current(A) Voltage (V) or Current(A) |
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Voltage (V) *not sure |
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Response time High Low (Low) High |
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Homogeneous response over sensor area Yes No --- Yes |
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Wavelength dependent sensitivity No Yes No No |
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Linear response Yes Yes, up to saturation --- --- |
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Effect of small variation of incident angle Negligible Significant Negligible Negligible |
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Table 2, source: GreenTEG AG, “gRAY comparison to photodiode detectors”(Upload pdf) and Gentec EO, “Product guide” |
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Fig 1 source: http://gray.greenteg.com/wp-content/uploads/2015/02/Head-without-plugs_web.png |
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Fig 2, adapted from Fig 3 with permission |
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Fig 3 source: S. Dröscher, M. Zahner, E. Schwyter, T. Helbling and C. Hierold, ʺReinventing Thermal Laser Power Measurementsʺ, Lasers in Manufacturing Conference 2015 |
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Fig 4 source: http://gray.greenteg.com/wp-content/uploads/2015/06/B01-SC.jpg |
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Fig 5 source: S. Dröscher, M. Zahner, E. Schwyter, T. Helbling and C. Hierold, ʺReinventing Thermal Laser Power Measurementsʺ, Lasers in Manufacturing Conference 2015 |
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Fig 6 source: “greenTEG Latest applications of gRAY detectors, © Copyright greenTEG AG, 2015 All Rights Reserved |
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Published 17th August 2015”, greenTEG.com |
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Fig 7 source: “greenTEG Latest applications of gRAY detectors, © Copyright greenTEG AG, 2015 All Rights Reserved |
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Published 17th August 2015”, greenTEG.com |
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Fig 8 source: http://www.greenteg.com/wp-content/uploads/Datasheet_SensorDrawingPositionSensor-01.png |
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Fig 9 Source: Thorlabs, S401C thermal sensor, https://www.thorlabs.com/images/TabImages/Thermal_Sensor_Tube_A1-150.jpg |
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References: |
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Thorlabs, Product Specification C-Series(Link it to website) |
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“Comparison of pyroelectric and thermopile”, Norbert Neumann, Victor Banta, Infra Tec GmbH, Gostritzer Str.61-61, 01217 Dresden, Germany and Dexter Research Center, Inc., 7300 Huron River Drive, Dexter; MI 48130, USA |
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GreenTEG, Thermopile sensor working(Link it to website) |
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Newport Corporation, http://www.newport.com/Thermopile-Laser-Power-Sensor-Technology-Tutorial/1009203/1033/content.aspx |
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ʺReinventing Thermal Laser Power Measurementsʺ, Lasers in Manufacturing Conference 2015, S. Dröscher, M. Zahner, E. Schwyter, T. Helbling and C. Hierold |
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LaserPoint, Operating Principles |
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RP Photonics, https://www.rp-photonics.com/laser_induced_damage.html |
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GreenTEG, “Whitepaper error sources”(Upload it with pdf) |
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GreenTEG, ʺLatest application of gRAY detectorsʺ(Upload it with pdf) |
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= References = |
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{{reflist}} |
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<!--- After listing your sources please cite them using inline citations and place them after the information they cite. Please see https://en.wikipedia.org/wiki/Wikipedia:REFB for instructions on how to add citations. ---> |
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Latest revision as of 07:41, 19 May 2024
Thermopile laser sensors (Fig 1) are used for measuring laser power from a few μW to several W (see section 2.4).[2] The incoming radiation of the laser is converted into heat energy at the surface.[3] This heat input produces a temperature gradient across the sensor. Making use of the thermoelectric effect a voltage is generated by this temperature gradient. Since the voltage is directly proportional to the incoming radiation, it can be directly related to the irradiation power (see section 2.1).
Unlike photodiodes, thermopile sensors can be used for a broad spectrum of wavelengths ranging from UV to MIR (depending on the characteristics of the absorption coating at different wavelengths).[4][5] Further, photodiodes are reverse biased and saturate for optical powers above a certain value (typically in mW),[6] making thermopile sensors suitable for high power measurements.[2]
Pyroelectric sensor and calorimeter are commonly used for measuring the energy of laser pulses.[7] Pyroelectric sensor can measure low to medium energies (mJ to J) and are prone to microphonic effects.[7] Calorimeters are capable of measuring high energies (mJ to kJ) but have large response times.[7]
Working principle and structure
[edit]
As shown in Fig 2, a thermopile laser sensor consists of several thermocouples connected in series with one junction type (hot junction at temperature T1) being exposed to an absorption area and the other junction type (cold junction at temperature T2) being exposed to a heat sink. When a laser beam hits the surface of a thermopile sensor, the incident radiation is absorbed within the coating layer and transformed into heat. This heat then induces a temperature gradient across the sensor given as
[K/m],
where t is the thickness of the sensor.[9]
Due to the thermoelectric effect, the temperature difference causes an electrical voltage to build up within each thermocouple. This output voltage is directly proportional to the power of the incoming radiation.[10] Since a large number of thermopiles are typically connected in series, voltages of several μV to V are reached.
In general, a thermopile sensor consists of three elements: an absorber, the sensor element and a cooling body to dissipate the incoming heat.
Absorber
[edit]Depending on the thickness of the absorption layer, the thermopile sensor can be classified into two categories.[11]
Surface absorber
[edit]For surface absorbers the thickness of the absorption layer is very thin (0.1 – 100 μm) and so is the total absorption length.[11] It is used for power measurements of lasers with long pulse length (generally for CW laser). If a laser with pulse length in the range of 10−7 – 10−4 sec is used the sensor can be damaged by either dielectric break-down or thermal effects.[12] In case of thermal damage, heat is deposited in a short time and cannot be dissipated until the next pulse arrives. This leads to an accumulation of energy in a thin layer leading to partial vaporization.[11] For dielectric breakdown, the peak energy density during a pulse is high enough to locally ionize the sensor surface.[13]
Volume absorber
[edit]To protect the sensor from damages by short optical pulses, volume absorbers are used with absorption lengths in the order of millimetres.[11] This enables volume absorbers to withstand higher pulse energy densities, since the optical power is absorbed over a considerable depth of material.[11]
Sensor geometry
[edit]
There are two main types of thermopile laser sensors which can be classified according to the geometric arrangement of the thermocouples inside the sensor element.
Radial thermopile sensor/Thermopile discs
[edit]Thermopile discs have thermocouples deposited onto an aluminium plate in a radial arrangement as shown in Fig 3(a).[8] All thermocouples are electrically connected in series with one junction at the circumference of the inner area which is illuminated and the other junction at the outer circumference.[8] The absorption coating in the illuminated area converts radiation into heat which flows radially outwards generating a temperature gradient between inner and outer ring and thus a thermoelectric voltage.[8]
Axial thermopile sensor
[edit]Fig 3(b) shows the cross sectional view of the axial sensor where the temperature difference is established between the top and bottom surfaces. Thermocouples are embedded into a matrix and aligned parallel with respect to the heat flow, forming junctions at top and bottom.[8] This arrangement permits a reduction of the total sensor thickness to 0.5 mm (Fig 4).[8]
Cooling/Heat management
[edit]It is crucial to dissipate the incoming heat in order to establish a stable temperature gradient across the sensor.[15] Therefore, the cold side of the sensor needs to be thermally coupled to a heat sink.
Passive cooling
[edit]In this method of cooling the cold side of the sensor is mounted onto a heat conductor (usually an aluminium heat sink), and heat is dissipated to the surrounding by conduction (through heat conductor) and convection (air flow).[15]
Active cooling
[edit]In this method of cooling the heat is actively transferred to the environment. This is usually done by mounting a fan on the heat sink of a passively cooled detector or by pumping water through a channel system to cool the sensor. The preferred choice depends on the amount of heat to be dissipated and thus on the detector power.
Characteristics
[edit]Sensitivity
[edit]The sensitivity S [V/W] is the ratio of voltage U [V] generated due to the incident laser power P [W] on the sensor. The voltage generated depends on the Seebeck coefficient of the thermoelectric material; hence it is a material specific constant.[9] The incident power can be calculated by measuring the sensor voltage and using the formula:
[W].
The effective sensitivity depends on the absorption property of the coating layer. For constant incident laser power a larger absorption coefficient means more heat is generated[16] leading to increase in output voltage.
Spectral range
[edit]The spectral range depends on the absorption characteristics of the coating material.[17] Typically, a flat absorption spectrum across a broad wavelength range is desired. It can also be tailored to a wavelength range or to a particular wavelength.
Rise time
[edit]The signal rise time is the time required by the sensor to reach 95 percent of the full signal amplitude when exposed to a step function of incident laser power. It depends on the overall thermal resistances and thermal capacitance of the sensor.[11] The magnitude of these two parameters depends on the detector materials and geometry [11] The rise time for axial sensors is usually shorter than for radial sensors since the axial sensors possess lower thermal mass and thermal resistance.[8] The difference can amount to a factor of 5 to 10 and is shown in Fig 5.[8]
Maximum power
[edit]The maximum power that can be measured accurately depends on the type of sensor, its material properties and the type of cooling used (see section 1.3).[12] Faulty measurements or even deterioration of the sensor can result due to too large irradiance.[12]
Maximum power density
[edit]The maximum laser power density for the sensor is given by the laser induced damage threshold of the coating material.[13] The threshold value depends on the wavelength of the laser, its pulse length and to a certain extent, on the structure of the absorbing surface [13]
| Pulse duration | t<10−9 | 10−9<t<10−7 | 10−7<t<−4 | t>10−4 |
|---|---|---|---|---|
| Damage mechanism | Avalanche ionization | Dielectric breakdown | Dielectric breakdown or thermal damage | Thermal damage |
| Relevant damage specification | N/A | Pulsed | Pulsed and CW | CW |
Sources of measurement errors
[edit]Temperature error
[edit]The sensitivity of the sensor varies with the mean sensor temperature. This is due to the temperature dependence of the Seebeck coefficient (see section 2.1).[18]
Since the dependence is quasi linear, the temperature error can be corrected by multiplying the measured value by a temperature dependent correction factor[19]
Background error
[edit]If the sensor temperature is different from the ambient temperature heat flows directly to the surrounding without contributing to the detected temperature gradient therefore effectively reducing the sensor output.[20] This type of error is on the order of few mW and is thus significant only at low incident powers[20]
The background error can be minimized by keeping the sensor at ambient temperature and avoiding convective air flows. It can also be corrected by subtracting the signal of a non-illuminated sensor (dark measurement).[19]
Applications
[edit]Thermopile laser sensors find their use mainly where sensitivity to a wide spectral range is needed or where high laser powers need to be measured. Thermopile sensors are integrated into laser systems and laser sources and are used for sporadic as well as continuous monitoring of laser power, e.g. in feedback control loops. Some of the applications are
Medical systems
[edit]According to EU standard (EN6001-1-22), every medical laser system needs to be equipped with a redundant power measurement unit. For procedures such as precise tissue cutting and ablation the laser power can be measured before operation or even continuously throughout the process. One possible means of integrating a thermopile sensor in a medical system is by using a shutter or beam reflector (Fig 6) which can be flipped into and out of the beam path for short measurement periods of the full laser power.[21]
Industrial systems
[edit]Manufacturing processes require precision and reproducibility. For laser materials processing the monitoring of laser power is beneficial as it can avoid scrap production and yield high quality products.
There are various ways of integrating a power measurement. In Fig 6 the integration in the beam path behind a beam splitter is shown. Fig 7 illustrates the option of mounting the detector behind the back mirror of a laser cavity for continuous monitoring. Beam losses further down the beam path, caused e.g. by a deterioration of optics, are not mapped in this type of arrangement.
As an alternative, detectors can be used for sporadic measurements at the laser system output. Usually, the full beam is measured in this case.[21]
Power meters
[edit]For sporadic measurements outside the laser system (e.g. during maintenance) a separate measuring unit is beneficial. For such a power meter, the sensor element is usually integrated into a metal housing for mechanical and thermal stability. The signal is recorded and processed in a read-out unit which displays the measured laser power (Fig 8).[21]
Ultrafast laser measurement
[edit]Short-pulsed lasers which are used in spectroscopy and optical communication can be measured using thermopile sensors since they possess high thresholds for laser induced damages, especially when equipped with a volume absorber. (see section 2.5).
Position detector
[edit]
An arrangement of several thermally coupled thermopile sensors similar to a quadrant photodiode design (Fig 9) can be used to detect beam position as well as beam power. This is useful for beam alignment purposes or for processes where a correct beam position is crucial for high production yield.[21]
Comparison between different types of detectors.
[edit]| Feature | Thermopile | Photodiode | Pyroelectric | Calorimeter |
|---|---|---|---|---|
| Physical principle | Thermoelectricity | Electrons hole combination | Pyro electricity | Thermoelectricity |
| Spectral Range | Broadband | narrow band | narrow band | broadband |
| Power Range | Low to medium | Low | Low to medium energies | Very high energies |
| Signal | Voltage(V) | Current(A) | Voltage(V) or Current(A) | Voltage(V) |
| Response time | High | Low | Low | High |
| Wavelength dependent sensitivity | No | Yes | No | No |
| Linear response | Yes | Yes, up to saturation | -- | -- |
| Effect of small variation of incident angle | Negligible | Significant | Negligible | Negligible |
References
[edit]- ^ "gRAY Sensors".
- ^ a b "Product Specification C-Series". Thorlabs. 6 May 2016. Retrieved 6 May 2016.
- ^ "Working Principle". gRAY. Retrieved 6 May 2016.
- ^ Bashar, Dr. Shabir A. (7 May 2016). "Study of Indium Tin Oxide (ITO) for Novel Optoelectronic Devices". Retrieved 7 May 2016.
- ^ "Throlabs C-Series Power Meter". 6 May 2016. Retrieved 6 May 2016.
- ^ J. Weidner (2009). Integrated Optoelectronics 4, Issue 41. The Electrochemical Society. ISBN 9781566777223.
- ^ a b c "Comparison of pyroelectric and thermopile", Norbert Neumann, Victor Banta, Infra Tec GmbH, Gostritzer Str.61-61, 01217 Dresden, Germany and Dexter Research Center, Inc., 7300 Huron River Drive, Dexter; MI 48130, USA
- ^ a b c d e f g h i j ʺReinventing Thermal Laser Power Measurementsʺ, Lasers in Manufacturing Conference 2015, S. Dröscher, M. Zahner, E. Schwyter, T. Helbling and C. Hierold
- ^ a b D. Pollock, Daniel (1985). Thermoelectricity: Theory, Thermometry, Tool, Issue 852. ASTM International. ISBN 9780803104099.
- ^ "gRAY Laser Power Detectors by greenTEG". gRAY - Laser Power Detectors. Retrieved 2016-04-28.
- ^ a b c d e f g "Thermopile Laser Power Sensor Technology Tutorial". www.newport.com. Retrieved 2016-04-28.
- ^ a b c d "Laser induced damage threshold". thorlabs.com.
- ^ a b c "Laser Induced Damage". RP Photonics.
- ^ "B01-SC". gRAY, greenTEG.
- ^ a b John H Lienhard (2019). A Heat Transfer Textbook: 5th Edition. Dover Pub.
- ^ Hugh H. Richardson, Michael T. Carlson, Peter J. Tandler, Pedro Hernandez, and Alexander O. Govorov (6 May 2016). "Experimental and theoretical studies of light-to-heat conversion and collective heating effects in metal nanoparticle solutions". Nano Lett. 9 (3): 1139–46. doi:10.1021/nl8036905. PMC 2669497. PMID 19193041.
{{cite journal}}: CS1 maint: multiple names: authors list (link) - ^ IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "Absorbance".
- ^ Kengo Kishimoto, Masayoshi Tsukamoto and Tsuyoshi Koyanagi (6 May 2016). "Temperature dependence of the Seebeck coefficient and the potential barrier scattering of n-type PbTe films prepared on heated glass substrates by rf sputtering". Journal of Applied Physics. 92 (9): 5331–5339. doi:10.1063/1.1512964.
- ^ a b "Thermal Management for Thermopile Laser Power Sensors" (PDF). gRAY. 6 May 2016. Retrieved 6 May 2016.
- ^ a b "Thermocouples: Theory". 6 May 2016. Retrieved 6 May 2016.
- ^ a b c d e f "Applications" (PDF). gray.greenteg.com. 2015-08-18.
- ^ "Thorlabs Power Meter". thorlabs.com.
- ^ "Position Sensor". gray.greenteg.com.
- ^ "Thermal sensor vs Photodiode" (PDF). gray.greenteg.com. 6 May 2016. Retrieved 6 May 2016.
- ^ Gentec EO Product Guide. gentec EO. 2014.
