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--- groups:mg:experiment:laser:285nmlaser [2015/09/01 21:40] – klaus
+++ groups:mg:experiment:laser:285nmlaser [2022/04/06 05:51] (current) – [Locking to Iodine-Spectroscopy] wfriesen
@@ Line 1: / Line 1: @@
 ====== 285 nm-Laser (S-MOT) ======
 The 285 nm Laser consists of a two-stage frequency doubled, raman-fiber-amplifier MOPA. The raman-fiber-amplifier is seeded by a diode laser.
-* Laser-Diode current: .. mA
+  * Laser-Diode current: 280 mA   @which settings?
-* Seed power (is displayed in the //FLPM RMU CCT 1.1.0.0// program): ~ 20 mW
+  * Seed power (is displayed in the //FLPM RMU CCT 1.1.0.0// program): ~ 20 mW
-<note important>Change values</note>
 ===== Turning on the Laser =====
-	* Enable main-switch. Set key to standby.
+	* Enable main-switch. Now set the key to standby.
 	* Wait for the LED to change the color from orange to green to orange (~15 seconds after turning on). Turn the key now.
 	* Start the program //FLPM RMU CCT 1.1.0.0// and select the checkbox of //Laser Enable//.
@@ Line 14: / Line 13: @@
 		* //2 - 2.500 W// for //100-150 mW// directly after 285 nm SHG.
 		* Do not exceed much more than //3.5 W//
+	* Flush the SHG with oxygen, by opening the bypass for roughly 10 seconds.
+	* Scan the SHG and optimize the incoupling and crystal position
+	* Lock the SHG, the voltmeter should display a value around 115 mV (@ 2 W Power Setpoint)
+	* Activate the powerstabilization
+===== Turning off the Laser =====
+	* Unlock the laser in DigiLock
+	* Now just turn off the main-power on the laser
+	* Disable oxygen to 285nm SHG.
 ===== Locking to Iodine-Spectroscopy =====
@@ Line 23: / Line 30: @@
             * Move the crosshair to the second slope, rightclick on press //PID: Lock to Slop//.
-==== Lock-Paramters ====
-<note important>Add parameters</note>
+        * **Troubleshooting**
+            * If signal in DigiLock-Software does not update/ signal is frozen  -> click the sampling checkbar to activate
+            * If signal in DigiLock-Software does not show the usual error-signal at correct frequency, but is saturated at left and right edge of the frame (see picture) -> Check the ref input for the lock-in-amplifier (near the iodine spectroscopy). Probably the input signal is too low. It should be slightly higher than 2 V (~2.2V works fine).{{ :groups:mg:experiment:laser:img-20210119-wa0001.jpg?400|}}
 ===== Lasersystem - Typical power values =====
-<note important>Kürzen und nur das wichtigste angeben</note>
 The 285nm SHG was build by Jan Friebe and is described in his diplomathesis.
 === 570 nm-Laser ===
-	* Outputpower after cube to 285 nm-SHG: ~ 1.2 W @ 2.5 W
+	* Outputpower after cube to 285 nm-SHG: ~ 1.2 W @ 2.5 W 1140nm pump
 	* Operationpower: < @ 3 W
 	* Max outpupower: ??? W @ ??? W
@@ Line 39: / Line 45: @@
 === Iodine spectroscopy ===
-	* Infront fiber: 	~ 38 mW @ 0.500 W
+== 500 mW pump of the yellow laser ==
+	* Infront fiber: 	~ 38 mW
 	* After fiber: 	~ 29 mW @ 0.500 W (= 400 mV @ 0.500 W) [efficiency ~ 70 %]
-	* Infront fiber: 	~ 220 mW @ 2.500 W
+== Normal operation (2-3 W) ==
-	* After fiber: 	~ 160 mW @ 2.500 W (= 2 V @ 2.500 W) [efficiency ~ 70 %]
+	* After fiber: ~ 100 mW
+	* At iodine cell: 20-40 mW
 ==== 285 nm-SHG ====
+	* Outputpower: ~ **100+ mW** @ 2.000 W
+	* Stabilized power (infront AOM): **80-90 mW**
+	* Power behind the AOM: **43** mW @ 2.000 W (efficiency ~ 50 %)
-	* Outputpower: ~ ... mW @ 2.000 W
+	* Power for the Zeaman-slower: **10 mW**
-	* Outputpower: ~ 100 mW @ 2.500 W
-	* Power for photodiode: ~ ... müW
-	* Stabilized power (infront AOM): **80 mW**
-	* Power infront the AOM in ... order: 80 mW
-	* Power behind the AOM: 43 mW @ 2.500 W (efficiency ~ 50 %)
-	* Power for the Zeaman-slower: ... mW
-	* Power behind the mystical mirrow: ... mW
+	* Power behind the mystical mirrow: **30 mW**

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