docs: replace Greek 'μ' with micro 'µ' again

Author: ddcc4

api/docs/v2/liquid_classes.rst

@@ -235,9 +235,9 @@ Next, edit individual liquid class properties based on your Flex pipette and tip
 
 .. code-block:: python
     
-  # edit aspirate submerge speed to 80 μL/sec
+  # edit aspirate submerge speed to 80 µL/sec
     custom_water_properties.aspirate.submerge.speed = 80
-  # edit aspirate flow rate by volume for 10 μL and 20 μL volumes
+  # edit aspirate flow rate by volume for 10 µL and 20 µL volumes
     custom_water_properties.aspirate.flow_rate_by_volume.set_for_volume(volume=10.0, value=40.0)
     custom_water_properties.aspirate.flow_rate_by_volume.set_for_volume(volume=20.0, value=30.0)
   # edit to delay for 1 sec before retracting after an aspirate

api/docs/v2/versioning.rst

@@ -170,7 +170,7 @@ Version 2.25
 -------------
 
 - Adds :py:class:`.FlexStackerContext` to support the :ref:`Flex Stacker Module <stacker>`. Use the load name ``flexStackerModuleV1`` with :py:meth:`.ProtocolContext.load_module` to add a Flex Stacker and automate labware storage in a protocol.
-- Use the load name ``flex_96channel_200`` with :py:meth:`.load_instrument` to add the Opentrons Flex 96-Channel Pipette (1–200 μL) to a protocol. Note that this pipette does not work with liquid class commands in this API version. 
+- Use the load name ``flex_96channel_200`` with :py:meth:`.load_instrument` to add the Opentrons Flex 96-Channel Pipette (1–200 µL) to a protocol. Note that this pipette does not work with liquid class commands in this API version. 
 
 Version 2.24
 -------------

api/release-notes.md

@@ -31,7 +31,7 @@ Use Opentrons Tough Universal Lids on compatible well plates and reservoirs.
 
 ### Improvements
 
-Transfer aqueous, viscous, or volatile liquids with the Opentrons Flex 96-Channel Pipette (1–200 μL) to apply optimized, liquid class transfer behavior to volumes as low as 1 µL.
+Transfer aqueous, viscous, or volatile liquids with the Opentrons Flex 96-Channel Pipette (1–200 µL) to apply optimized, liquid class transfer behavior to volumes as low as 1 µL.
 
 ### Bug Fixes
 
@@ -45,12 +45,12 @@ Welcome to the v8.6.0 release of the Opentrons robot software! This release adds
 ### New Features
 
 - Automate labware storage with the Flex Stacker Module. Use new commands like `retrieve()` and `store()` to move well plates, reservoirs, or Flex tip racks to and from the Stacker during a protocol.
-- This release adds support for the Opentrons Flex 96-Channel Pipette (1–200 μL) to transfer as little as 1 µL in a protocol.
+- This release adds support for the Opentrons Flex 96-Channel Pipette (1–200 µL) to transfer as little as 1 µL in a protocol.
 - Control individual robot motors, like the gantry, extension mount, or gripper, with new commands.
 
 ### Known Limitations
 
-- The Opentrons Flex 96-Channel Pipette (1–200 μL) does not yet support liquid classes. Use legacy liquid-handling commands from the Python Protocol API.
+- The Opentrons Flex 96-Channel Pipette (1–200 µL) does not yet support liquid classes. Use legacy liquid-handling commands from the Python Protocol API.
 - The Flex Gripper can't currently sense if it has failed to pick up a labware lid.
 - Certain partial tip pickup actions adjacent to a Flex Stacker raise an error, even though no collision would occur.
 - Certain robot motor control commands don't appear properly in the run log. The commands are still functional.

docs/flex/docs/labware/concepts.md

@@ -22,7 +22,7 @@ Custom labware is labware that is not included in the Labware Library or was cre
 
 Let's take a moment to unpack the concept of custom labware. 
 
-As an example, the Opentrons Labware Library includes 96-well plates (200 µL) from Corning and Bio-Rad, but other manufacturers make these well plates too. And, thanks to commonly accepted industry standards, the differences among these ubiquitous lab items are minor. However, an ordinary 200 μL, 96-well plate from Stellar Scientific, Oxford Lab, or Krackeler Scientific (or any other supplier for that matter) is "custom labware" for the Flex because it isn't pre-defined in our Labware Library. Additionally, minor differences in labware dimensions can have a drastic impact on the success of your protocol run. For this reason, it's important to have an accurate labware definition for each labware you want to use in your protocol. 
+As an example, the Opentrons Labware Library includes 96-well plates (200 µL) from Corning and Bio-Rad, but other manufacturers make these well plates too. And, thanks to commonly accepted industry standards, the differences among these ubiquitous lab items are minor. However, an ordinary 200 µL, 96-well plate from Stellar Scientific, Oxford Lab, or Krackeler Scientific (or any other supplier for that matter) is "custom labware" for the Flex because it isn't pre-defined in our Labware Library. Additionally, minor differences in labware dimensions can have a drastic impact on the success of your protocol run. For this reason, it's important to have an accurate labware definition for each labware you want to use in your protocol. 
 
 Also, while custom labware could be an esoteric, one-off piece of kit, most of the time it's just the tips, plates, tubes, and racks used every day in labs all over the world. Again, the only difference between Opentrons labware and custom labware is that the custom labware is not predefined in the software that powers the robot. The Flex can, and does, work with other basic labware items or something unique, but you need to record that item's characteristics in a labware definition JSON file and import that data into the Opentrons App. See the [Labware Definitions section](definitions.md) for more information. 
 

docs/flex/docs/labware/types.md

@@ -83,7 +83,7 @@ Flex pipettes only accept tips with capacities less than or equal to the pipette
 | Pipette capacity | Compatible tips             |
 | :--------------- | :-------------------------- |
 | 1–50 µL          | 50 µL tips only             |
-| 5–1000 µL        | 50 μL, 200 μL, and 1000 µL tips |
+| 5–1000 µL        | 50 µL, 200 µL, and 1000 µL tips |
 
 For best performance, use the smallest tips that can hold the amount of liquid you need to aspirate. See [Pipette specifications][pipette-specifications] for examples. 
 

docs/flex/docs/modules/hepa-uv.md

@@ -10,13 +10,13 @@ title: "Opentrons Flex: HEPA/UV Module"
 The top-mounted Opentrons Flex HEPA/UV Module is a clean air and ultraviolet (UV-C) disinfectant accessory for the Flex liquid handling robot. It contains a mesh pre-filter, a HEPA filter, and two UV lights. During operation, the HEPA system creates a positive pressure environment inside the Flex enclosure, which helps protect samples from contamination. When running the UV lights and air filtration for a full, 15-minute cycle, the HEPA/UV module can achieve ISO-5 clean bench standards within the Flex enclosure.
 
 !!!warning
-    The HEPA/UV Module is not a biosafety cabinet. Do not use it with pathogens or to filter particles smaller than 0.3 micrometers (μm).
+    The HEPA/UV Module is not a biosafety cabinet. Do not use it with pathogens or to filter particles smaller than 0.3 micrometers (µm).
 
 ## HEPA/UV Module features
 
 ### Air filtration
 
-The HEPA/UV Module relies on a 2-stage filtration system to purify air pulled into the enclosure. This system includes a reusable pre-filter and a disposable H14 HEPA main filter. The pre-filter traps large particles while the HEPA filter captures up to 99.99% of airborne particulate matter at ≥ 0.3 μm. Vertical air flow from the filter creates a positive pressure environment within the enclosure.
+The HEPA/UV Module relies on a 2-stage filtration system to purify air pulled into the enclosure. This system includes a reusable pre-filter and a disposable H14 HEPA main filter. The pre-filter traps large particles while the HEPA filter captures up to 99.99% of airborne particulate matter at ≥ 0.3 µm. Vertical air flow from the filter creates a positive pressure environment within the enclosure.
 
 ### UV disinfection
 

docs/flex/docs/system-description/pipettes.md

@@ -236,7 +236,7 @@ The User Kit includes a metal pipette calibration probe, which you use during po
 
 ![The 96-channel tip rack adapter.](../images/96-channel-tip-rack-adapter.png "96-channel tip rack adapter")
 
-The Opentrons Flex 96-channel pipette ships with four tip rack adapters. These are precision formed aluminum brackets that you place on the deck. The adapters hold Flex 50 μL, 200 μL, and 1000 µL tip racks.
+The Opentrons Flex 96-channel pipette ships with four tip rack adapters. These are precision formed aluminum brackets that you place on the deck. The adapters hold Flex 50 µL, 200 µL, and 1000 µL tip racks.
 
 Because of the force involved, the 96-channel pipette requires an adapter to attach a full tip rack properly. During the attachment procedure, the pipette moves over the adapter, lowers itself onto the mounting pins, and pulls tips onto the pipettes by lifting the adapter and tip rack. Pulling the tips, rather than pushing, provides the leverage needed to secure tips to the pipettes and prevents warping the deck surface. When finished, the 96-channel pipette lowers the adapter and empty tip rack onto the deck. See the [Tips and Tip Racks section][tips-and-tip-racks] of the Labware chapter for more information.
 

docs/flex/docs/touchscreen/quick-transfer.md

@@ -68,15 +68,15 @@ After making instrument and well selections, you'll set the transfer volume and
 
 ## Transfer volumes and name
 
-You'll set the amount of liquid to transfer (in μL) after specifying the source and destination wells. You'll also have a chance to name the transfer after setting the transfer volume. A good, concise name helps you find a quick transfer in a list of saved or pinned transfers and indicates what it does.
+You'll set the amount of liquid to transfer (in µL) after specifying the source and destination wells. You'll also have a chance to name the transfer after setting the transfer volume. A good, concise name helps you find a quick transfer in a list of saved or pinned transfers and indicates what it does.
 
 ## Advanced settings
 
 These are available after you name a quick transfer and before you save it. If some settings are familiar to you that's because they're the same as those offered in Protocol Designer. Advanced settings are optional; select any that you need or just save or run the transfer.
 
 | Setting {style="width: 25%;"} | Description |
 |----------|-------------|
-| Aspirate and dispense flow rates | Set how quickly the pipette will aspirate or dispense, in μL/s.|
+| Aspirate and dispense flow rates | Set how quickly the pipette will aspirate or dispense, in µL/s.|
 | Pipette path           | Choose how the pipette moves between wells. Options include:<br><ul><li>single transfer (1 well to 1 well)</li><li>multi-aspirate (many wells to 1 well)</li><li>multi-dispense (1 well to many wells)</li></ul> |
 | Tip position           | Change where in the well the pipette aspirates or dispenses. By default, the robot positions the tip 1 mm from the bottom center of a well. |
 | Pre-wet tip            | Pre-wet the pipette tip by aspirating and dispensing ⅔ of the tip's maximum volume. |

docs/hepa-uv/docs/hepa-specs.md

@@ -2,7 +2,7 @@
 title: "HEPA/UV Module: HEPA Specifications"
 ---
 
-The Flex HEPA/UV Module uses a two-stage filtration system to purify air pulled into the enclosure. This system includes a reusable pre-filter and a disposable H14 HEPA main filter. The pre-filter traps large particles while the HEPA filter captures up to 99.99% of airborne particulate matter at ≥ 0.3 microns (μm). Vertical air flow from the HEPA filter creates a positive-pressure environment within the enclosure. This air boundary helps protect samples inside the Flex from external contamination. The air cleaning system of the Flex HEPA/UV Module meets ISO-5 clean bench standards.
+The Flex HEPA/UV Module uses a two-stage filtration system to purify air pulled into the enclosure. This system includes a reusable pre-filter and a disposable H14 HEPA main filter. The pre-filter traps large particles while the HEPA filter captures up to 99.99% of airborne particulate matter at ≥ 0.3 microns (µm). Vertical air flow from the HEPA filter creates a positive-pressure environment within the enclosure. This air boundary helps protect samples inside the Flex from external contamination. The air cleaning system of the Flex HEPA/UV Module meets ISO-5 clean bench standards.
 
 <figure style="width: 50%;" markdown>
 ![HEPA filtration airflow diagram](images/hepa-uv-airflow.svg "HEPA filtration airflow diagram")
@@ -14,6 +14,6 @@ The Flex HEPA/UV Module uses a two-stage filtration system to purify air pulled
 |---|---|
 | ISO clean bench standards | ISO-5 |
 | Pre-filter | <ul><li>Metal mesh</li><li>Reusable</ul> |
-| HEPA filter | <ul><li>Grade H14</li><li>99.99% efficiency for particles ≥ 0.3 μm</li><li>Disposable</ul> |
+| HEPA filter | <ul><li>Grade H14</li><li>99.99% efficiency for particles ≥ 0.3 µm</li><li>Disposable</ul> |
 | HEPA filter lifetime | 3 years of use (~6,000 hours) |
 | Ambient fan noise | ≤ 70 dB at 1 meter during fan operation |

opentrons-ai-server/api/storage/docs/pd/step_doc.md

@@ -3825,29 +3825,29 @@ Pipette:
 - Left mount: p1000 single channel Flex pipette
 
 Labware:
-- Tiprack-1: Opentrons Flex 96 Filter Tip Rack 1000 μL (Slot D1)
-- Tiprack-2: Opentrons Flex 96 Filter Tip Rack 1000 μL (Slot C1)
-- Plate: NEST 96 Well Plate 200 μL Flat (Slot D3)
+- Tiprack-1: Opentrons Flex 96 Filter Tip Rack 1000 µL (Slot D1)
+- Tiprack-2: Opentrons Flex 96 Filter Tip Rack 1000 µL (Slot C1)
+- Plate: NEST 96 Well Plate 200 µL Flat (Slot D3)
 - Reservoir: NEST 12 Well Reservoir 15 mL (Slot D2)
 
 
 Liquids:
 - Diluent liquid (green, 12 mL in reservoir well A1)
-- Sample liquid (red, 150 μL in each well of column 1 of the plate)
+- Sample liquid (red, 150 µL in each well of column 1 of the plate)
 
 Steps:
-1. Distribute 100 μL of diluent from reservoir well A1 to all wells in columns 2-11 of the plate (with 10 μL air gap during aspiration and 5 μL disposal volume)
+1. Distribute 100 µL of diluent from reservoir well A1 to all wells in columns 2-11 of the plate (with 10 µL air gap during aspiration and 5 µL disposal volume)
 
 2. Perform serial dilutions for Row A:
- - Transfer 50 μL from A1 to A2, mix 5× with 75 μL
- - Transfer 50 μL from A2 to A3, mix 5× with 75 μL
+ - Transfer 50 µL from A1 to A2, mix 5× with 75 µL
+ - Transfer 50 µL from A2 to A3, mix 5× with 75 µL
  - Continue this pattern through A10 to A11
- - Use 10 μL air gap during aspiration
+ - Use 10 µL air gap during aspiration
  - Change tip once for the entire row
 
 3-9. Repeat the same serial dilution pattern for Rows B through H (one row at a time)
 
-10. Add 100 μL blank (diluent) to the last column (column 12) of the plate
+10. Add 100 µL blank (diluent) to the last column (column 12) of the plate
 ```
 
 Output protocol: