Name of this Object.

ID of this Object.

Object of this Object.

Type of this Object.

Notebook this object belongs to.

Objects that represent instances of this model.

Indicates if this instrument model is historical and no longer used in the lab.

The person(s) who created this instrument model.

An example photo of this model of instrument.

PDFs for the manuals or instruction guides for this model of instrument.

Detailed drawings of the instrument that explain its capabilities and limitations.

The type(s) of the power source(s) used by instruments of this model.

All battery requirements for battery-powered instruments of this model.

Estimated power consumption rate of the instrument in Watts (Joule/Second).

All data connector requirements needed to interface the instruments of this model with a computer.

Operating system that the software of instruments of this model runs on.

All PCICard requirements needed to install specialized hardware.

Indicates if an instrument of this model requires a security dongle in the computer to run.

Items installed with the instrument for full function.

The type of waste generated by this instrument.

A list of the measurement modules on this instrument.

The type of the component of the mass spectrometer that performs ion separation based on mass-to-charge (m/z) ratio. The type of the component of the mass spectrometer that performs ion separation based on mass-to-charge (m/z) ratio. Time of flight (TOF) analyzers accelerate and resolve ions using an applied electrical field, thereby resolving ions by their flight path (a function of m/z). QTOF (quantitative time of flight) mass analyzer can perform two accelerations and also measure ion fragments.

The type of ionization source used to generate gas phase ions from the molecules in the sample. Electrospray ionization (ESI) produces ions using an electrospray in which a high voltage is applied to a liquid to create an aerosol, and gas phase ions are formed from the fine spray of charged droplets as a result of solvent evaporation and Coulomb fission. In matrix-assisted laser desorption/ionization (MALDI), the sample is embedded in a laser energy absorbing matrix which is then irradiated with a pulsed laser, ablating and desorbing the molecules with minimal fragmentation and creating gas phase ions from the analyte molecules in the sample.

The possible detection modes for ions (in Negative mode, negatively charged ions and in Positive mode, positively charged ions are generated and analyzed).

Data acquisition functions that can be performed on this instrument.

The type of focusing element for the ions.

Boolean describing whether or not the TOF mass spectrometer is equipped with a ion mirror (reflectron) to increase the flight path of the ions in the flight tube and improve mass accuracy.

Wavelength of the laser used for desorption/ionization.

Duration of each laser pulse used for desorption/ionization.

The shot frequency of the laser used for desorption/ionization.

Power of the laser used for desorption/ionization.

The rate charged by the ECL for time used on this instrument in the course of conducting user experiments.

The generic billing category this instrument model will be listed under.

With respect to cost, the category of devices, for which this Instrument falls into.

All electrical requirements for plug-in parts of this model.

Generates a pattern of all the valid position names for this model of instrument.

A list of materials in the instrument which may be wetted by user-specified liquids.

PDFs for facility requirements and pre-installation checkoff forms provided by the supplier for instruments of this model.

The external dimensions of this model of instrument.

The shape of this model of instrument in the X-Y plane.

A top-down (X-Y plane) image of this model of instrument which can be overlaid on a 2D container plot.

A Graphics primitive corresponding to the 2D shape of this model of instrument.

A Graphics primitive corresponding to the 3D shape of this model of instrument.

Spatial definitions of the positions that exist in this model of instrument.

Readily available configurations of container models in specified positions on the deck of this instrument model.

The largest diameter of a syringe that can fit in the syringe pump of the mass spetrometer.

The longest syringe (in centimeter) that can fit in the syringe pump of the mass spetrometer.

Items required to be present in the local cache for instruments of this model, along with the required quantity of each item.

The physical conditions such as temperature and humidity this instrument provides for samples stored long term within it.

Specifications for the ports on this model of instrument that may connect to other plumbing components.

Specifications for the wiring ends of this instrument that may plug into and conductively connect to other items, parts or instruments.

A list of the Qualifications which should be run on instruments of this model and their required frequencies.

A list of the maintenance protocols which should be run on instruments of this model and their required frequencies.

A list of tracked replacement part models for this instrument.

Indicates if the exterior surfaces of this instrument model can be cleaned while in use.

The minimum flow rate of air generated by the instrument's ventilator for its safe and proper function.

The flow rate of air generated by the instrument's ventilator recommended by its manufacturer.

Indicates if the instrument is required to operate continuously in the lab, regardless of if it is InUse by a specific protocol, such as a freezer.

The company that originally manufactured this model of instrument.

A list of instruments for which this model is an accompanying accessory.

Indicates that this model of instrument is used for protocols where SterileTechnique is indicated to be used.

Indicates the type of cellular samples (Mammalian or Microbial) that this instrument is used to handle.

Indiciates that this model of instrument permanently resides in the glove box.

Hazards to be aware of during operation of instruments of this model.

Special handling considerations that samples on this instrument require.

Type of sensors which cannot monitor the internal contents of instruments of this model from the outside.

The lowest value of mass-to-charge ratio (m/z) the instrument can detect.

The highest value of mass-to-charge ratio (m/z) the instrument can detect.

Indicate if this intrument is capable of conducting tandem mass spectrometry.

For the Mass Spectrometer that has tandem mass spectrometry feature, this value indicate the lowest value of mass-to-charge ratio (m/z) that the second mass analyzer (MS2) of instrument can detect.

For the Mass Spectrometer that has tandem mass spectrometry feature, this value indicate the highest value of mass-to-charge ratio (m/z) that the second mass analyzer (MS2) of instrument can detect.

For the Mass Spectrometer that has tandem mass spectrometry feature, this value indicate the highest value of voltage that could be applied to the collision cell.

For the Mass Spectrometer that has tandem mass spectrometry feature, this value indicate the lowest value of voltage that could be applied to the collision cell.

For some Mass Spectrometers that has tandem mass spectrometry feature (e.g. ESI-QQQ), this value indicate the highest value of voltage that could be applied between the exit point of the collision cell and the second mass analyzer.

For some Mass Spectrometers that has tandem mass spectrometry feature (e.g. ESI-QQQ), this value indicate the lowest value of voltage that could be applied between the exit point of the collision cell and the second mass analyzer.

The minimum voltage the instrument can apply to the the grid eletrode.

The maximum voltage the instrument can apply to the grid electrode.

The minimum voltage that can be applied to the ion focusing lens located at the entrance of the mass analyser.

The maximum voltage that can be applied to the ion focusing lens located at the entrance of the mass analyser.

The minimum voltage that can be applied to the guide wire used to focus the divergent ions in the mass analyzer.

The maximum voltage that can be applied to the guide wire used to focus the divergent ionsin the mass analyzer.

The minimum voltage the instrument can apply to the target plate to accelerate the ions.

The maximum voltage the instrument can apply to the target plate to accelerate the ions.

The minimum number of laser shots that can be fired at each spot.

The maximum number of laser shots that can be fired at each spot.

The minimum delay between laser ablation and ion extraction accepted by the instrument.

The maximum delay between laser ablation and ion extraction accepted by the instrument.

Minimum voltage that can be applied to the stainless steel capillary from which the ion spray is generated.

Maximum voltage that can be applied to the stainless steel capillary from which the ion spray is generated.

Minimum voltage that indicates the voltage between the ion block (the reduced-pressure chamber of the source block) and the stepwave ion guide (the optics before the quadrupole mass analyzer) for ESI-QTOF; Or the voltage applied between the orifice (where ions enter the mass spectrometer) and the ion guide to prevent the ionized small particles from aggregating together for ESI-QQQ.

Maximum voltage that indicates the voltage between the ion block (the reduced-pressure chamber of the source block) and the stepwave ion guide (the optics before the quadrupole mass analyzer) for ESI-QTOF; Or the voltage applied between the orifice (where ions enter the mass spectrometer) and the ion guide to prevent the ionized small particles from aggregating together for ESI-QQQ.

Minimum voltage that can be applied on the Ion guide to guides and focuses the ions through the high-pressure Ion guid region, this parameter is also labeled as Entrance Potential (EP).

Maximum voltage that can be applied on the Ion guide to guides and focuses the ions through the high-pressure Ion guid region, this parameter is also labeled as Entrance Potential (EP).

The minimum temperature setting for the source block (the reduced pressure chamber holding the sample cone through which the ions travel on their way to the mass analyzer).

The maximum temperature setting for the source block (the reduced pressure chamber holding the sample cone through which the ions travel on their way to the mass analyzer).

The minimum temperature setting for the source desolvation heater that controls the nitrogen gas temperature used for solvent cluster evaporation before ions enter the mass spectrometer through the sampling cone.

The maximum temperature setting for the source desolvation heater that controls the nitrogen gas temperature used for solvent cluster evaporation before ions enter the mass spectrometer through the sampling cone.

The minimum nitrogen gas flow ejected around the sample inlet cone to encourage solvent cluster evaporation.

The maximum nitrogen gas flow ejected around the sample inlet cone to encourage solvent cluster evaporation.

The minimum nitrogen gas flow ejected around the ion source capillary to encourage solvent evaporation.

The maximum nitrogen gas flow ejected around the ion source capillary to encourage solvent evaporation.

Minimum voltage that between the 1st and 2nd stage of the ion guide which leads ions coming from the sample cone towards the quadrupole mass analyzer.

Maximum voltage that between the 1st and 2nd stage of the ion guide which leads ions coming from the sample cone towards the quadrupole mass analyzer.

The minimum flow rate at which the instrument can pump buffer or sample into the system via the built-in syringe pump system.

The maximum flow rate at which the instrument can pump buffer or sample into the system via the built-in syringe pump system.