Vapor delivery apparatus, associated vapor phase reactor and methods of use

What is claimed is: 1 . A vapor delivery apparatus configured for converting a solid source material to a gaseous precursor for use in a vapor phase reactor, the apparatus comprising: a vessel comprising a vessel interior; a fluidized bed region disposed within the vessel interior, the fluidized bed region configured for containing a plurality of solid precursor particles; a carrier gas inlet into the vessel interior; a heating system configured for heating the fluidized bed region; a pressure sensing system constructed and arranged to generate a differential pressure signal (ΔP s ) by monitoring a pressure drop (ΔP) across the plurality of solid precursor particles when a carrier gas flows upwards through the plurality of solid precursor particles to form a fluidized bed within the fluidized bed region, wherein the pressure sensing system comprises a first pressure sensor device disposed upstream of the fluidized bed region and a second pressure sensor device disposed downstream of the fluidized bed region to monitor the pressure drop across the plurality of solid precursor particles; and a control system constructed and arranged to receive the differential pressure signal (ΔP) from the pressure sensing system and calculate a remaining weight (W) of the plurality of solid precursor particles within the fluidized bed region. 2 . The apparatus of claim 1 , wherein the first pressure sensor device comprises a first pressure sensor disposed upstream of the carrier gas inlet and the second pressure sensor device comprises a second pressure sensor disposed downstream of the vessel interior. 3 . The apparatus of claim 1 , wherein the pressure sensing system comprises a differential pressure sensor wherein the first pressure sensor device comprises a first port and the second pressure sensor device comprises a second port. 4 . The apparatus of claim 1 , further comprising an alert system linked to the control system, wherein the alert system is configured to be activated by an alert signal generated from the control system when the remaining weight of the plurality of solid precursor particles within the vessel interior reaches a predetermined minimum value. 5 . The apparatus of claim 1 , further comprising a low-pass filter configured to reduce fluctuations in the differential pressure signal (ΔP s ). 6 . The apparatus of claim 5 , wherein the low-pass filter comprises at least one of a buffer volume disposed downstream of the vessel interior, or an electrical circuit disposed within the control system. 7 . The apparatus of claim 1 , further comprising a distribution plate disposed upstream of the fluidized bed region, wherein the carrier gas inlet is disposed upstream of the distribution plate. 8 . The apparatus of claim 1 , further comprising a filter disposed downstream of the fluidized bed region and configured to filter solid precursor particles from the gaseous precursor generated from the plurality of solid precursor particles. 9 . A vapor phase reactor in fluid communication with the vapor delivery apparatus of claim 1 . 10 . A vapor phase reactor configured for vapor processing of substrates, comprising: a vapor delivery apparatus comprising; a carrier gas inlet; a fluidized bed region disposed within an inner volume of the vapor delivery apparatus, the fluidized bed region constructed and arranged to allow a carrier gas to lift and stir a plurality of solid precursor particles to form a fluidized bed; a heater configured to heat the fluidized bed region; a precursor gas outlet disposed downstream of the fluidized bed region; a pressure sensing system constructed and arranged to monitor a pressure drop (ΔP) across the fluidized bed and generate a differential pressure signal (ΔP) from said pressure drop, wherein the pressure sensing system comprises a first pressure sensor disposed upstream of the fluidized bed region and a second pressure sensor disposed downstream of the fluidized bed region; and a vapor phase reaction chamber in fluid communication with the vapor delivery apparatus, wherein the vapor phase reaction chamber is configured to receive a gaseous precursor generated in the vapor delivery apparatus; a reactor control system constructed and arranged to receive the differential pressure signal (ΔP s ) from the pressure sensing system and calculate a remaining weight of the fluidized bed; and an alert system linked to the reactor control system, wherein the alert system is configured to be activated by a signal generated from the reactor control system in response to the weight of the fluidized bed reaching a predetermined minimum value. 11 . The vapor phase reactor of claim 10 , further comprising a low-pass filter configured to reduce fluctuations in the differential pressure signal (ΔP). 12 . The vapor phase reactor of claim 11 , wherein the low-pass filter comprises at least one of a buffer volume disposed downstream of the inner volume, or an electrical circuit disposed within the reactor control system. 13 . A method for monitoring and controlling a vapor delivery system, the method comprising: flowing a carrier gas upward through a plurality of solid source particles within an inner volume of a vessel to form a fluidized bed comprising a bed weight; generating a gaseous precursor from the fluidized bed by vaporizing a portion of the plurality of solid source particles; monitoring a pressure differential (ΔP) across the fluidized bed as the gaseous precursor is generated by sensing a first pressure upstream of the fluidized bed and a second pressure downstream of the fluidized bed; calculating a remaining bed weight within the fluidized bed as the bed weight reduces as a result of the vaporization of a portion of the plurality of solid source particles; and activating an alert system in response to the remaining bed weight being less than a predetermining minimum value. 14 . The method of claim 13 , wherein monitoring the pressure differential (ΔP) across the fluidized bed comprises monitoring the pressure differential (ΔP) utilizing a pressure sensing system. 15 . The method of claim 14 , wherein the pressure sensing system comprises at least two pressure sensors, a first pressure sensor disposed upstream of the fluidized bed and a second pressure sensor disposed downstream of the fluidized bed. 16 . The method of claim 14 , wherein the pressure sensing system comprises a differential pressure sensor comprising two ports, a first port fluidly coupled upstream of the fluidized bed and a second port fluidly coupled downstream of the fluidized bed. 17 . The method of claim 14 , further comprising employing a low-pass filter to reduce any fluctuations in the monitored pressure differential (ΔP). 18 . The method of claim 17 , wherein the low-pass filter comprises at least one of a buffer volume disposed downstream of the inner volume, or an electrical circuit disposed within a control system in communication with the pressure sensing system. 19 . The method of claim 13 , wherein calculating the remaining bed weight within the fluidized bed as the bed weight reduces is performed by a control system in communication with the pressure sensing system. 20 . The method of claim 13 , wherein activating the alert system initiates one or more further processes, said processes comprising, at least one of, initiating a refill of the inner volume of the vessel with additional solid precursor particles, or discontinuing gaseous precursor generation.