Integrated photodetector with charge storage bin of varied detection time

1 - 35 . (canceled) 36 . A sequencing instrument, comprising: a sample well configured to support a sample; an excitation light source configured to illuminate the sample well to excite fluorescent emission from the sample; an integrated photodetector configured to detect fluorescent emission from the sample, the integrated photodetector comprising: a photodetection region configured to convert received photons to charge carriers; a charge carrier storage region; and an electrode located, at least in part, at a boundary of the photodetection region and the charge carrier storage region and configured to control transfer of charge carriers from the photodetection region to the charge carrier storage region, wherein the integrated photodetector is controllable to: aggregate charge carriers in the charge carrier storage region following each of a first plurality of illuminations of the sample well by the excitation light source and read out a first signal indicative of a quantity of charge carriers aggregated in the charge carrier storage region following the first plurality of illuminations collectively; and aggregate charge carriers in the charge carrier storage region following each of a second plurality of illuminations of the sample well by the excitation light source and read out a second signal indicative of a quantity of charge carriers aggregated in the charge carrier storage region following the second plurality of illuminations collectively, and wherein the electrode is controllable to direct charge carriers from the photodetection region to the charge carrier storage region at first times with respect to the first plurality of illuminations and at second times with respect to the second plurality of illuminations such that a ratio of the first signal and the second signal indicates fluorescence lifetime information of the sample. 37 . The sequencing instrument of claim 36 , further comprising: a control circuit configured to: control the electrode to aggregate charge carriers in the charge carrier storage region following each of the first plurality of illuminations of the sample well; control read out of the first signal; control the electrode to aggregate charge carriers in the charge carrier storage region following each of the second plurality of illuminations of the sample well; and control read out of the second signal, wherein the control circuit is configured to: control the electrode to initiate aggregation of charge carriers following each of the first plurality of illuminations of the sample well; and control the electrode to initiate aggregation of charge carriers following each of the second plurality of illuminations of the sample well. 38 . The sequencing instrument of claim 36 , further comprising: a control circuit configured to sequence the sample at least in part by repeatedly performing a sequence comprising: controlling the electrode to aggregate charge carriers in the charge carrier storage region following each of the first plurality of illuminations of the sample well; controlling read out of the first signal; controlling the electrode to aggregate charge carriers in the charge carrier storage region following each of the second plurality of illuminations of the sample well; and controlling read out of the second signal. 39 . The sequencing instrument of claim 36 , further comprising: a control circuit configured to: control the electrode to aggregate charge carriers in the charge carrier storage region following each of the first plurality of illuminations of the sample well; control read out of the first signal; control the electrode to aggregate charge carriers in the charge carrier storage region following each of the second plurality of illuminations of the sample well; and control read out of the second signal, wherein the integrated photodetector further comprises a rejection region, and the control circuit is further configured to: for each of the first plurality of illuminations, prior to controlling the electrode to aggregate charge carriers in the charge carrier storage region, control a first transfer of charge carriers from the photodetection region to the rejection region; and for each of the second plurality of illuminations, prior to controlling the electrode to aggregate charge carriers in the charge carrier storage region, control a second transfer of charge carriers from the photodetection region to the rejection region. 40 . The sequencing instrument of claim 36 , wherein: the charge carrier storage region is a first charge carrier storage region; the integrated photodetector further comprises a second charge carrier storage region configured to receive charge carriers from the first charge carrier storage region; and the integrated photodetector is controllable to read out the first signal and the second signal using the second charge carrier storage region. 41 . The sequencing instrument of claim 40 , wherein the first charge carrier storage region and the second charge carrier storage region are located on a same side of the photodetection region. 42 . A system, comprising: a pixel comprising: a photodetection region configured to receive, following each of a plurality of trigger events, photons, and generate, in response to receiving the photons, charge carriers; a charge carrier storage region; and an electrode located, at least in part, at a boundary of the photodetection region and the charge carrier storage region and configured to direct, from the photodetection region to the charge carrier storage region, the charge carriers; and a control circuit configured to: after a first amount of time following each of a first plurality of trigger events, control the electrode to initiate a transfer of first charge carriers to the charge carrier storage region, the first charge carriers generated in the photodetection region following each of the first plurality of trigger events, respectively; read out, from the pixel, a first signal indicative of a quantity of the first charge carriers aggregated in the charge carrier storage region following the first plurality of trigger events collectively; after a second amount of time following each of a second plurality of trigger events, control the electrode to initiate a transfer of second charge carriers to the charge carrier storage region, the second charge carriers generated in the photodetection region following each of the second plurality of trigger events, respectively; and read out, from the pixel, a second signal indicative of a quantity of the second charge carriers aggregated in the charge carrier storage region following the second plurality of trigger events collectively. 43 . The system of claim 42 , wherein the control circuit is configured to control the first amount of time and the second amount of time such that a ratio of the first signal and the second signal indicates fluorescence lifetime information of a sample that emitted at least some of the photons. 44 . The system of claim 42 , further comprising: a sample well configured to support a sample, wherein the photodetection region is configured to receive at least some of the photons emitted by the sample in response to excitation of the sample. 45 . The system of claim 44 , wherein the control circuit is configured to sequence the sample at least in part by repeatedly performing a sequence comprising: controlling the electrode to initiate the transfer of the first charge carriers; reading out the first signal; controlling the electrode to initiate the transfer of second charge carriers; and reading out the second signal.