Device for detecting chemical/physical phenomenon

The invention claimed is: 1. A method for controlling chemical or physical phenomenon detecting device, wherein the device comprises a semiconductor substrate in which a sensing region and a charge accumulation region are partitioned, a potential of the sensing region changes in accordance with a change in an external environment, and an amount of charges reflecting the potential of the sensing region is accumulated in the charge accumulation region and the accumulated charges are detected wherein the charge accumulation region comprises a first potential well region continuous with the sensing region, a second potential well region, and an analog gate region positioned between the first potential well region and the second potential well region, wherein the semiconductor substrate further comprises a charge input region for supplying charges to the sensing region, and an input charge control region formed between the charge input region and the sensing region to adjust the supply of charges from the charge input region to the sensing region, and the sensing region has photosensitivity, the method comprising: a sensing step for making the boundary potential of charges in the first potential well region equal to the potential of the sensing region; and a step for making setting absolute potential values of the analog gate region and the input charge control region such that the input charge control region <the analog gate region ≤the sensing region, a step for transferring charges generated in response to incident light in the sensing region to the second potential well region via the analog gate region, and a detecting step for detecting an amount of the charges held in the first potential well region in the sensing step. 2. A chemical or physical phenomenon detecting device comprising a semiconductor substrate containing a sensing region and a charge accumulation region, wherein: the charge accumulation region comprises a first potential well region which is adjacent to, and spatially contiguous with, the sensing region; an electrical potential of the sensing region changes in response to a change in an external environment in communication with the sensing region; the sensing region and accumulation region are jointly configured and arranged such that, when a boundary electrical potential of the first potential well is equal to the electrical potential of the sensing region, an amount of charge corresponding to the electrical potential of the sensing region collects in the accumulation region in the absence of any voltage externally applied to any of the first potential well and the sensing region; and an electrical signal corresponding to the amount of charge collected in the accumulation region is produced at an electrical output terminal of the device. 3. A chemical or physical phenomenon detection device according to claim 2 , wherein the charge accumulation region further includes: a second potential well region, and an analog gate region positioned between the first potential well region and the second potential well region; wherein the first and second potential well regions are jointly configured and arranged such that the amount of charge collected in the accumulation region is transferred from the first potential well region to the second potential well region by adjusting the electric potential of the analog gate region; and wherein the electrical signal corresponding to the amount of charge collected in the accumulation region is produced according to an amount of charge collected in the second potential well. 4. A chemical or physical phenomenon detection device according to claim 2 wherein the semiconductor substrate further contains: a charge input region for supplying charges to the sensing region; an input charge control region formed between the charge input region and the sensing region to adjust the supply of charges from the charge input region to the sensing region; and a third potential well region positioned between the input charge control region and sensing region and formed adjacent to, and contiguous with, the sensing region. 5. A method of measuring a chemical or physical phenomenon using a chemical or physical phenomenon detecting device wherein: the device comprises a semiconductor substrate containing a sensing region, a charge accumulation region, and an electrical output terminal; the charge accumulation region comprises a first potential well region which is adjacent to, and spatially contiguous with, the sensing region; an electrical potential of the sensing region changes in response to a change in an external environment in communication with the sensing region; and the sensing region and accumulation region are jointly configured and arranged such that, when a boundary electrical potential of the first potential well is equal to the electrical potential of the sensing region, an amount of charge corresponding to the electrical potential of the sensing region collects in the accumulation region in the absence of any voltage externally applied to any of the first potential well and the sensing region; the method comprising: (i) during a sensing step, configuring the electrical boundary potential of the first potential well to equal the electrical potential of the sensing region; and (ii) during a detection step following the sensing step, producing an electrical signal corresponding to the amount of charge collected in the accumulation region at the electrical output terminal of the device. 6. A method of measuring a chemical or physical phenomenon using a chemical or physical phenomenon detecting device according to claim 5 wherein the sensing region is sensitive to light; wherein the sensing step further includes configuring respective absolute potential values of the analog gate region and the input charge control region such that an electric potential of the input charge control region <an electric potential of the analog gate region ≤the electrical potential of the sensing region, and wherein the method further includes, after the sensing step and before the detection step, transferring charges generated in response to incident light in the sensing region to the second potential well region via the analog gate region.