Disclosed are apparatus, systems, and methods for electroplating cobalt, nickel, and alloys thereof in interconnect features of partially or fully fabricated electronic devices. During electroplating, cobalt, nickel, or alloys thereof fill features by a bottom up electrofill mechanism. Examples of features that may be electrofilled with cobalt, nickel, or alloys thereof include micro TSVs, contacts for devices, and certain gates for transistors. Electroplating apparatus may include electroplating cells along with one or more instances of each of a post-electrofill module, an anneal chamber, a plasma pretreatment module, and a substrate pre-wetting module.

Sequential electrodeposition of metals into through-mask features on a semiconductor substrate is conducted such as to reduce the deleterious consequences of lipseal's pressure onto the mask material. In a first electroplating step, a first metal (e.g., nickel) is electrodeposited using a lipseal that has an innermost point of contact with the semiconductor substrate at a first distance from the edge of the substrate. In a second electroplating step, a second metal (e.g., tin) is electrodeposited using a lipseal that has an innermost point of contact with the semiconductor substrate at a greater distance from the edge of the substrate than the first distance. This allows to at least partially shift the lipseal pressure from a point that could have been damaged during the first electrodeposition step and to shield from electrolyte any cracks that might have formed in the mask material during the first electroplating step.

Sequential electrodeposition of metals into through-mask features on a semiconductor substrate is conducted such as to reduce the deleterious consequences of lipseal's pressure onto the mask material. In a first electroplating step, a first metal (e.g., nickel) is electrodeposited using a lipseal that has an innermost point of contact with the semiconductor substrate at a first distance from the edge of the substrate. In a second electroplating step, a second metal (e.g., tin) is electrodeposited using a lipseal that has an innermost point of contact with the semiconductor substrate at a greater distance from the edge of the substrate than the first distance. This allows to at least partially shift the lipseal pressure from a point that could have been damaged during the first electrodeposition step and to shield from electrolyte any cracks that might have formed in the mask material during the first electroplating step.

An electroplating system has a vessel assembly holding an electrolyte. A weir thief electrode assembly in the vessel assembly includes a plenum inside of a weir frame. The plenum divided into at least a first, a second and a third virtual thief electrode segment. A plurality of spaced apart openings through the weir frame lead out of the plenum. A weir ring is attached to the weir frame and guides flow of current during electroplating. The electroplating system provides process determined radial and circumferential current density control and does not require changing hardware components during set up.

An electroplating system has a vessel assembly holding an electrolyte. A weir thief electrode assembly in the vessel assembly includes a plenum inside of a weir frame. The plenum divided into at least a first, a second and a third virtual thief electrode segment. A plurality of spaced apart openings through the weir frame lead out of the plenum. A weir ring is attached to the weir frame and guides flow of current during electroplating. The electroplating system provides process determined radial and circumferential current density control and does not require changing hardware components during set up.

Provided is a wetting method for substrate that allows reducing an amount of air bubbles attached to a surface to be plated with a simple structure.

The wetting method for substrate includes a holding step 102 of holding a back surface of a substrate with a back plate such that a surface to be plated of the substrate is opposed to a liquid surface of a plating solution housed in a plating tank, a supplying step 104 of supplying the plating solution to the plating tank such that the plating solution upwardly flows through a plurality of through-holes in a center part of an ionically resistive element arranged inside the plating tank to raise a center part of the liquid surface of the plating solution, a first lowering step 106 of lowering a supporting member for supporting an outer edge portion of the surface to be plated of the substrate held by the holding member toward the liquid surface of the plating solution, and a second lowering step 108 of lowering the holding member such that the substrate is sandwiched by the supporting member lowered in the first lowering step 106 and the holding member while the center part of the liquid surface of the plating solution is raised in the supplying step 104.

Electrochemical deposition systems and methods are described that have enhanced crystallization prevention features. The systems may include a bath vessel operable to hold an electrochemical deposition fluid having a metal salt dissolved in water. The systems may also include sensors including a thermometer and concentration sensor operable to measure characteristics of the electrochemical deposition fluid. The systems further include a computer configured to perform operations that include receiving system data from the electrochemical system and generating a control signal to change a characteristic of the electrochemical deposition fluid to prevent crystallization of a metal salt in the fluid. The computer generates the control signal based on processing that may include comparing an actual metal salt concentration in the electrochemical deposition fluid to a theoretical solubility limit for the metal salt in the fluid.

An apparatus includes a template-former, a growth template, having a surface area containing three-dimensional features; a container which includes or retains electrolytes or other fluids from which materials are deposited, removed, or modified onto the growth template or to a structure-in-production; and a computer to plan and control said deposition, removal, or modification.

An apparatus includes a template-former, a growth template, having a surface area containing three-dimensional features; a container which includes or retains electrolytes or other fluids from which materials are deposited, removed, or modified onto the growth template or to a structure-in-production; and a computer to plan and control said deposition, removal, or modification.

An electrochemical plating apparatus for depositing a conductive material on a wafer includes a cell chamber. The plating solution is provided from a bottom of the cell chamber into the cell chamber. A plurality of openings passes through a sidewall of the cell chamber. A flow regulator is arranged with each of the plurality of openings configured to regulate an overflow amount of the plating solution flowing out through the each of the plurality of openings. The electrochemical plating apparatus further comprises a controller to control the flow regulator such that overflow amounts of the plating solution flowing out through the plurality of openings are substantially equal to each other.