A structure includes a semiconductor substrate, and a polycrystalline resistor region over the semiconductor substrate. The polycrystalline resistor region includes a semiconductor material in a polycrystalline morphology. A dopant-including polycrystalline region is between the polycrystalline resistor region and the semiconductor substrate.

The present disclosure generally relates to a semiconductor device having a capacitor and a resistor and a method of forming the same. More particularly, the present disclosure relates to a metal-insulator-metal (MIM) capacitor and a thin film resistor (TFR) formed in a back end of line portion of an integrated circuit (IC) chip.

In some implementations, one or more semiconductor processing tools may form a via for a semiconductor device. The one or more semiconductor processing tools may deposit a metal plug within the via. The one or more semiconductor processing tools may deposit an oxide-based layer on the metal plug within the via. The one or more semiconductor processing tools may deposit a resistor on the oxide-based layer within the via. The one or more semiconductor processing tools may deposit a first landing pad and a second landing pad on the resistor within the via. The one or more semiconductor processing tools may deposit a first metal plug on the first landing pad and a second metal plug on the second landing pad.

Various embodiments of the present disclosure are directed towards an integrated chip (IC). The IC comprises a substrate. A resistor overlies the substrate. The resistor comprises a resistive structure overlying the substrate. The resistor also comprises a conductive contact overlying and electrically coupled to the resistive structure. A capping structure is disposed over the conductive contact, wherein the capping structure extends laterally over an upper surface of the conductive contact and vertically along a first sidewall of the conductive contact, such that a lower surface of the capping structure is disposed below a lower surface of the conductive contact.

Various embodiments of the present disclosure are directed towards an integrated chip (IC). The IC comprises a substrate. A resistor overlies the substrate. The resistor comprises a first metal nitride structure, a second metal nitride structure spaced from the first metal nitride structure, and a metal structure disposed between the first metal nitride structure and the second metal nitride structure. A first dielectric structure is disposed over the substrate and the resistor.

The present disclosure describes a method for forming a barrier structure between liner-free conductive structures and underlying conductive structures. The method includes forming openings in a dielectric layer disposed on a contact layer, where the openings expose conductive structures in the contact layer. A first metal layer is deposited in the openings and is grown thicker on top surfaces of the conductive structures and thinner on sidewall surfaces of the openings. The method further includes exposing the first metal layer to ammonia to form a bilayer with the first metal layer and a nitride of the first metal layer, and subsequently exposing the nitride to an oxygen plasma to convert a portion of the nitride of the first metal layer to an oxide layer. The method also includes removing the oxide layer and forming a semiconductor-containing layer on the nitride of the first metal layer.

Semiconductor structures and methods of forming the same are provided. A method according to an embodiment includes forming a conductive feature and a first conductive plate over a substrate, conformally depositing a dielectric layer over the conductive feature and the first conductive plate, conformally depositing a conductive layer over the conductive feature and the first conductive plate, and patterning the conductive layer to form a second conductive plate over the first conductive plate and a resistor, the resistor includes a conductive line extending along a sidewall of the conductive feature. By employing the method, a high-resistance resistor may be formed along with a capacitor regardless of the resolution limit of, for example, lithography.

An electric fuse element has a first portion, a second portion arranged on one end of the first portion, and a third portion arranged on the other end of the first portion. A resistor element is arranged separately from the electric fuse element. A material of each of the electric fuse element and the resistor element has silicon metal or nickel chromium. The electric fuse element and the resistor element are arranged in an upper layer of the first wiring and in lower layer of the second wiring. A wiring width of the second portion and a wiring width of the third portion are larger than a wiring width of the first portion.

A resistor material including a plurality of crystalline phases having a positive temperature coefficient of resistance, and an amorphous phase having a negative temperature coefficient of resistance and having a resistivity higher than the crystalline phase, in a mixed state, is provided. Moreover, a resistor element having a resistor film configured by the resistor material described above, and a method of manufacturing a resistor element by forming a film of an amorphous material having a negative temperature coefficient of resistance and subjecting this film to an annealing treatment to obtain the resistor element described above, are provided.

A thin film resistor (TFR) module is formed in an integrated circuit device. The TFR module includes a TFR element connected between first and second vertically-extending TFR side contacts. The TFR element includes a base portion extending laterally between the TFR side contacts, and first and second TFR element end flanges projecting vertically from opposing ends of the base portion. The first TFR element end flange is formed on a sidewall of the first TFR side contact, and the second TFR element end flange is formed on a sidewall of the second TFR side contact. A first TFR head contacts the first TFR side contact and a top of the first TFR element end flange, and a second TFR head contacts the second TFR side contact and a top of the second TFR element end flange, thus defining two parallel conductive paths between the TFR element and each TFR head.