摘要:
Methods are provided herein for forming electrode layers over high dielectric constant (“high k”) materials. In the illustrated embodiments, a high k gate dielectric, such as zirconium oxide, is protected from reduction during a subsequent deposition of silicon-containing gate electrode. In particular, a seed deposition phase includes conditions designed for minimizing hydrogen reduction of the gate dielectric, including low hydrogen content, low temperatures and/or low partial pressures of the silicon source gas. Conditions are preferably changed for higher deposition rates and deposition continues in a bulk phase. Desirably, though, hydrogen diffusion is still minimized by controlling the above-noted parameters. In one embodiment, high k dielectric reduction is minimized through omission of a hydrogen carrier gas. In another embodiment, higher order silanes, aid in reducing hydrogen content for a given deposition rate.
摘要:
The present invention relates to methods for forming dielectric layers on a substrate, such as in an integrated circuit. In one aspect of the invention, a thin interfacial layer is formed. The interfacial layer is preferably an oxide layer and a high-k material is preferably deposited on the interfacial layer by a process that does not cause substantial further growth of the interfacial layer. For example, water vapor may be used as an oxidant source during high-k deposition at less than or equal to about 300° C.
摘要:
Methods are provided herein for treating substrate surfaces in preparation for subsequent nucleation-sensitive depositions (e.g., polysilicon or poly-SiGe) and adsorption-driven deposition (e.g. atomic layer deposition or ALD). Prior to depositing, the surface is treated with non-depositing plasma products. The treated surface more readily nucleates polysilicon and poly-SiGe (such as for a gate electrode), or more readily adsorbs ALD reactants (such as for a gate dielectric). The surface treatment provides surface moieties more readily susceptible to a subsequent deposition reaction, or more readily susceptible to further surface treatment prior to deposition. By changing the surface termination of the substrate with a low temperature radical treatment, subsequent deposition is advantageously facilitated without depositing a layer of any appreciable thickness and without significantly affecting the bulk properties of the underlying material. Preferably less than 10 Å of the bulk material incorporates the excited species, which can include fluorine, chlorine and particularly nitrogen excited species.
摘要:
A high k dielectric film and methods for forming the same are disclosed. The high k material includes two peaks of impurity concentration, particularly nitrogen, such as at a lower interface and upper interface, making the layer particularly suitable for transistor gate dielectric applications. The methods of formation include low temperature processes, particularly CVD using a remote plasma generator and atomic layer deposition using selective incorporation of nitrogen in the cyclic process. Advantageously, nitrogen levels are tailored during the deposition process and temperatures are low enough to avoid interdiffusion and allow maintenance of the desired impurity profile.
摘要:
A vapor deposition method and apparatus including at least two vessels containing a same first source chemical. A controller is programmed to simultaneously pulse to the reaction space doses or pulses of a gas from the vessels, each of the doses having a substantially consistent concentration of the first source chemical. The apparatus may also include at least two vessels containing a same second source chemical. The controller can be programmed to simultaneously pulse to the reaction space doses or pulses of a gas from the vessels containing the second source chemical, each of the doses having a substantially consistent concentration of the second source chemical. The second source chemical can be pulsed to the reaction space after the reaction space is purged of an excess of the first source chemical.
摘要:
A vapor deposition method and apparatus including at least two vessels containing a same first source chemical. A controller is programmed to simultaneously pulse to the reaction space doses or pulses of a gas from the vessels, each of the doses having a substantially consistent concentration of the first source chemical. The apparatus may also include at least two vessels containing a same second source chemical. The controller can be programmed to simultaneously pulse to the reaction space doses or pulses of a gas from the vessels containing the second source chemical, each of the doses having a substantially consistent concentration of the second source chemical. The second source chemical can be pulsed to the reaction space after the reaction space is purged of an excess of the first source chemical.
摘要:
Multiple sequential processes are conducted in a reaction chamber to form ultra high quality silicon-containing compound layers, including silicon nitride layers. In a preferred embodiment, a silicon layer is deposited on a substrate using trisilane as the silicon precursor. A silicon nitride layer is then formed by nitriding the silicon layer. By repeating these steps, a silicon nitride layer of a desired thickness is formed.
摘要:
Multiple sequential processes are conducted in a reaction chamber to form ultra high quality silicon-containing compound layers, including silicon nitride layers. In a preferred embodiment, a silicon layer is deposited on a substrate using trisilane as the silicon precursor. A silicon nitride layer is then formed by nitriding the silicon layer. By repeating these steps, a silicon nitride layer of a desired thickness is formed.
摘要:
Sequential processes are conducted in a batch reaction chamber to form ultra high quality silicon-containing compound layers, e.g., silicon nitride layers, at low temperatures. Under reaction rate limited conditions, a silicon layer is deposited on a substrate using trisilane as the silicon precursor. Trisilane flow is interrupted. A silicon nitride layer is then formed by nitriding the silicon layer with nitrogen radicals, such as by pulsing the plasma power (remote or in situ) on after a trisilane step. The nitrogen radical supply is stopped. Optionally non-activated ammonia is also supplied, continuously or intermittently. If desired, the process is repeated for greater thickness, purging the reactor after each trisilane and silicon compounding step to avoid gas phase reactions, with each cycle producing about 5-7 angstroms of silicon nitride.
摘要:
A high k dielectric film and methods for forming the same are disclosed. The high k material includes two peaks of impurity concentration, particularly nitrogen, such as at a lower interface and upper interface, making the layer particularly suitable for transistor gate dielectric applications. The methods of formation include low temperature processes, particularly CVD using a remote plasma generator and atomic layer deposition using selective incorporation of nitrogen in the cyclic process. Advantageously, nitrogen levels are tailored during the deposition process and temperatures are low enough to avoid interdiffusion and allow maintenance of the desired impurity profile.