Advanced quality control tools for manufacturing bimodal and multimodal polyethylene resins

What is claimed is: 1. A method of producing polyethylene comprising: (a) polymerizing ethylene in one or more reaction zones to produce a first polyethylene resin, wherein the first polyethylene resin is a first multimodal resin, wherein each reaction zone of the one or more reaction zones operates independently at a first value for a plurality of parameters, wherein each parameter of the plurality of parameters is selected from the group consisting of ethylene concentration, comonomer concentration, hydrogen to ethylene ratio, temperature, catalyst concentration, cocatalyst concentration, pressure, and residence time, wherein the first polyethylene resin is characterized by a first melt index that is within 30% of a target melt index, and wherein the first polyethylene resin is characterized by a first density that is within 2.5% of a target density; (b) determining a dynamic viscosity (η s *) of the first polyethylene resin; (c) comparing the dynamic viscosity of the first polyethylene resin with a target dynamic viscosity (η c *), wherein comparing the dynamic viscosity comprises calculating a first dynamic viscosity deviation (a first % MVD) from the target dynamic viscosity, and wherein the first polyethylene resin is characterized by the first % MVD of equal to or greater than about 100%; (d) selecting a second value for one or more parameters of the plurality of parameters for at least one of the one or more reaction zones based on the first % MVD being equal to or greater than about 100%; (e) operating the at least one of the one or more reaction zones independently at the second value of the one or more parameters of the plurality of parameters to produce a second polyethylene resin that is a second multimodal resin, wherein the second polyethylene resin is characterized by a second % MVD of less than about 100%, a second melt index that is within 30% of the target melt index, and a second density that is within 2.5% of the target density; and (f) recovering the second polyethylene resin from the one or more reaction zones. 2. The method of claim 1 , wherein the dynamic viscosity is determined across a range of shear rate (ω i ) of from about 0.01 s −1 to about 1,000 s −1 . 3. The method of claim 1 , wherein the second polyethylene resin is a bimodal resin. 4. The method of claim 1 , wherein the first % MVD or the second % MVD is calculated using the following equation: % ⁢ ⁢ MVD = 100 × ∑ i ⁢ [ ( η s * ) ω i - ( η c * ) ω i ( η c * ) ω i ] 2 i , wherein (η s *) ω i is the dynamic viscosity of the corresponding polyethylene resin at a shear rate ω i , wherein (η c *) ω i is the target dynamic viscosity at the shear rate ω i , wherein i represents the number of data points collected for the dynamic viscosity (η s *) across the range of shear rate (ω i ), and wherein i is equal to or greater than 3. 5. The method of claim 1 further comprising (i) determining a gel permeation chromatography (GPC) curve profile of the second polyethylene resin; wherein the GPC curve profile comprises a differential weight fraction (dw/d(log M)) as a function of log M, wherein M is the molecular weight of the weight fraction w; and (ii) comparing the GPC curve profile of the second polyethylene resin with a target GPC curve profile, wherein comparing the GPC curve profile comprises calculating a GPC curve profile deviation (% GPCD) from the target GPC curve profile. 6. The method of claim 5 , wherein, when the second polyethylene resin is characterized by a % GPCD of equal to or greater than about 15%, the second polyethylene resin is designated as a low quality resin; and wherein, when the second polyethylene resin is characterized by a % GPCD of less than about 15%, the second polyethylene resin is designated as a high quality resin. 7. The method of claim 5 , wherein % GPCD is calculated using the following equation: % ⁢ ⁢ GPCD = 100 × ∑ j ⁢ Abs ⁡ ( ( dw d ⁡ ( Log ⁢