CLA-2-28:OT:RR:NC:N3:136
Sunghee Yeon
EcoPro BM
100 2 Sandan-ro (Songdae-ri 329) Ochang-eup, Cheongwon-gu
Cheongju-si, Chungcheongbuk-do, 28117
South Korea
RE: The country of origin of Cathode Active Material and its Precursor
Dear Ms. Yeon:
In your letter dated December 14, 2021, you requested a country of origin determination for five different scenarios. Each scenario involves different levels of production in different countries, related to the four manufacturing steps described herein.
Your country of origin questions are as follows:
Scenario 1: What is the country of origin of imported Raw Materials upon entry into the U.S.?
Scenario 2: What is the country of origin of Semi-Finished Good A when manufactured in South
Korea and imported into the U.S.?
Scenario 3: What is the country of origin of Semi-Finished Good A when manufactured in China
and imported into the U.S.?
Scenario 4: What is the country of origin of the Finished Good when manufactured in South Korea and imported into the U.S.?
Scenario 5: What is the country of origin of Semi-Finished Good C when manufactured in South
Korea and imported into the U.S.?
Description of Goods: Raw Materials
Major raw materials used in the production of Semi-Finished Goods A through C and the Finished Good include nickel sulfate (country of origin Australia), cobalt sulfate (country of origin China), manganese sulfate (country of origin China), sodium hydroxide (country of origin South Korea), lithium hydroxide (country of origin China or Chile), proprietary substance 1 (country of origin Japan), proprietary substance 2 (country of origin Germany), and proprietary substance 3 (country of origin China).
Description of Goods: Semi-Finished Good A, B and C
Semi-Finished Good A (precursor) is nickel cobalt manganese hydroxide in a black powder state, which is manufactured by reacting four different raw materials (nickel sulfate, cobalt sulfate, manganese sulfate, sodium hydroxide) under a special manufacturing process. The result is a metal hydroxide composed of three metallic elements, which is also called a “precursor” in the commercial market.
Semi-Finished Good B (cathode active material) is lithium nickel cobalt manganese oxide in a black powder state, which is made by chemically reacting “Semi-Finished Good A” and lithium hydroxide under a special manufacturing process. The result is a mixed metal oxide composed of three metallic elements, which is also called a “cathode active material” in the commercial market.
Semi-Finished Good C (doped-cathode active material) is doped-lithium nickel cobalt manganese oxide in a black powder state, which is made by doping Semi-Finished Good B with proprietary doping elements under a special doping process where proprietary substances 1, 2, and 3 are added. Semi-Finished Good C, is differentiated from Semi-Finished Good B as it is doped and therefore has superior product performance over Semi-Finished Good B. Specifically, the proprietary substance 1 doping element is used to increase discharge capacity, improve lifespan of the cathode active material, and improve capacity and retention rate under high voltage conditions. The proprietary substance 2 doping element is used to prevent the spread of lithium. Finally, the proprietary substance 3 doping element is used to increase charge and discharge capacity, and to control cation mixing. Semi-Finished Good C is also called “dopedcathode active material” in the commercial market.
Description of Goods: Finished Good
The Finished Good (coated and doped-cathode active material), is the core material used in electric vehicle batteries that determines the voltage, energy density, lifespan, and output. More specifically, the unique combination of nickel (Ni), manganese (Mn), cobalt (Co) and proprietary substance 2 determine the performance of each cell contained within the EV battery.
The Finished Good is coated and doped-lithium nickel cobalt manganese oxide in a black powder state, which is made by coating Semi-Finished Good C with propriety coating elements under a special coating process where proprietary substance 1, proprietary substance 2, and proprietary substance 3 are added. The coating process provides a heightened structural stability that uncoated products do not have.
Manufacturing Process
Process 1: Four different raw materials (nickel sulfate, cobalt sulfate, manganese sulfate, sodium hydroxide) are dissolved, and these solutions are mixed together. This combined solution is used to synthesize the precursor through a special manufacturing process involving a chemical reaction. After the precursor synthesis process, washing and dehydration processes are performed. Then, the product is dried and a quality check is performed to eliminate defects. The resulting precursor in powder form, Semi-Finished Good A, is then de-ironed, evenly blended, and packaged. Final inspection is done after final packaging.
Process 2: The precursor powder, Semi-Finished Good A, is mixed with lithium hydroxide and subjected to a firing process at high temperature. During the firing, the powder undergoes a chemical reaction which changes the input into cathode active material. It then goes through roll smashing and crushing processes, and then is filtered to remove defective product. The cathode active material, Semi-Finished Good B, is packaged and sold to the market or is put into the 3rd process.
Process 3: The cathode active material, Semi-Finished Good B, is then combined with doping compounds and undergoes a chemical reaction during another firing at a high temperature. The new material that has undergone the doping and firing process, Semi-Finished Good C, is packaged and sold to the market as a doped cathode active material or is put into the 4th process.
Process 4: This step is almost identical to Process 3, however, where Process 3 uses proprietary substance 1, proprietary substance 2, and proprietary substance 3 as doping compounds to produce Doped-Lithium Nickel Cobalt Manganese Oxide, Process 4 uses those same three input chemicals as coating compounds to chemically coat the doped output from Process 3 into the Finished Good, Doped & Coated-Lithium Nickel Cobalt Manganese Oxide.
Country of Origin and Classification
"Country of origin" is defined in 19 CFR 134.1(b) as "the country of manufacture, production, or growth of any article of foreign origin entering the United States. Further work or material added to an article in another country must effect a substantial transformation in order to render such other country the 'country of origin' within the meaning of this part.”
A substantial transformation occurs when an article emerges from a process with a new name, character or use different from that possessed by the article prior to processing. United States v. Gibson-Thomsen Co., Inc., 27 CCPA 267, C.A.D. 98 (1940); National Hand Tool Corp. v. United States, 16 CIT 308 (1992), aff’d, 989 F. 2d 1201 (Fed. Cir. 1993). However, if the manufacturing or combining process is merely a minor one that leaves the identity of the article intact, a substantial transformation has not occurred. Uniroyal, Inc. v. United States, 3 CIT 220, 542 F. Supp. 1026, 1029 (1982), aff’d, 702 F.2d 1022 (Fed. Cir. 1983).
In this case, we find the above described senarios and manufacturing processes result in the following:
Scenario 1: The country of origin of the Raw Materials when imported into the U.S. is the country of origin from which they are sourced.
Scenario 2: The subcomponents of the Semi-Finished Good A undergo a chemical reaction in
South Korea resulting in a distinct chemical structure, chemical formula, and CAS number, thereby resulting in a change in name, character, and use. Therefore, the country of origin of the Semi-Finished Good A when imported into the U.S. is South Korea.
Scenario 3: The subcomponents of the Semi-Finished Good A undergo a chemical reaction in
China resulting in a distinct chemical structure, chemical formula, and CAS number, thereby
resulting in a change in name, character, and use. Therefore, the country of origin of the Semi-Finished Good A when imported into the U.S. is China.
Scenario 4: The subcomponents of the Finished Good undergo a chemical reaction in South Korea resulting in a distinct chemical structure, chemical formula, and CAS number thereby resulting in a change in name, character, and use. Therefore, the country of origin of the Finished Good when imported into the U.S. is South Korea.
Scenario 5: The subcomponents of the Semi-Finished Good C undergo a chemical reaction in
South Korea resulting in a distinct chemical structure, chemical formula, and CAS number, thereby resulting in a change in name, character, and use. Therefore, the country of origin of Semi-Finished Good C when imported into the U.S is South Korea.
The applicable subheading for Semi-Finished Good A will be 2825.90.9000, Harmonized Tariff Schedule of the United States (HTSUS), which provides for Hydrazine and hydroxylamine and their inorganic salts; other inorganic bases; other metal oxides, hydroxides and peroxides: Other: Other. The general rate of duty will be 3.7 percent ad valorem.
The applicable subheading for the Finished Good and Semi-Finished Good C will be 3824.99.3900, HTSUS, which provides for Prepared binders for foundry molds or cores; chemical products and preparations of the chemical or allied industries (including those consisting of mixtures of natural products), not elsewhere specified or included: Other: Other: Other: Mixtures of two or more inorganic compounds: Other. The general rate of duty will be free.
Pursuant to U.S. Note 20 to Subchapter III, Chapter 99, HTSUS, products of China classified under subheading 2825.90.9000, HTSUS, unless specifically excluded, are subject to the additional 25 percent ad valorem rate of duty. At the time of importation, you must report the Chapter 99 subheading, i.e., 9903.88.03, in addition to subheading 2825.90.9000, HTSUS, listed above.�
The HTSUS is subject to periodic amendment so you should exercise reasonable care in monitoring the status of goods covered by the Notice cited above and the applicable Chapter 99 subheading. For background information regarding the trade remedy initiated pursuant to Section 301 of the Trade Act of 1974, you may refer to the relevant parts of the USTR and CBP websites, which are available at https://ustr.gov/issue-areas/enforcement/section-301-investigations/tariff-actions and https://www.cbp.gov/trade/remedies/301-certain-products-china, respectively.
This merchandise may be subject to the requirements of the Toxic Substances Control Act (TSCA), which are administered by the U.S. Environmental Protection Agency. Information on the TSCA can be obtained by contacting the EPA at 1200 Pennsylvania Avenue, N.W., Mail Code 70480, Washington, D.C., by telephone at (202) 554-1404, or by visiting their website at www.epa.gov.
Duty rates are provided for your convenience and are subject to change. The text of the most recent HTSUS and the accompanying duty rates are provided on World Wide Web at https://hts.usitc.gov/current.
This ruling is being issued under the provisions of Part 177 of the Customs Regulations (19 C.F.R. 177).
A copy of the ruling or the control number indicated above should be provided with the entry documents filed at the time this merchandise is imported.
If you have any questions regarding scenarios 1, 2, or 3, contact National Import Specialist Nuccio Fera at [email protected]. If you have any questions regarding scenarios 4 or 5, contact National Import Specialist John Bobel at [email protected].
Sincerely,
Steven A. Mack
Director
National Commodity Specialist Division