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詳細
Graphene oxide sheet size: 300-800 nm lateral size
Number of layer for graphene oxide: single layer
品質水準
形状
liquid
特徴
avg. no. of layers 1
環境により配慮した代替製品の特徴
Design for Energy Efficiency
Learn more about the Principles of Green Chemistry.
sustainability
Greener Alternative Product
濃度
40 mg/mL (Graphene oxide aquous ink)
粘度
100-210 Pa.s (25 °C at shear rate of 10 s-1)
環境により配慮した代替製品カテゴリ
, Enabling
保管温度
2-8°C
関連するカテゴリー
詳細
We are committed to bringing you Greener Alternative Products, which adhere to one or more of The 12 Principles of Green Chemistry. This product has been enhanced for energy efficiency. Click here for more information.
アプリケーション
This product can be used in material extrusion 3D printing technique.
This product is a thixotropic ink based on graphene oxide (GO) nanosheets. It is suitable for various direct ink write (aka robocasting) printing technologies. The ink offers a stable dispersion of GO, high viscosity, good printability, and long shelf life. Freeze-dried and annealed patterns provide low electrical resistivity and high surface area. The ink is suitable for applications such as batteries, supercapacitors, electrocatalysis, etc.
調製ノート
Before Printing:
Bring the ink to room temeprature, best to mix the ink in a planetary mixer before usage.
Printing:
Recommended 3D printing nozzle diameter size is 400 micron.
Post printing:
After 3D printing, this ink can be directly freeze-dried in liquid nitrogen and vacuum to obtain free- standing graphene oxide aerogel.
This ink can also be processed by adding gelling agents to enable a covalent bond established between the graphene oxide sheets. Gelation agents such as ammonium carbonate, ammonium hydroxide, resorcinol formaldehyde have all been reported to be sufficient. After gelation, the wet GO gels printed parts are washed in acetone to remove water from the pores. Supercritical CO2 can then be used to dry the GO gels.
Curing:
Parts that are printed with gelling agent can be cured in sealed glass vials at 85 °C.
The dried aerogels are generally reduced to graphene aerogels by thermal treatment at 1050 °C under inert atmosphere. Other chemical reduction methods include hydrazine reduction, dried aerogels can also be reduced using hydroiodic acid, followed by washing in ethanol, water and then freeze drying.
Bring the ink to room temeprature, best to mix the ink in a planetary mixer before usage.
Printing:
Recommended 3D printing nozzle diameter size is 400 micron.
Post printing:
After 3D printing, this ink can be directly freeze-dried in liquid nitrogen and vacuum to obtain free- standing graphene oxide aerogel.
This ink can also be processed by adding gelling agents to enable a covalent bond established between the graphene oxide sheets. Gelation agents such as ammonium carbonate, ammonium hydroxide, resorcinol formaldehyde have all been reported to be sufficient. After gelation, the wet GO gels printed parts are washed in acetone to remove water from the pores. Supercritical CO2 can then be used to dry the GO gels.
Curing:
Parts that are printed with gelling agent can be cured in sealed glass vials at 85 °C.
The dried aerogels are generally reduced to graphene aerogels by thermal treatment at 1050 °C under inert atmosphere. Other chemical reduction methods include hydrazine reduction, dried aerogels can also be reduced using hydroiodic acid, followed by washing in ethanol, water and then freeze drying.
保管および安定性
Tighly seal remaining ink, and store in 2-8 °C fridge.
保管分類コード
10 - Combustible liquids
WGK
WGK 3
適用法令
試験研究用途を考慮した関連法令を主に挙げております。化学物質以外については、一部の情報のみ提供しています。 製品を安全かつ合法的に使用することは、使用者の義務です。最新情報により修正される場合があります。WEBの反映には時間を要することがあるため、適宜SDSをご参照ください。
Jan Code
916579-VAR:
916579-10ML:
916579-BULK:
最新バージョンのいずれかを選択してください:
Toward Macroscale, Isotropic Carbons with Graphene-Sheet-Like Electrical and Mechanical Properties.
Worsley M A, et al.
Advances in Functional Materials, 24(27), 4259-4264 (2014)
Versatile mechanically strong and highly conductive chemically converted graphene aerogels..
Liu Y, et al.
Carbon, 125, 352-359 (2017)
Bin Yao et al.
Advanced materials (Deerfield Beach, Fla.), 32(8), e1906652-e1906652 (2020-01-18)
The performance of pseudocapacitive electrodes at fast charging rates are typically limited by the slow kinetics of Faradaic reactions and sluggish ion diffusion in the bulk structure. This is particularly problematic for thick electrodes and electrodes highly loaded with active
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