der Waals force present in between stacked layers of bulk material. These intercalated
compounds can be exfoliated by a modest sonication technique to mono- or few-layer
sheets. In the majority of cases, hydrogen gas is produced due to a reaction between
intercalated ions and water, which further promotes exfoliation. Through these methods,
a high yield of 2D materials can be achieved [38]. Therefore, liquid exfoliation via ion
intercalation is suitable to synthesize 2D materials for bioelectronics. Furthermore, the
electrochemical ion intercalation method has been effectively employed to prepare a
variety of 2D materials [38]. Figure 3.8 shows the schematic representation of 2D gra
phene synthesis through electrochemical assisted liquid exfoliation of graphite. In this
method, electrochemical force and ions for intercalation act as the driving force [39]. The
metallic foils coated with bulk material act as a cathode, while Li foils (intercalating ion)
act as anodes. Under the applied voltage, the layered bulk material is intercalated with Li,
and intercalated material is obtained on the electrodes. Afterward, the electrodes with
intercalated material are washed and the obtained suspension was sonicated for ex
foliation. Later, exfoliated material is centrifuged to obtain mono- or few-layered 2D
material. This approach has many benefits such as high yield, flexibility in various con
ditions, and ecofriendly in nature. However, complexity and irreversibility are the two
major drawbacks that restrict the widespread use of electrochemical intercalation.
Moreover, liquid exfoliation by cation or anion exchange is also utilized to synthesize
2D materials. Layered metal oxides and metal phosphorus trichalcogenides are fre
quently exfoliated through cation exchange [40]. In the process, the layered metal oxide is
immersed in an acidic medium. This resulted in H+ cation exchange and the formation of
FIGURE 3.7
Liquid exfoliation of graphite via sonication to obtain graphene. Adapted with permission [ 36]. Copyright
(2018) Elsevier.
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Bioelectronics