普鲁士蓝及其类似物: Comparison
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基于普鲁士蓝类似物(Prussian blue analogues (PBA)的负极材料(氧化物,硫化物,硒化物,磷化物,硼化物和碳化物)已在能量转换和存储领域进行了广泛的研究。这是由于PBA的独特性能,包括高理论比容量,环保和低成本。s)-based anode materials (oxides, sulfides, selenides, phosphides, borides, and carbides) have been extensively investigated in the field of energy conversion and storage. This is due to PBAs’ unique properties, including high theoretical specific capacity, environmental friendly, and low cost.

  • Prussian blue analogues
  • electrode materials
  • energy storage
  • nanocomposites

1. 普鲁士蓝及其衍生物作为氧化物 Prussian Blue and Its Derivatives as Oxides

1.1.Mechanism 普鲁士蓝作为储能材料的氧化物机理of Oxide Derived from Prussian Blue as Energy Storage Material

研究了基于PB和PBA的中空纳米结构氧化物衍生物作为各种可充电电池系统的负极材料[12,1330313233,3435]。例如,PB 立方体可以导出为 Fe

Oxide derivatives with hollow nanostructures based on PB and PBA were investigated as anode materials for varous kind of rechargeable batteries system[1][2][3][4][5][6][7][8]. For example, PB cube can be derived as Fe

2

O

3 [12]. 这些铁

[3]. These Fe

2

O

3微盒具有不同的物理架构。这些铁的物理结构

microboxes have distinct physical architectures. The physical architectures of these Fe

2

O

3微盒是独一无二的。它们的多孔或空心结构可以改善电解质扩散和锂离子在电极中的传输,这种纳米结构可以有效避免充放电过程中的体积变化[36]。同时,高结晶度和空心铁

microboxes are unique. Their porous or hollow architectures may improve electrolyte diffusion and Li

+

ions transport in the electrode, and this nano structure can effectively avoid volume change during the charging and discharging process [9]. At the same time, high crystallinity and hollow Fe

2

O

3微盒在长期的充电和放电过程中提供结构稳定性。

microboxes provide structural stability during the long terms of charging and discharging process.

除氧化铁外,与结构相关的锂储存特性也可以在PBA衍生的钴氧化物中找到。公司

In addition to iron oxide, structure-related lithium storage properties can also be found in cobalt oxides derived from PBA. Co

3

O

4由于其易于合成和高比容量,已被用于锂离子电池。由于法拉第过程提供的电荷存储,氧化钴引起了很多关注,并作为储能材料进行了很长时间的研究。各种形式的钴氧化物易于合成,具有非常高的理论电容。公司

has been used in Li-ion battery because of its easy synthesis and high specific capacity. Because of the charge storage provided by the Faraday processes, cobalt oxide has attracted a lot of attention and has been studied for a long time as an energy storage material. Various forms of cobalt oxides are easy to synthesize and have very high theoretical capacitance. Co

3

O

4可以在碱性电解质中转化为CoOOH,然后转化为Co

can be converted into CoOOH in an alkaline electrolyte, and then Co

3

O

4可以转换为C

can be converted into CoO2 [10]. Although its theoretical capacitance is high, its practical capacitance is lower due to conductivity reduction and parasitic species formation during the long terms of charging and discharging process. Furthermore, it is noted that the expansion/contraction phenomenon limits the cycling life of cobalt oxide-based electrode. The main way to overcome these shortcomings is to design various high surface area morphologies.

Hu et al. successfully demoO2nstrated [37]虽然其理论电容较高,但由于长时间充放电过程中电导率降低和寄生物种的形成,其实际电容较低。此外,膨胀/收缩现象限制了氧化钴基电极的循环寿命。克服这些缺点的主要方法是设计各种高表面积形态。 胡等人成功论证了Co3O4源自 derived from Co3[公司(中国)Co(CN)6]2 PBA并得到多孔 and obtained the porous Co3O4纳米笼[15]。易某等发现,多孔C nano3O4纳米笼作为锂固体笼的负极具有较好的电化学性能cages [11].这种纳米结构还具有很高的锂存储容量[4]。作为一种储能材料,它还显示出许多优点:(1)多孔壳有利于锂扩散;(2)双峰孔径分布和较大的表面积通过缩短L Yi扩散长度,增加电解液/电极接触面积和增加电解液接触面积来降低电解液电阻;(3)涂层无定形碳能适应循环诱导的应变;(4)表面原子和结构应变由小纳米粒子富集。这些特性使得PBA衍生的多孔 et al. found that porous Co++3O4纳米笼在锂离子电池(LIB)的应用中具有显着优势,可用于制造高性能锂离子电池。所有这些发现都表明,PBA氧化物衍生物作为储能材料具有很大的性能,并且它们将来可用于增强LIB的性能。

1.2. PBA衍生的氧化物作为储能材料的应用

为了追求更高性能的储能材料,研究人员进行了广泛的探索,以进一步改进具有高容量、稳定循环、快速充电能力的新材料。过渡金属氧化物因其易于获得、低成本和高理论比容量,被认为是良好的储能材料[30]。使用PBA衍生的氧化物纳米材料将改善纳米结构电极材料的优化和设计,提高离子扩散能力和结构稳定性,并使高性能储能材料的生产成为可能。例如,Z nanocages had a better electrochemicang等人[12]已经探索了Fl performance2O3由不同温度下的PB立方体制成的盒式二次电池作为LIB的阳极材料。多孔铁2O3由F as the组成的微粒2O3纳米颗粒可以很容易地通过PB纳米立方体在高温下的氧化和分解来合成。当用作锂离子电池的负极材料时,多孔F anode2O3所获得的纳米立方体还显示出优异的循环性能和高比容量(∼800 of lithiumA h solid cage. This nanostructure also has a hig−1h capacity 200for mA g 时−1)lithium storage .在另一项实验中,研究人员发现F As an e2O3微盒也受到壳复杂性的影响[13]。通过PB微立方体的氧化分解和氧化铁壳的晶体生长,证明了具有众多壳结构的各向异性空心结构的可膨胀合成.Fne的循环稳定性2O3具有多个壳的微盒明显高于Frgy storage2O3具有单壳和双壳的微盒。当用作锂离子电池的负极材料时,F mate2O3具有明确的中空结构和带有层状外壳的微孔,显示出高比容量(∼950rial, it also shows mAany advantages: (1) the porous sh g−1ell facilitates Li+ diffusion; (200 mA g 时−1)和出色的循环性能。 同时,金属氧化物与碳材料的结合是提高) the bimodal pore size distribution and larger surface area reduce electrolyte resistance by shortening LIB性能的有益途径。使用两种PBi diffusion length, increasing electrolyte/石墨烯泡沫前驱体,Shao等[14]成功制备了Felectrode area of contact, and increasing electrolyte contact area; (3) coating amorphous carbon can adapt to cyclic-induce2O3/石墨烯泡沫复合材料。准备好的铁2O3/石墨烯泡沫材料用作LIB的独立电极,结合了铅衍生金属氧化物和石墨烯泡沫的优点。它表现出比纯铁更好的储锂性能2O3与石墨烯泡沫由于两种组分的协同作用。这些研究结果将有助于开发和改进用于储能的电极材料。 此外,Hd strain; (4) su等人[15]提出了一种新的简单方法来制造多孔Crface ato3O4基于Kms and structural strain arkendall效应的纳米笼,其中包括PBA Co的热分解3[公司(中国)6]2在400°C下截断纳米立方体。e enriched by small nanoparticles. These characteristics enable PBA-derived porous 这些纳米笼克服了Co的固有缺点。3O4阳极具有稳定性、高容量和优异的循环效率。当应用于锂离子电池的电极材料时,制备的C nanocages to provide significant benefits in the application of Lithium-ion batteries (LIBs), which may be exploited to3O4多孔纳米笼表现出优异的电池性能。电流密度为 300create mA g 时−1,它仍然具有high-performance LIBs. All of these 1465discoveries mA h g 的容量−150个循环后。金属氧化物具有巨大的存储容量;然而,它们在充电和放电时会受到显着的体积波动并且电导率低。Zdemonstrate that PBA oxide derivatives perform greatly as energy storage materials, and that they may be u等人通过煅烧预制PBA Zn克服了这一挑战sed to enhance the performance of LIBs in the future.

1.2. Application of Oxide Derived from PBAs as Energy Storage Material

In order to pursue higher performance energy storage materials, researchers have carried out extensive exploration to further improve the new materials with a high capacity, stable cycle, and fast charging capacity. Because of their ease of availability, low cost, and high theoretical specific capacity, transition metal oxides are regarded as good energy storage materials [1]. The use of PBA-derived oxide nanomaterials will improve the optimization and design of the nanostructured electrode materials, improve ion diffusion ability and structural stability, and enable the production of high-performance energy storage materials. For instance, Zhang et al. [3] have explored the effect of Fe2O3 box secondary cells made of PB cubes at varying temperatures as anode materials for LIBs. Porous Fe2O3 micro particles composed of Fe2O3 nano particles can be easily synthesized by the oxidation and decomposition of PB nano cubes at high temperatures. When used as anode material of LIBs, the porous Fe2O3 nano cube obtained also shows the excellent cycle performance and high specific capacity (∼800 mA h g−1 at 200 mA g−1). In another experiment, researchers discovered that the electrochemical properties of Fe2O3 microboxes are also affected by the shell complexity [2]. The expandable synthesis of anisotropic hollow structures with numerous shell structures was demonstrated by the oxidative decomposition of PB microcube and crystal growth of iron oxide shell. The cycle stability of Fe2O3 microboxes with multiple shells is dramatically higher than that of Fe2O3 microboxes with single and double shells. When it is used as the anode material of LIBs, Fe2O3 has a well-defined hollow structure and microboxes with a layered shell, showing high specific capacity (∼950 mAh g−1 at 200 mA g−1) and outstanding cycle performance.

Meanwhile, the combination of metal oxides and carbon materials is a beneficial way to enhance the performance of LIBs. Using two PB/graphene foam precursors, Shao et al. [12] successfully prepared Fe2O3/graphene foam composites. The prepared Fe2O3/graphene foam material was used as a LIB’s independent electrode, combining the advantages of lead-derived metal oxides and graphene foam. It exhibited better lithium storage performance than pure Fe2O3 and graphene foam due to the synergistic effect of the two components. These research findings will help to develop and improve electrode materials for the storage of energy.

In addition, Hu et al. [11] suggested a new and simple method for creating porous Co3O4 nanocages based on the Kirkendall effect, which includes the thermal decomposition of PBA Co3[Co(CN)6]2 truncated nano cubes at 400 °C. These nanocages overcame the inherent disadvantage of Co3O4 anodes by exhibiting stability, high capacity, and excellent cycle efficiency. When applied to the electrode material of LIBs, the prepared Co3O4 porous nanocage showed excellent battery performance. At a current density of 300 mA g−1, it still had a capacity of 1465 mA h g−1 after 50 cycles. Metal oxides have a huge storage capacity; however, they suffer from significant volume fluctuations and have low conductivity when charged and discharged. Zhu et al. overcame this challenge by calcining preformed PBA Zn

3[公司(中国)

[Co(CN)

6

]

2纳米球用于制造自组装的ZnO/Co

nanospheres to create self-assembled ZnO/Co

3

O

4纳米复合材料[16]。这些氧化锌/钴

nanocomposites [13]. These ZnO/Co

3

O

4纳米复合材料具有良好的循环和储锂能力。所形成的团簇结构的合理设计,加上双组分功能纳米颗粒体系的协同作用,大大提高了由其产生的电极材料的电化学性能。这种特殊的纳米结构具有优越的储锂能力,为LIBs的进一步优化提供了新的方向。

nanocomposites have good cycling and lithium storing capacity. The rational design of the formed cluster structure, together with the synergistic impact of the bicomponent functional nanoparticle system, considerably improves the electrochemical performance of the electrode material generated from it. This special nanostructure has superior lithium storage capacity, which provides a new direction for further optimization of LIBs.

2. Prussian Blue and Its Derivatives as Sulfide

2. 普鲁士蓝及其衍生物作为硫化物

2.1. 硫化物作为储能材料的机理 Mechanism of Sulfide as Energy Storage Material

近年来,金属硫化物已被证明比等效金属氧化物具有更高的导电性、机械稳定性、热稳定性和电化学活性[383940]。金属硫化物具有比同类金属氧化物更高的导电性,以及丰富的价态、机械和热稳定性,所有这些都有利于电化学性能[41]。混合金属硫化物作为电化学储能和转换系统的可行电极材料越来越受欢迎[42]。与单一金属硫化物相比,混合金属硫化物的电化学性能明显更好[1143],这是由于更好的电子导电性和更多样化的氧化还原过程。金属硫化物由于其广泛的氧化还原化学性质、高导电性和两种金属离子的协同作用而成为潜在的电极材料。由于近年来锂硫电池的性能更好,应用广泛,是一种有潜力的新型储能技术,可以满足不断增长的能源需求。典型的LIB由负极、正极、电解质和夹在平行电极之间的隔膜组成[444546]。两种器件的工作原理均为电压驱动阳离子迁移(Na, Li

Metal sulfides have been shown to have higher conductivity, mechanical stability, thermal stability, and electrochemical activity than equivalent metal oxides in recent years [14][15][16]. Metal sulfides offer higher conductivity than comparable metal oxides, as well as a rich valence state, mechanical and thermal stability, all of which are beneficial to electrochemical performance [17]. Mixed metal sulfide is gaining popularity as a viable electrode material for electrochemical energy storage and conversion systems [18]. When compared to a single metal sulfide, mixed metal sulfide performs significantly better electrochemically [19][20], owing to better electronic conductivity and more diverse redox processes. Metal sulfide has emerged as a potential electrode material due to its extensive redox chemistry, high conductivity, and the synergistic action of two metal ions. Because of their better performance and widespread use in recent years, lithium sulfur batteries are a potential new energy storage technology that can fulfill the rising energy demand. A typical LIB is made up of a negative electrode, a positive electrode, an electrolyte, and a separator sandwiched between parallel electrodes [21][22][23]. The working principle of both devices is voltage-driven cation migration (Na

+

, Li

+,H、K 等)或阴离子(俄勒冈州

, H

+

, K

+

, etc.) or anions (OH

等)通过电解质朝向电极进行可逆电化学反应。同时,电子通过外部电路流动以保持电荷平衡。这些锂电池需要适当有效的材料,特别是作为基体、夹层和层压金属有机骨架作为新型多孔材料。电极材料的化学特性和物理结构必须适合于高效的储能系统[4748]。金属有机骨架复合材料和MOF衍生物具有更好的性能,减少了纯MOF的缺点[4950]。

, etc.) through electrolyte towards electrodes for reversible electrochemical reactions. At the same time, electrons flow via the external circuit to keep the charge balanced. These lithium batteries require appropriate and effective materials, particularly as matrix, sandwich, and laminated metal organic skeleton as a novel porous material. The chemical characteristics and physical architectures of electrode materials must be appropriate for an efficient energy storage system [24][25]. Metal–organic framework composites and MOF derivatives have a better performance, reducing the shortcomings of pure MOFs [26][27].

Previous research found that interstitial water promoted the insertion and extraction of multivalent ions. PBAs have excellent electrochemical performance because water weakens the electrostatic repulsion between ions, lowering the activation energy of ion diffusion and interface transfer [28]. Lithium ion is relatively easy to embed in PBAs for ion diffusion, whereas sodium or potassium are more difficult to embed due to defects that inhibit sodium/potassium diffusion and coordination water. The vacancy and water content in PBA will be significantly reduced through a well controlled crystallization process, so that the cycle capacity and capacity of sulfur ion battery (SIB) and LIB can be improved [29]. PBA and its sulfide derivatives play an important role in the application of energy storage materials because they provide sufficient gaps for the transfer of ions and electrolytes, as well as many active sites for the insertion of ions.

先前的研究发现,间质水促进了多价离子的插入和提取。PBA具有优异的电化学性能,因为水削弱了离子之间的静电排斥,降低了离子扩散和界面转移的活化能[51]。锂离子相对容易嵌入PBA中以进行离子扩散,而钠或钾由于抑制钠/钾扩散和配位水的缺陷而更难包埋。通过控制良好的结晶过程,PBA中的空位和含水量将显着降低,从而提高硫离子电池(SIB)和LIB的循环容量和容量[52]。PBA及其硫化物衍生物在储能材料的应用中起着重要作用,因为它们为离子和电解质的转移提供了足够的间隙,并为离子的插入提供了许多活性位点。

2.2. Application of Sulfide as Energy Storage Material

2.2. 硫化物作为储能材料的应用

PB及其硫化物衍生物因其优异的性能而受到许多研究人员的青睐,因此PB及其硫化物衍生物在储能材料中有许多应用。

PB and its sulfide derivatives are favored by many researchers because of their excellent performance, so PB and its sulfide derivatives have many applications in energy storage materials.

以PB为起始原料,经过两步原位转化工艺合成了分级硫化铁纳米立方体,并涂覆多层石墨烯(Fe

A graded iron sulfide nano cube was synthesized using PB as the starting material in a two-step in situ transformation process, and it was coated with several layers of graphene (Fe

1-xS@C/rGO)。当用作SIB的阳极时,梯度纳米立方体表现出323 mAh g的优异倍率能力

S@C/rGO). When used as the anode of SIBs, the graded nano cube shows excellent rate capability of 323 mAh g

−1电流密度为 10 A g 时

at a current density of 10 A g

−1 [17.150次循环,铁基钠离子电池的分类为Fe

[30]. For 150 cycles, the iron base sodium ion battery has a classification of Fe

1-xS@C/rGO阳极,PB阴极容量为323 mAh g

S@C/rGO anode and the capacity of PB cathode is 323 mAh g

−1.铁

. The Fe

1-xS@C/rGO纳米立方体具有稳定的层状建筑结构和转化过程中获得的高度石墨化的碳,具有良好的钠离子存储性能。石墨烯涂层的纳米立方体结构阻止了硫化铁碳核壳纳米颗粒的融合,也适应了循环过程中的大体积膨胀。碳的高结晶度赋予了良好的电子导电性,使钠离子可及性,并增强了铁的机械耐久性

S@C/rGO nano cube has good sodium ion storage performance due to the stable layered building structure and highly graphitized carbon obtained during the conversion process. The nano cube structure of graphene coating prevents the amalgamation of iron sulfide carbon core–shell nanoparticles and also adapts to the large volume expansion during the cycle. Carbon’s high crystallization degree conferred great electronic conductivity, enabled sodium ion accessibility, and enhanced mechanical durability on Fe

1-xS@C/rGO纳米立方体。

S@C/rGO nano cubes.

Zeng et al. created 3D hollow CoS2 nanoframes (HCSN) using partial anion replacement of Co-based PB nano cubes [31]. Because of its uniform broken hollow structure and excellent dispersion, the synthesized three-dimensional (3D) HCSN has a large specific surface area, leading to good electrochemical performance, such as the high specific capacitance of 568 F g−1 at 0.5 A g−1 and the excellent cycle stability of 88.3% specific capacitance retention after 5000 cycles. The HCSN supercapacitor has a great energy density of 32.3 Wh kg−1 and a power density of 4 kW kg−1. The HCSN also exhibit excellent structural stability and low density, indicating a potential application in energy storage materials.

The development of these new devices and their high performance show that PB sulfide derivatives play a significant role in the application of energy storage materials, as well as offering new ideas for the further development and utilization of sulfide in the future.

3. Prussian 普鲁士蓝及其衍生物作为硒化物Blue and Its Derivatives as Selenide

3.1. 硒化物作为储能材料的机理Mechanism of Selenide as Energy Storage Material

最近,许多研究人员对过渡金属硒化物产生了兴趣,它具有高转化率和容量的优点[54]。与金属硫化物和金属氧化物相比,过渡金属硒化物具有弱金属硒离子键,有利于Recently, many researchers have become interested in transition metal selenides, which have the advantages of a high conversion rate and capacity [32]. Compared with metal sulfides and metal oxides, transition metal selenides have weak metal selenium ion bonds, which is conducive to the rapid transport of Li/Na的快速传输[5556]。由于硒( [33][34]. Metal selenides have the potential of cycle stability and excellent charge discharge specific capacity due to the powerful electronic conductivity of Se (1 × 10)强大的电子导电性,金属硒化物具有循环稳定性和出色的充放电比容量的潜力++−5 S m−1)和弱电负性。在已发现的钠离子电池正极材料中,具有巨大理论容量的金属硒化物被认为是一个有希望的候选者。然而,金属硒化物负极仍存在电子导电性差、初始库仑效率低、充放电过程中体积变化快等问题。此外,“聚硒化物的穿梭效应”(溶解在正极和负极之间的聚硒化物的穿梭)将导致循环过程中的容量下降。因此,为了缓解这些问题,已经采取了许多缓解措施。MOF因其良好的形貌、高比表面积和均匀的多孔结构,最近被用作制备金属氧化物和硫化物中空结构的前驱体。由于其特殊的尺寸和形状依赖性,PB及其类似物由与刚性有机氰基团配位的金属离子组成,并已发展用于设计和制备各种多孔纳米结构[3357]。

3.2. 硒化物作为储能材料的应用

PB) and weak electronegativity. A硒化物衍生物可用于构建具有高比表面积和独特形状的多孔或中空纳米结构,可促进电子传输,同时避免显着的体积膨胀,从而提高电导率[585960]。同时,通过结合不同带隙的纳米材料,可以促进Lmong the discovered cathode materi/Na的扩散速率,加速表面反应动力学,可以形成具有独特界面效果的双金属硒化物结构设计。PBA硒化物衍生物在储能材料中有着广泛的应用。此外,PBA作为由金属中心和有机连接器组成的MOF,可作为合成多孔材料的自模板[61]。MOF可以原位限制和生成小尺寸金属颗粒,然后可用于设计金属硒化物。由于它们的优异特性,许多研究人员被吸引来开发和使用它们。++

4. 普鲁士蓝及其衍生物作为磷化物

4.1. 磷化物作为储能材料的机理

过渡金属磷化物是LIBls for s极性材料的候选材料之一,因为它们具有良好的极性、高催化活性、热稳定性和化学稳定性[676869]。因此,研究TMP在Lodi-S电池中的使用至关重要。Huang等人利用密度泛函理论表明,FeP可以与多硫化物形成增强键,促进进一步的氧化还原转化[70]。Cm ion batteries, metal selenides with huge theoreng等人[71]创建了双层Ntical capacity are regarded as a promising candidate. However, metal selenide anodes are still plagued by poor electron conductivity, low initial coulomb efficiency, and rapi-Fd volume change-P/N掺杂碳纳米材料,并证明了其在LIBs中的稳定循环和优异的倍率性能。硬碳和软碳是最常见的负极材料,但它们的容量有限(通常小于300 mAh during charging and discharging. In addition, the “shuttle effect of polyselenides” (shuttle of polyselenides dissolved between positive and neg−1ative electrodes) [72]。will lead to capacity FdeP最近被认为是一个潜在的候选者,因为它具有良好的理论容量(926 mAh g−1)、中等操作潜力和环境友好性[73]。然而,必须解决与Fgradation during the cycleP颗粒不可忽略的体积变化和低固有电导率有关的主要问题,这将大大降低动力学与循环稳定性之间的关系[74]。为了解决前面提到的比容量和循环稳定性之间的权衡,减小粒径可以有效减少扩散长度,同时增加钠扩散系数[7576]。F. As a reP纳米颗粒(12sult, nm)锚定并均匀分散在氮掺杂的碳框架(FeP@NC)上。它具有更大的可逆容量,为253.9 mAh g−1低于umerous mitigation measures have been implemented in order 2to A g−1alleviate these [77]issues. 考虑到MOFe在PB框架中的均匀分布,预计PB的磷化/碳化将导致FeP纳米颗粒在碳基体中的均匀分布。

4.2. 磷化物作为储能材料的应用

PBA磷化物衍生物在储能材料中的优异性能使其受到许多研究人员的青睐,许多研究人员已经开发和应用了它们。 S has recently been used as a precursor for preparing等人[20]使用F hollow structures of me-Ntal oxi-P@nitrogen掺杂的碳(Fe-Ni-P@NC),衍生自Fe-Ni PBA,用作Li-S电池的高效硫宿主。Fe-Ni-P颗粒不仅有效促进LiPS的转化,而且提高了LiPS的吸附性。此外,PBAs的CN-在热解过程中容易转化为氮掺杂碳,可以提高复合材料的导电性。由于这些优点,具有S@Fe-Ni-P@NC复合阴极的LIBs/SIBs表现出优异的电化学性能、优异的倍率能力,在500des and sulfides due to its good morphology, high surface area, and uniform porous structure. Because of its special size and shape dependence, PB and its analogues are composed of metal ions coordinated with rigid organic cyano groups and have been evolved for the design and preparation of various porous nanostructures °C下循环1次,每次循环的容量衰减率低,为0[6][35].08%。

3.2. Application of Selenide as Energy Storage Material

PBA selenide derivatives can be used to build porous or hollow nanostructures with a high specific surface area and a unique shape that promotes electron transmission while avoiding significant volume expansion and thereby improving conductivity [36][37][38]. At the same time, by combining nanomaterials with different band gaps, it can promote the diffusion rate of Li+/Na+ and accelerate the surface reaction kinetics, which can form the design of bimetallic selenide architecture with unique interface effects. PBA selenide derivatives have a wide range of applications in energy storage materials. In addition, PBAs, as a MOF composed of metal centers and organic connectors, are available as self templates for the synthesis of porous materials [39]. MOF can limit and generate small size metal particles in situ, which can then be used to design metal selenides. Due to their excellent properties, many researchers are drawn to develop and use them.

Zhang et al. took full advantage of the porosity of PBA materials and the high capacity and high conversion of selenides, and used Zn-Fe PBA@polydopamine as a precursor to carbonization-selenization to design the microporous nanostructure ZnSe-Fe3Se4@NC successfully [45]. In addition, they investigated the electrochemical performance of N-doped Zn-Fe-Se heterostructures in LIBs. The ZnSeFe3Se4@NC anode exhibits excellent cycle stability and rate performance at 1 A g−1 after 723 cycles for LIBs (900 mA h g−1) because of the advantages of high conductivity carbon coating and porous structure. Previous research has shown that nanostructure fabrication and hybridization with carbonaceous materials are effective methods for mitigating mechanical strain caused by volume and structure changes during charge and discharge processes [40][41]. On the one hand, due to the short transmission path, reducing the electrochemical active materials to nano scale facilitates ions and electrons [42]. The carbonaceous reagent, on the other hand, can not only improve the transmittance of the electrode but also act as an effective buffer matrix to mitigate volume and structure changes during the cycle [43]. Wang et al. [44] successfully designed porous Mn-Fe-Se adhered/inserted with interlaced CNTs using a simple chemical precipitation approach and a one-step carbonization-selenization of the Mn-Fe PBA precursor process. Mn-Fe-Se/CNT exhibit remarkable electrochemical properties as well as high cycling and rate capabilities due to the synergistic effect of interlaced CNT. N-doped FeC@C box, which acts as the efficient polyselenide reservoir, is successfully created via a simple pyrolysis method using PB nano cubes as a precursor by Wang et al. [45]. Their results show that the PBA selenide derivative battery has high reversible specific capacity, better conduction rate, and cycle stability.

The above results indicate that PBA selenide is a promising electrode material for LIB. This result is expected to arouse people’s interest in energy storage and conversion of PBA selenide derivatives.

4. Prussian Blue and Its Derivatives as Phosphide

4.1. Mechanism of Phosphide as Energy Storage Material

Transition metal phosphides are one of the candidates for LIBs polar materials, because they have good polarity, high catalytic activity, thermal stability, and chemical stability [46][47][48]. Therefore, it is critical to investigate the use of TMPs in Li-S batteries. Huang et al., using the density functional theory, showed that FeP can form a strengthening bond with polysulfides, promoting further redox conversion [49]. Cheng et al. [50] created double-layer Ni-Fe-P/N-doped carbon nanomaterials and demonstrated their stable cycle and excellent rate performance in LIBs. Hard carbon and soft carbon are the most common anode materials, but their capacities are limited (generally less than 300 mAh g−1)[51]. FeP has recently been considered as a potential candidate due to its good theoretical capacity (926 mAh g−1), medium operational potential, and environmental friendliness [52]. Nevertheless, major problems related to the non-negligible volume change of FeP particles and low inherent conductivity must be solved, which will greatly reduce the relationship between dynamics and cycle stability [53]. To address the previously mentioned tradeoff between specific capacity and cycle stability, particle size reduction can effectively decrease diffusion length while increasing sodium diffusion coefficient [54][55]. FeP nanoparticles (12nm) anchored and uniformly dispersed on nitrogen-doped carbon frames (FeP@NC). It has a greater reversible capacity of 253.9 mAh g−1 under 2 A g−1 [56]. Considering the uniform distribution of Fe in the PB framework, it is expected that the phosphating/carbonization of PB will lead to the uniformly distributed of FeP nanoparticles in the carbon matrix.

4.2.Application of Phosphide as Energy Storage Material

The excellent properties of PBA phosphide derivatives in energy storage materials make them favorable to many researchers, and many researchers have developed and applied them.

Song et al. [57] used Fe-Ni-P@nitrogen-doped carbon (Fe-Ni-P@NC) derived from Fe-Ni PBA, which is used as the efficient sulfur host of Li-S batteries. Fe-Ni-P particles not only effectively promote the conversion of LiPS, but also improve the adsorption of LiPS. Furthermore, the CN- of PBAs is easily converted into nitrogen-doped carbon during pyrolysis, which can improve the composite’s conductivity. Because of these benefits, LIBs/SIBs with S@Fe-Ni-P@NC composite cathodes demonstrated excellent electrochemical performance, excellent rate capability, and a stable cycle of 500 cycles at 1 ℃, and the capacity decay rate of each cycle is low, 0.08%.

By combining the tubular PB cathode with its derived phosphating anode, Jiang et al. demonstrated an excellent sodium ion battery [22][58]. Because of the tubular configuration, the PB has fast reaction kinetics and, thus, a high specific capacity of 94.4 mAh g−1 even at a high rate of 5.0 A g−1. PB-derived phosphides are characterized by encapsulating FeP nanoparticles in a conductive carbon matrix, thereby achieving excellent sodium energy storage. The as-assembled sodium-ion full cell has a record capacity of 105.3 mAh g−1 at 2.0 A g−1 and a long cycling lifetime. Their research proposes a homologous design strategy for outstanding sodium-ion full cells based on PB and its derivatives.

5. Prussian Blue and Its Derivatives as Boride

5.1. Mechanism of Boride as Energy Storage Material

Metal borides’ electrochemical properties have been extensively researched due to their high chemical stability, low cost, conductivity, and unique electronic interaction between boron atoms and metal atoms [78][59]. Metal boride nanostructures can open up an entirely new dimension for harnessing these properties. Nanostructures can provide advantages such as increased surface area, easier access to exposed catalytic centers, faster reaction rate kinetics, tunable electronic structures, and lower charge transfer resistance [79,80][60][61]. Recent research has revealed that transition metal borides have the potential to be effective electrocatalysts for water splitting [81,82,83][62][63][64]. Bimetallic and ternary borides have been shown to have higher electrocatalytic activity than single-metal borides due to a synergistic effect [84,85][65][66]. Schuhmann et al. used operando X-ray absorption spectroscopy on ultrathin nickel boride nanosheets to demonstrate this aspect [82][63]. These studies clearly illustrate that the surface oxidation states change from Ni2+ to Ni3+ during the oxygen evolution reaction (OER) process, resulting in the formation of a NiO(OH) surface layer on a NiB@NiO(OH) core–shell structure. Amorphous cobalt boride nanosheets are also effective at OER electrocatalytic water splitting [86][67]. NiCoB and NiFeB nanosheet heterostructures with r-GO and single phase borated metal boride layers exhibit good performance in OER electrocatalysis [87,88][68][69]. The presence of heteroatoms is thought to reduce charge transfer resistance, increase the density of active catalytic sites, and ease electronic state regulation. As a type of MOF family, PBAs have been used as precursors or templates for metal hydroxides, phosphides, and sulfides. PBAs can be converted into various nanostructured metal borides by mild chemical reduction based on their different structures and metal ions. Many researchers worked on developing this material, which has excellent performance in the field of energy storage.

5.2. Application of Boride as Energy Storage Material

PBA boride derivatives have been developed and utilized for their excellent properties in energy storage materials. He et al. synthesize amorphous Co-Ni-B-O nanosheets (CNBO-NSs) by chemically reducing bimetallic PBA (Co-Ni PBAs) with sodium borohydride [23][70]. The electrochemical catalytic activity and stability of the as-prepared CNBO-NSs are excellent. During 24 h operation, they can maintain a current density of 10 mA cm−2 at 140 mV over potential for hydrogen evolution and 300 mV for oxygen evolution. The formation of metal boron bonds, as well as an increase in surface area and conductivity in the CNBO-NS structure, are the factors that contribute to the increase in catalytic activity. This research can provide new insights for the application of MOF in the design of functional nanomaterials, as well as valuable insights for efficient electrolytic energy conversion and other aspects of crystallization engineering. As an efficient and durable electrocatalyst for OER, CoFe-based nanomaterials derived from PBA have increased specific surface area and rich catalytic active sites. Yang et al. [24][71] found that due to the adjustable chemical conformation and controllable 3D morphology, CoFe-B nano cube has a nano cube structure wrapped in ultra-thin nano sheets, and has excellent electrocatalytic performance and remarkable reaction kinetics in 1.0 m KOH aqueous solution. Furthermore, CoFe-B nano cubes have overpotentials of 261 and 338 mV at current densities of 10 and 200 mA cm−2, respectively, with a small Tafel slope of 61 mV dec1 for OER. The unique ultra-thin nano sheet wrapped nano cube structure is largely responsible for the excellent electrocatalysis performance. This work not only introduces a new method for using PBA, but it also introduces an efficient scheme for electrocatalysis.

6. Prussian Blue and Its Derivatives as Carbide

6.1. Mechanism of Carbide as Energy Storage Material

Metal carbides are ideal electrode materials for electrochemical storage devices (such as LIB and the supercapacitor) because of their excellent stability, good conductivity, and high theoretical capacity [89,90][72][73]. Metal carbides have greater electronic conductivity and mechanical stability, as well as corrosion resistance, due to their special atomic structure in which carbon atoms are found in the voids between densely packed metallic host atoms [90,91][73][74]. Gogotis et al. proved that two-dimensional layered carbides can be used as anode materials for LIBs, and found that the Li storage mechanism is the intercalation and de intercalation of Li layers. Furthermore, Gogotsi and his colleagues demonstrated the potential of layered carbides as electrode materials for supercapacitors [92][75]. When PBAs are combined with carbides, two-dimensional layered carbides act as a binder and conductive additive to connect the nanoparticles, facilitating charge transfer and avoiding the significant drop in electrode conductivity that would otherwise occur. PBAs can increase interlayer space, electrolyte diffusion, and battery electrochemical activity, making them perfect for all aspects of the energy storage sector. In addition, metal carbides and carbon-encapsulated metal/metal alloys exhibit outstanding electrocatalytic activity due to the synergistic impact between carbon materials and metals. PB/PBA nanoparticles with uniform element distribution and abundant cyanide ligands are also being investigated as chemical precursors for the preparation of catalytic metal carbides and carbon-encapsulated metal/metal alloys [93][76]. Because of the superior features of metal carbides, they offer significant benefits in the fields of energy storage and electrocatalysis, and they are frequently investigated and implemented in practice.++

6.2. Application of Carbide as Energy Storage Material

It is an effective method to use PBA as the precursor and provide two metal elements at the same time to form bimetallic carbide and carbon skeleton nanocomposites with distinct structures. Ma et al. developed a method of implanting uniformly distributed carbide nanoparticles into a spherical porous carbon framework to form microspheres similar to pitaya [25][77]. The synthesized pitaya-shaped microspheres can effectively buffer volume changes and prevent Co3ZnC nanoparticles from aggregating during the charging/discharging process of LIBs due to their unique composition and structural characteristics. The porous carbon framework allows unimpeded electron transmission and Li diffusion, and restricts the thin solid electrolyte interface layer to the outer surface of the carbon shell. After 300 charge/discharge cycles, the anodes in LIBs deliver a high capacity of 608 mA h g−1 at 100 mA g−1 and ultrahigh cyclic stability and rate performance with a capacity of 423 mA h g−1 even after 1150 consecutive cycles at 1000 mA g−1. The thermal decomposition of PB produced Fe/Fe3C without altering its original morphology, but the surface area and porosity increased significantly [94][78]. Due to the presence of metallic iron, each of these Fe/Fe3C nanoparticles is uniformly coated with several layers of graphite carbon, which enhances its stability and electronic conductivity. Kumar et al. reported for the first time a one-step method for manufacturing the unique superstructure of carbon-encapsulated Fe/Fe3C nanocomposites for supercapacitor electrodes [26][79]. Nanocomposites with carbon encapsulation have excellent cycle stability and no capacitance decay after 20000 CV cycles. Asymmetric supercapacitors exhibit good electrochemical performance in terms of capacitance, energy, power density, and cycle stability when assembled, which is practical for future applications.

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