JoVE Journal > Chemistry
Summary
Abstract
Introduction
Protocol
Results
Discussion
Disclosures
Acknowledgements
Materials
References
Automatic Translation
Please note that all translations are automatically generated. Click here for the English version.
Chemistry

抑制登德里特的锌海绵电池电极

Published: September 29, 2020
doi:
10.3791/61770
, , , ,
1Naval Research Laboratory, National Research Postdoctoral Associate,U.S. Naval Research Laboratory, Washington, DC, 20375, United States, 2Surface Chemistry Branch,U.S. Naval Research Laboratory, Washington, DC, 20375, United States

Summary

报告协议的目标是制造可充电的锌海绵电极,以抑制锌电池(如镍锌或锌空气)的树突和形状变化。

Abstract

我们报告了两种方法来制造锌海绵电极,以抑制树突的形成和可充电锌电池的形状变化。这两种方法的特点是创建由锌颗粒、有机粥原和粘度增强剂制成的糊糊,这些粘稠性增强剂在惰性气体下加热,然后在空气中加热。在惰性气体加热过程中,锌颗粒一起退火,波源分解:在空气中,锌熔断和残余有机物燃烧,产生开放细胞金属泡沫或海绵。我们通过不同的锌与孢子质量比、惰性气体和空气下的加热时间以及锌和粥原颗粒的大小和形状来调整锌海绵的机械和电化学特性。报告方法的一个优点是它们能够微调锌海绵结构。锌和粥原颗粒的选定大小和形状影响孔隙结构的形态。一个限制是,由此产生的海绵有紊乱的孔隙结构,导致低体积锌(<30%)的机械强度低。这些锌海绵电极的应用包括用于电网存储、个人电子产品、电动汽车和电力航空的电池。用户可以期望锌海绵电极以技术相关速率循环高达 40% 的放电深度,并且无需形成分离器穿孔树突。

Introduction

报告的制造方法的目的是制造锌(Zn)海绵电极,抑制树突的形成和形状的变化。从历史上看,这些问题限制了Zn电池的循环寿命。锌海绵电极解决了这些问题,使Zn电池的循环寿命更长,1,2,3,4,5,6。海绵结构抑制树突的形成和形状的变化,因为(1) 融合的Zn框架电导海绵的整个体积:(2) 孔隙在Zn-海绵表面附近持有锌酸盐:和(3)海绵有一个高表面积,降低局部电流密度低于价值确定发芽树突在碱性电解质7。但是,如果海绵表面积过高,则会发生大量腐蚀。如果海绵毛孔太大,海绵的体积容量将很低。此外,如果海绵孔隙过小,Zn电极在放电过程中电解质将不足以进入Zn,导致功率和容量低5,6。

报告制造方法背后的理由是制造具有适当海绵孔隙和孔径的Zn海绵。实验中,我们发现Zn海绵的孔隙在50%到70%之间,孔径接近10μm的周期在全电池中,并显示低腐蚀率5。我们注意到,现有的商业金属泡沫制造方法未能在这些长度尺度8上达到类似的形态,因此需要报告的制造方法。

这里报告的方法比替代品的优势是,海绵特征的精细控制,并能够制造大型,密集的Zn海绵与技术相关的是容量值5,6,9,10。创建 Zn 泡沫的替代方法可能无法创建具有海绵孔隙接近 50% 的可比 10 μm 毛孔。然而,这种替代品可能需要更少的能量来制造,因为它们避免了高温处理步骤。替代过程包括以下策略:冷烧结Zn粒子11,将Zn沉积在三维宿主结构12,13,14,15,16,17,切割Zn箔成二维泡沫18,并通过脊柱分解19或渗透溶解20产生Zn泡沫。

所报告的方法在更广泛的出版的文献中是主要由钻头等人的作品建立的。他们采用了制造多孔陶瓷的方法,为电池制造了最早报道的三维(尽管很脆弱)Zn泡沫之一。然而,这些作者未能证明可充电性,可能是因为Zn粒子之间的连接性差。在可充电的 Zn-海绵电极之前,Zn 箔电极的最佳替代品是 Zn 粉末电极,其中 Zn 粉末与凝胶电解质混合。锌粉电极在原石碱性电池(Zn-MnO2)中用于商业用途,但充电性差,因为Zn粒子由Zn氧化物(ZnO)钝化,这可以增加局部电流密度,刺激树突生长3,22。我们注意到,还有其他树突抑制策略,不涉及泡沫或海绵结构23,24。

据报道,Zn-海绵的制造方法需要一个管炉,空气和氮气的来源(N2)和烟罩。所有步骤都可以在没有环境控制的情况下在实验室办公桌前执行,但在热处理过程中管炉的排气应管道输送到烟气罩。由此产生的电极适合那些有兴趣创建可充电的Zn电极能够高正位容量(>10毫安厘米地球+2)6

第一个报告的制造方法是一种基于乳液的路线,以创建Zn-海绵电极。第二,是一条基于阿苏的路线。乳液路线的一个优点是它能够创建 Zn 糊状体,当干燥时,很容易从模具腔中脱下。缺点是它依赖昂贵的材料。对于海绵路线,海绵预制件可能具有挑战性,但这个过程使用廉价和丰富的材料。

这两种方法都涉及将 Zn 颗粒与粥原和粘度增强剂混合。产生的混合物在N2 下加热,然后呼吸空气(不是合成空气)。在N2下加热时,Zn颗粒退火和粥原分解:在呼吸空气下,退火的Zn颗粒熔断,粥原燃烧。这些工艺产生金属泡沫或海绵。Zn 海绵的机械和电化学特性可以通过不同的 Zn-porogen 质量比、N2 下的加热时间和空气以及 Zn 和聚源颗粒的大小和形状来调整。

Protocol

1. 制造Zn-海绵电极的乳液方法 在 100 mL 玻璃烧杯中加入 2.054 毫升的去离子水。 在烧饼中加入 4.565 mL 的脱脂。 搅拌0.1000±0.0003克硫酸钠(SDS),直到溶解。 用手搅拌0.0050±0.0003克 水溶性 中粘性甲基纤维素(CMC)钠盐5分钟或直到CMC完全溶解。注意:使用塑料或塑料涂层的搅拌工具。用金属表面的工具搅拌会对由此产生的 Zn 海绵产生不利影响。 搅拌0….

Representative Results

由此产生的,完全热处理,乳液为基础的Zn海绵有2.8克+厘米+3的密度,而水性海绵接近3.3克+厘米+3。在空气加热过程中,Zn 表面形成一层 ZnO,厚度应为 0.5°1.0 μm(使用扫描电子显微镜观察)5。产生的海绵中的固体应该是72%Zn(乳液版本)或78%Zn(水文版本),其余的为ZnO(X射线衍射测量)6。两种海绵的孔隙应接近50%,孔径分布以10μm为中心,?…

Discussion

与这些协议相关的修改和故障排除包括将新混合的 Zn 糊填充到模具腔中。应小心避免气囊。填充后或灌装时点击模具可减少不需要的空隙。由于水性 Zn 糊是干燥的,因此可以直接施加压力到 Zn 糊中,以在填充模具腔的同时推出气囊。

方法的一个局限性是Zn-海绵毛孔结构紊乱,但Zn和波源粒子大小可用于改变孔隙形态。使用添加剂制造可以制造出更有序、可能更坚固、更轻的…

Disclosures

The authors have nothing to disclose.

Acknowledgements

这项研究由美国海军研究办公室资助。

Materials

Corn starch Argo Not applicable This acts as a porogen and viscosity-enhancing agent.
Decane MilliporeSigma D901
Medium viscosity water-soluble carboxymethyl cellulose (CMC) sodium salt MilliporeSigma C4888-500G This CMC acts primarily as a viscosity-enhancing agent.
Overhead stirrer Caframo Lab Solutions BDC3030
Small cylindrical models for Zn sponges VWR 66014-358 The caps of the vials can be used as molds.
Sodium dodecyl sulfate MilliporeSigma 436143
Water-insoluble IonSep CMC 52 preswollen carboxymethyl cellulose resin BIOpHORETICS B45019.01 This CMC acts as a porogen and viscosity-enhancing agent.
Zn powder EverZinc Custom order
DOWNLOAD MATERIALS LIST

References

  1. Parker, J. F., et al. Retaining the 3D Framework of Zinc Sponge Anodes upon Deep Discharge in Zn-Air Cells. ACS Applied Materials & Interfaces. 6 (22), 19471-19476 (2014).
  2. Parker, J. F., Chervin, C. N., Nelson, E. S., Rolison, D. R., Long, J. W. Wiring zinc in three dimensions re-writes battery performance-dendrite-free cycling. Energy & Environmental Science. 7, 1117-1124 (2014).
  3. Parker, J. F., et al. Rechargeable nickel-3D zinc batteries: An energy-dense, safer alternative to lithium-ion. Science. 356 (6336), 415-418 (2017).
  4. Ko, J. S., et al. Robust 3D Zn sponges enable high-power, energy-dense alkaline batteries. ACS Applied Energy Materials. 2 (1), 212-216 (2018).
  5. Hopkins, B. J., et al. Fabricating architected zinc electrodes with unprecedented volumetric capacity in rechargeable alkaline cells. Energy Storage Materials. 27, 370-376 (2020).
  6. Hopkins, B. J., et al. Low-cost green synthesis of zinc sponge for rechargeable, sustainable batteries. Sustainable Energy & Fuels. 4, 3363-3369 (2020).
  7. Yufit, V., et al. Operando Visualization and Multi-scale Tomography Studies of Dendrite Formation and Dissolution in Zinc Batteries. Joule. 3 (2), 485-502 (2019).
  8. Ashby, M. F., et al. . Metal Foams: A Design Guide. , (2000).
  9. Parker, J. F., Ko, J. S., Rolison, D. R., Long, J. W. Translating Materials-Level Performance into Device-Relevant Metrics for Zinc-Based Batteries. Joule. 2 (12), 2519-2527 (2018).
  10. Hopkins, B. J., Chervin, C. N., Parker, J. F., Long, J. W., Rolison, D. R. An areal-energy standard to validate air-breathing electrodes for rechargeable zinc-air batteries. Advanced Energy Materials. 10 (30), 2001287 (2020).
  11. Jayasayee, K., et al. Cold Sintering as a Cost-Effective Process to Manufacture Porous Zinc Electrodes for Rechargeable Zinc-Air Batteries. Processes. 8 (5), 592 (2020).
  12. Chamoun, M., et al. . NPG Asia Materials. 7, 178 (2015).
  13. Kang, Z., et al. 3D Porous Copper Skeleton Supported Zinc Anode toward High Capacity and Long Cycle Life Zinc Ion Batteries. ACS Sustainable Chemistry & Engineering. 7 (3), 3364-3371 (2019).
  14. Yu, J., et al. Ag-Modified Cu Foams as Three-Dimensional Andoes for Rechargeable Zinc-Air Batteries. ACS Applied Nano Materials. 2 (5), 2679-2688 (2019).
  15. Stumpp, M., et al. Controlled Electrodeposition of Zinc Oxide on Conductive Meshes and Foams Enabling Its Use as Secondary Anode. Journal of The Electrochemical Society. 165 (10), 461-466 (2018).
  16. Stock, D., et al. Design Strategy for Zinc Anodes with Enhanced Utilization and Retention: Electrodeposited Zinc Oxide on Carbon Mesh Protected by Ionomeric Layers. ACS Applied Energy Materials. 1 (10), 5579-5588 (2018).
  17. Li, C., et al. Spatially homogeneous copper foam as surface dendrite-free host for zinc metal anode. Chemical Engineering Journal. 379, 122248 (2020).
  18. Zhou, Z., et al. Graphene oxide-modified zinc anode for rechargeable aqueous batteries. Chemical Engineering Science. 194, 142-147 (2019).
  19. McDevitt, K. M., Mumm, D. R., Mohraz, A. Improving Cyclability of ZnO Electrodes through Microstructural Design. ACS Applied Energy Materials. 2 (11), 8107-8117 (2019).
  20. Wang, C., Zhu, G., Liu, P., Chen, Q. Monolithic Nanoporous Zn Anode for Rechargeable Alkaline Batteries. ACS Nano. 14 (2), 2404-2411 (2020).
  21. Drillet, J. F., et al. Development of a Novel Zinc/Air Fuel Cell with a Zn Foam Anode, a PVA/KOH Membrane and a MnO2/SiOC-based Air Cathode. ECS Transactions. 28, 13-24 (2010).
  22. Bozzini, B., et al. Morphological evolution of Zn-sponge electrodes monitored by in situ X-ray computed microtomography. ACS Applied Energy Materials. , (2020).
  23. Yang, Q., et al. Do Zinc Dendrites Exist in Neutral Zinc Batteries: A Developed Electrohealing Strategy to In Situ Rescue In-Service Batteries. Advanced Materials. 31, 1903778 (2019).
  24. Yang, Q., et al. Hydrogen-Substituted Graphdiyne Ion Tunnels Directing Concentration Redistribution for Commercial-Grate Dendrite-Free Zinc Anodes. Advanced Materials. 32, 2001755 (2020).
  25. Narayanan, S. R., et al. Materials challenges and technical approaches for realizing inexpensive and robust iron-air batteries for large-scale energy storage. Solid State Ionics. 216, 105-109 (2012).
  26. Xiong, H., et al. Effects of Heat Treatment on the Discharge Behavior of Mg-6wt.%Al-1wt.%Sn Alloy as Anode for Magnesium-Air Batteries. Journal of Materials Engineering and Performance. 26, 2901-2911 (2017).
  27. Hopkins, B. J., Shao-Horn, Y., Hart, D. P. Suppressing corrosion in primary aluminum-air batteries via oil displacement. Science. 362, 658-661 (2018).
  28. Hopkins, B. J., Long, J. W., Rolison, D. R. High-Performance Structural Batteries. Joule. , (2020).

Tags

Zinc-sponge BatteryZinc ElectrodeDendrite SuppressionCMCCarboxymethyl CelluloseZinc PowderTube FurnaceHeat TreatmentGas Flow
check_url/61770?article_type=t

Play Video
PDF
DOI
DOWNLOAD MATERIALS LIST
Cite This Article
Hopkins, B. J., Sassin, M. B., Parker, J. F., Long, J. W., Rolison, D. R. Zinc-Sponge Battery Electrodes that Suppress Dendrites. J. Vis. Exp. (163), e61770, doi:10.3791/61770 (2020).
Download Citation
Reprints and Permissions

View Video

To prove you're not a robot, please enter the text in the image below

CAPTCHA Image
Play CAPTCHA Audio
Refresh Image