S.W.K. 和 C.P.R. 感谢海军研究办公室海军海底研究计划（批准号：N00014-21-1-2072）的支持。S.W.K. 感谢海军研究企业实习计划的支持。C.P.R和C.M.感谢美国国家科学基金会材料研究与教育伙伴关系（PREM）智能材料组装中心（第2122041号奖项）对反应条件分析的支持。

注：微波合成过程的示意图如 图1所示。
1. α-Ni（OH）2 纳米片的微波合成
<ol><li>前体溶液的制备<ol><li>通过混合 15 mL 超纯水 （≥18 MΩ-cm） 和 105 mL 乙二醇来制备前体溶液。加入 5.0 克 Ni（NO3）2 ·6 H2O和4.1 g尿素溶液并盖上盖子。</li>
		<li>将前体溶液置于充满冰和水的浴超声仪（40kHz频率）中，并以全功率（无脉冲）超声处理30分钟。</li>
	</ol></li>
	<li>前驱体溶液的微波反应<ol><li>将 20 mL 前体溶液转移到带有聚四氟乙烯 （PTFE） 搅拌棒的微波反应瓶中，并用带有 PTFE 衬里的锁定盖密封反应容器。</li>
		<li>使用设置对微波反应器进行编程，使其尽可能快地加热到反应温度（至120或180°C），并在该温度下保持13-30分钟。 注意： 尽可能快的加热是一种微波设置，可施加最大微波功率，直到达到所需温度;此后施加可变功率以保持反应温度。</li>
		<li>反应完成后，用压缩空气排出反应室，直到溶液温度达到55°C。 反应的每个阶段（加热、保持和冷却）在 600 rpm 的磁力搅拌下进行。</li>
	</ol></li>
	<li>离心洗涤微波反应沉淀。<ol><li>将反应后溶液转移到 50 mL 离心管中。在室温下以6,000rpm / 6,198rcf离心反应后溶液4分钟，然后倾析上清液。</li>
		<li>加入 25 mL 超纯水以重悬纳米片。使用相同的条件离心，然后倒出上清液。</li>
		<li>用水重复洗涤、离心和倾析步骤共五次，然后用乙醇重复三次。 注意：异丙醇也可以用来代替乙醇。</li>
	</ol></li>
	<li>测量微波反应前后的pH值<ol><li>在开始微波反应之前测量前体溶液的pH值，并在第一次离心后立即测量上清液的pH值。</li>
	</ol></li>
	<li>干燥样品<ol><li>用纸巾或纸巾覆盖离心管，作为多孔盖，以减少潜在的污染，并在70°C的样品箱中在环境气氛下干燥21小时。 注：干燥时间和条件会影响（XRD）峰的相对强度和2θ°值，如代表性结果中所述。</li>
	</ol></li>
</ol>2. 材料表征与分析
<ol><li>使用扫描电子显微镜 （SEM） 和能量色散 X 射线光谱 （EDS） 表征其形态和组成<ol><li>使用水浴超声仪将少量 Ni（OH）2 粉末悬浮在 1 mL 乙醇中，制备用于 SEM 和 EDS 分析的样品。</li>
		<li>将Ni（OH）2 /乙醇混合物浇注在SEM存根上，并通过将SEM存根置于70°C的样品箱中蒸发乙醇。</li>
		<li>收集SEM显微照片和EDS光谱。在 6.5 kX、25 kX 和 100 kX 的放大倍率下，使用 10 kV 的加速电压和 0.34 nA 的电流收集 SEM 图像。使用 10 kV 的加速电压、1.4 nA 的电流和 25 kX 的放大倍率收集选定区域的 EDS 光谱。</li>
	</ol></li>
	<li>使用氮物理吸附孔隙度法分析表面积和孔隙率<ol><li>通过向样品管中加入 25 mg Ni（OH）2 来制备用于分析的样品。在分析前在120°C的真空下进行预分析脱气和干燥程序16小时。</li>
		<li>将样品管从脱气口转移到分析口以收集氮气 （N2） 等温线。</li>
		<li>使用 Brunauer-Emmett-Teller （BET） 分析 N2 等温线数据以确定比表面积。根据国际纯粹与应用化学联合会 （IUPAC） 方法33 进行 BET 分析。用于执行BET分析的特定分析软件包包含在 材料表中。</li>
		<li>使用Barrett-Joyner-Halenda（BJH）方法分析等温线的解吸分支，以获得孔体积，孔径和孔径分布。根据 IUPAC 方法进行 BJH 分析。33 用于进行 BJH 分析的特定分析软件包包含在 材料表中。</li>
	</ol></li>
	<li>使用粉末 X 射线衍射 （XRD） 进行结构分析<ol><li>用Ni（OH）2填充零背景粉末XRD支架的样品孔，确保粉末表面平坦。</li>
		<li>使用 CuKα 5°-80° 2θ 之间的辐射源以 0.01 步长收集粉末 X 射线衍射图。</li>
		<li>使用布拉格定律分析d间距， nλ = 2d sinθ， 其中 n 是整数，λ 是 X 射线的波长， d 是 d 间距， θ 是入射光线与样品之间的角度。</li>
		<li>使用 Scherrer 方程分析微晶畴 大小 D， <img alt="Equation 1" src="/files/ftp_upload/65412/65412eq01.jpg" style="margin: auto;"> 其中 Ks 是 Scherrer 常数（分析使用 0.92 的 Scherrer 常数）， λ 是 X 射线的波长，β2θ是衍射峰的积分宽度，θ 是布拉格角（以弧度为单位）。为了进行分析，取β2θ作为半最大值 （fwhm） 的全宽，并乘以常数 0.939434。</li>
	</ol></li>
	<li>使用衰减总反射率-傅里叶变换红外光谱 （ATR-FTIR） 表征材料<ol><li>将衰减总反射率 （ATR） 附件配备到傅里叶变换红外 （FTIR） 光谱仪。</li>
		<li>在两个载玻片之间按压少量 Ni（OH）2 粉末以形成小颗粒。</li>
		<li>将 Ni（OH）2 颗粒放在硅 ATR 晶体上，获得 400 至 4,000 cm-1 之间的 FTIR 光谱。红外光谱代表 16 次分辨率为 4 cm-1 的单独扫描的平均值。</li>
	</ol></li>
</ol>

氢氧化镍纳米片的微波合成与表征

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F., Genzel, C. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=.">.</a> Thin Film Analysis by X-ray Scattering. , (2006).</li><li>Hall, D. S., Lockwood, D. J., Poirier, S., Bock, C., MacDougall, B. R. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Raman+and+infrared+spectroscopy+of+alpha+and+beta+phases+of+thin+nickel+hydroxide+films+electrochemically+formed+on+nickel.">Raman and infrared spectroscopy of alpha and beta phases of thin nickel hydroxide films electrochemically formed on nickel.</a> Journal of Physical Chemistry A. 116 (25), 6771-6784 (2012).</li><li>Choy, J. H., Kwon, Y. M., Han, K. S., Song, S. W., Chang, S. H. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Intra-+and+inter-layer+structures+of+layered+hydroxy+double+salts,+Ni1-xZn2x(OH)2(CH3CO2)2xnH2O.">Intra- and inter-layer structures of layered hydroxy double salts, Ni1-xZn2x(OH)2(CH3CO2)2xnH2O.</a> Materials Letters. 34 (3-6), 356-363 (1998).</li><li>Momma, K., Izumi, F. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=VESTA+for+three-dimensional+visualization+of+crystal,+volumetric+and+morphology+data.">VESTA for three-dimensional visualization of crystal, volumetric and morphology data.</a> Journal of Applied Crystallography. 44 (6), 1272-1276 (2011).</li><li>Godinez-Salomon, F., Mendoza-Cruz, R., Arellano-Jimenez, M. J., Jose-Yacaman, M., Rhodes, C. P. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Metallic+two-dimensional+nanoframes:+unsupported+hierarchical+nickel-platinum+alloy+nanoarchitectures+with+enhanced+electrochemical+oxygen+reduction+activity+and+stability.">Metallic two-dimensional nanoframes: unsupported hierarchical nickel-platinum alloy nanoarchitectures with enhanced electrochemical oxygen reduction activity and stability.</a> ACS Applied Materials &amp; Interfaces. 9 (22), 18660-18674 (2017).</li><li>Shakhashiri, B. Z., Dirreen, G. E., Juergens, F. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Color,+solubility,+and+complex+ion+equilibria+of+nickel+(II)+species+in+aqueous+solution.">Color, solubility, and complex ion equilibria of nickel (II) species in aqueous solution.</a> Journal of Chemical Education. 57 (12), 900-901 (1980).</li></ol>

作者没有利益冲突。

微波合成提供了一种生成Ni（OH）2的途径，与传统的水热方法（典型反应时间为4.5小时）相比，该途径明显更快（13-30分钟的反应时间）38。使用这种弱酸性微波合成途径生产超薄α-Ni（OH）2纳米片，观察到反应时间和温度会影响反应的pH值、产率、形貌、孔隙率和所得材料的结构。使用原位反应压力表，在两个120°C反应期间都会发生非常少量的压力积聚，?...

氢氧化镍 Ni（OH）2 用于多种应用，包括镍锌和镍氢电池1、2、3、4、燃料电池4、水电解槽4、5、6、7、8、9、超级电容器4、光催化剂4、阴离子交换剂10，以及许多其他分析、电化学和传感器应用 4,5。Ni（OH）2 具有两种主要晶体结构：β-Ni（OH）2 和 α-Ni（OH）211。β-Ni（OH）2 采用水镁铁矿型 Mg（OH）2 晶体结构，而 α-Ni（OH）2 是 β-Ni（OH）2 的涡轮层状形式，夹有化学合成4 的残余阴离子和水分子。在 α-Ni（OH）2 中，插层分子不在固定的晶体位置内，但具有一定程度的取向自由度，并且还起到稳定 Ni（OH）2 层的层间胶的作用 4,12。α-Ni（OH）2 的层间阴离子影响平均 Ni氧化态 13，并影响 α-Ni（OH）2（相对于 β-Ni（OH）2）对电池2、13、14、15、电容器16 和水电解应用17,18 的电化学性能。
Ni（OH）2 可通过化学沉淀、电化学沉淀、溶胶-凝胶合成或水热/溶剂热合成4.化学沉淀和水热合成路线在Ni（OH）2的生产中被广泛应用，不同的合成条件改变了其形貌、晶体结构和电化学性能。Ni（OH）2 的化学沉淀涉及将高碱性溶液添加到镍 （II） 水溶液中。沉淀物的相和结晶度由所用镍（II）盐和碱性溶液的温度、特性和浓度决定4。
Ni（OH）2 的水热合成涉及在加压反应瓶中加热前体镍 （II） 盐的水溶液，允许反应在高于环境压力4 下通常允许的温度下进行。水热反应条件通常有利于β-Ni（OH）2，但α-Ni（OH）2 可以通过以下方式合成：（i）使用插层剂，（ii）使用非水溶液（溶剂热合成），（iii）降低反应温度，或（iv）在反应中加入尿素，从而产生氨插层α-Ni（OH）24。镍盐中 Ni（OH）2 的水热合成通过两步过程进行，该过程涉及水解反应（公式 1），然后是醇化缩合反应（公式 2）。19
[镍（H2O）N]2+ + hH2O ↔ [Ni（OH）h（H2O） N-h]（2-h）++ hH3O+ （1）
Ni-OH + Ni-OH2 Ni-OH-Ni + H2O （2）
微波化学已被用于各种纳米结构材料的一锅合成，并且基于特定分子或材料将微波能量转化为热量的能力20。在传统的水热反应中，反应是通过反应器直接吸收热量来引发的。相反，在微波辅助水热反应中，加热机理是溶剂在微波场中振荡的偶极极化和产生局部分子摩擦的离子传导20。微波化学可以提高化学反应的反应动力学、选择性和产率20，这使得合成Ni（OH）2的可扩展、工业上可行的方法具有重要意义。
对于碱性电池阴极，与β-Ni（OH）2相13相比，α-Ni（OH）2相提供了更好的电化学容量，合成α-Ni（OH）2的合成方法特别令人感兴趣。α-Ni（OH）2 已通过多种微波辅助方法合成，包括微波辅助回流21,22、微波辅助水热技术 23,24 和微波辅助碱催化沉淀25。在反应溶液中加入尿素会显著影响反应产率26、机理26、27、形貌和晶体结构27。微波辅助分解尿素被确定为获得α-Ni（OH）227的关键组分。乙二醇-水溶液中的水含量已被证明会影响微波辅助合成α-Ni（OH）2纳米片的形态24。当使用硝酸镍水溶液和尿素溶液通过微波辅助热液途径合成时，α-Ni（OH）2 的反应产率取决于溶液pH 26。先前使用 EtOH/H2O、硝酸镍和尿素的前体溶液对微波合成的 α-Ni（OH）2 纳米花的研究发现，温度（在 80-120 °C 范围内）不是关键因素，前提是反应在尿素水解温度 （60 °C） 以上进行）27。最近一篇研究使用乙酸镍四水合物、尿素和水的前驱体溶液微波合成 Ni（OH）2 的论文发现，在 150 °C 的温度下，该材料同时含有 α-Ni（OH）2 和 β-Ni（OH）2 相，这表明温度可能是合成 Ni（OH）2的关键参数 28.
微波辅助水热合成可用于通过使用溶解在乙二醇/H2O溶液12,29,30,31中的金属硝酸盐和尿素组成的前驱体溶液来生产高比表面积的α-Ni（OH）2和α-Co（OH）2。使用为大型微波反应器设计的放大合成合成，合成了用于碱性镍锌电池的金属取代α-Ni（OH）2正极材料12。微波合成的α-Ni（OH）2也被用作制备β-Ni（OH）2纳米片12、析氧反应（OER）电催化剂29的镍铱纳米框架以及燃料电池和水电解槽30的双官能氧电催化剂的前驱体。该微波反应路线也被修改为合成Co（OH）2作为酸性OER电催化剂31和双功能电催化剂30的钴铱纳米框架的前体。微波辅助合成也用于制备Fe取代的α-Ni（OH）2纳米片，Fe取代比改变了结构和磁化强度32。然而，微波合成 α-Ni（OH）2 的分步程序以及评估水-乙二醇溶液中反应时间和温度的变化如何影响材料内层间阴离子的晶体结构、表面积和孔隙率以及局部环境的评估以前没有报道过。
该协议建立了使用快速和可扩展的技术进行α-Ni（OH）2 纳米片的高通量微波合成程序。采用 原位 反应监测、扫描电子显微镜、能量色散X射线光谱、氮气孔隙率、粉末X射线衍射（XRD）和傅里叶变换红外光谱等手段，对反应温度和时间的影响进行了评估，了解合成变量对α-Ni（OH）2 纳米片反应产率、形貌、晶体结构、孔径和局部配位环境的影响。

<table border="1" fo:keep-together.within-page="1" fo:keep-with-next.within-page="always">
	<tbody>
		<tr>
			<td>ATR-FTIR</td>
			<td>Bruker</td>
			<td></td>
			<td>Tensor II FT-IR spectrometer equipped with a Harrick Scientific SplitPea ATR micro-sampling accessory</td>
		</tr>
		<tr>
			<td>Bath sonicator</td>
			<td>Fisher Scientific</td>
			<td>15-337-409</td>
			<td>--</td>
		</tr>
		<tr>
			<td>Ethanol&#160;</td>
			<td>VWR analytical</td>
			<td>AC61509-0040</td>
			<td>200 proof</td>
		</tr>
		<tr>
			<td>Ethylene Glycol</td>
			<td>VWR analytical</td>
			<td>BDH1125-4LP</td>
			<td>99% purity</td>
		</tr>
		<tr>
			<td>Falcon Centrifuge tubes</td>
			<td>VWR analytical</td>
			<td>21008-940</td>
			<td>50 mL</td>
		</tr>
		<tr>
			<td>KimWipes</td>
			<td>VWR analytical</td>
			<td>21905-026</td>
			<td>--</td>
		</tr>
		<tr>
			<td>Lab Quest 2</td>
			<td>Vernier&#160;</td>
			<td>LABQ2</td>
			<td>--</td>
		</tr>
		<tr>
			<td>Microwave Reactor</td>
			<td>Anton Parr</td>
			<td>165741</td>
			<td>Monowave 450</td>
		</tr>
		<tr>
			<td>Ni(NO3)2 &#183; 6 H2O</td>
			<td>Ward&#39;s Science</td>
			<td>470301-856</td>
			<td>Research lab grade</td>
		</tr>
		<tr>
			<td>pH Probe</td>
			<td>Vernier&#160;</td>
			<td>PH-BTA</td>
			<td>Calibrated vs standard pH solutions (pH= 4, 7, 11)</td>
		</tr>
		<tr>
			<td>Porosemeter</td>
			<td>Micromeritics&#160;</td>
			<td>--</td>
			<td>ASAP 2020. Analysis software: Micromeritics, version 4.03</td>
		</tr>
		<tr>
			<td>Powder x-ray diffactometer</td>
			<td>Bruker</td>
			<td></td>
			<td>AXS Advanced Poweder x-ray diffractometer; d-spacing, and crystallite size analyses were performed using Highscore XRD software, and crystal structures were created using VESTA 3 software.</td>
		</tr>
		<tr>
			<td>Reaction vial</td>
			<td>Anton Parr</td>
			<td>82723</td>
			<td>30 mL G30 wideneck, 20 mL max fill capacity</td>
		</tr>
		<tr>
			<td>Reaction vial locking lid</td>
			<td>Anton Parr</td>
			<td>161724</td>
			<td>G30 Snap Cap</td>
		</tr>
		<tr>
			<td>Reaction vial PTFE septum</td>
			<td>Anton Parr</td>
			<td>161728</td>
			<td>Wideneck</td>
		</tr>
		<tr>
			<td>Scanning electron microscope</td>
			<td>FEI</td>
			<td>--</td>
			<td>Helios Nanolab 400</td>
		</tr>
		<tr>
			<td>Urea</td>
			<td>VWR analytical</td>
			<td>BDH4602-500G</td>
			<td>ACS grade</td>
		</tr>
	</tbody>
</table>

effect of microwave synthesis conditions on the structure of nickel hydroxide nanosheets

提出了一种在弱酸性条件下快速微波辅助水热合成氢氧化镍纳米片的方案，并研究了反应温度和时间对材料结构的影响。所有研究的反应条件都产生层状α-Ni（OH）2 纳米片的聚集体。反应温度和时间对材料结构和产物收率有很大影响。在较高温度下合成α-Ni（OH）2 可提高反应产率，降低层间间距，增加晶畴尺寸，改变层间阴离子振动模式的频率，并降低孔径。较长的反应时间可提高反应产率，并产生相似的晶域大小。 原位 监测反应压力表明，在较高的反应温度下获得更高的压力。这种微波辅助合成路线提供了一种快速、高通量、可扩展的工艺，可应用于各种过渡金属氢氧化物的合成和生产，用于多种能量存储、催化、传感器和其他应用。

Nickel hydroxide, Ni(OH)2, is used for numerous applications including nickel-zinc and nickel-metal hydride batteries1,2,3,4, fuel cells4, water electrolyzers4,5,6,7,8,9, supercapacitors4, photocatalysts4, anion exchangers10, and many other analytical, electrochemical, and sensor applications4,5. Ni(OH)2 has two predominant crystal structures: &#946;-Ni(OH)2 and &#945;-Ni(OH)211. &#946;-Ni(OH)2 adopts a brucite-type Mg(OH)2 crystal structure, while &#945;-Ni(OH)2 is a turbostratically layered form of &#946;-Ni(OH)2 intercalated with residual anions and water molecules from the chemical synthesis4. Within &#945;-Ni(OH)2, the intercalated molecules are not within fixed crystallographic positions but have a degree of orientational freedom, and also function as an interlayer glue stabilizing the Ni(OH)2 layers4,12. The interlayer anions of &#945;-Ni(OH)2 affect the average Ni oxidation state13 and influence the electrochemical performance of &#945;-Ni(OH)2 (relative to &#946;-Ni(OH)2) toward battery2,13,14,15, capacitor16, and water-electrolysis applications17,18.
Ni(OH)2 can be synthesized by chemical precipitation, electrochemical precipitation, sol-gel synthesis, or hydrothermal/solvothermal synthesis4. Chemical precipitation and hydrothermal synthesis routes are widely utilized in the production of Ni(OH)2, and different synthetic conditions alter the morphology, crystal structure, and electrochemical performance. The chemical precipitation of Ni(OH)2 involves adding a highly basic solution to an aqueous nickel (II) salt solution. The phase and crystallinity of the precipitate are determined by the temperature and&#160;identities&#160;and concentrations of the nickel (II) salt and&#160;basic solution used4.
Hydrothermal synthesis of Ni(OH)2 involves heating an aqueous solution of precursor nickel (II) salt in a pressurized reaction vial, allowing the reaction to proceed at higher temperatures than ordinarily allowed under ambient pressure4. Hydrothermal reaction conditions typically favor &#946;-Ni(OH)2, but &#945;-Ni(OH)2 can be synthesized by (i) using an intercalation agent, (ii) using a non-aqueous solution (solvothermal synthesis), (iii) lowering the reaction temperature, or (iv) including urea in the reaction, resulting in ammonia-intercalated &#945;-Ni(OH)24. The hydrothermal synthesis of Ni(OH)2 from nickel salts occurs via a two-step process that involves a hydrolysis reaction (equation 1) followed by an olation condensation reaction (equation 2).19
[Ni(H2O)N]2+ + hH2O &#8596; [Ni(OH)h(H2O) N-h](2-h)++ hH3O+ (1)
Ni-OH + Ni-OH2 Ni-OH-Ni + H2O (2)
Microwave chemistry has been used for the one-pot synthesis of a wide variety of nanostructured materials and is based on the ability of a specific molecule or material to convert microwave energy into heat20. In conventional hydrothermal reactions, the reaction is initiated by the direct absorption of heat through the reactor. In contrast, within microwave-assisted hydrothermal reactions, the heating mechanisms are dipolar polarization of the solvent oscillating in a microwave field and ionic conduction generating localized molecular friction20. Microwave chemistry can increase the reaction kinetics, selectivity, and yield of chemical reactions20, making it of significant interest for a scalable, industrially viable method to synthesize Ni(OH)2.
For alkaline battery cathodes, the &#945;-Ni(OH)2 phase provides improved electrochemical capacity compared with the &#946;-Ni(OH)2 phase13, and synthetic methods to synthesize &#945;-Ni(OH)2 are of particular interest. &#945;-Ni(OH)2 has been synthesized by a variety of microwave-assisted methods, which include microwave-assisted reflux21,22, microwave-assisted hydrothermal techniques23,24, and microwave-assisted base-catalyzed precipitation25. The inclusion of urea within the reaction solution significantly influences the reaction yield26, mechanism26,27, morphology, and crystal structure27. The microwave-assisted decomposition of urea was determined to be a critical component for obtaining &#945;-Ni(OH)227. Water content in an ethylene glycol-water solution has been shown to impact the morphology of microwave-assisted synthesis of &#945;-Ni(OH)2 nanosheets24. The reaction yield of &#945;-Ni(OH)2, when synthesized by a microwave-assisted hydrothermal route using an aqueous nickel nitrate and urea solution, was found to depend on the solution pH26. A prior study of microwave synthesized &#945;-Ni(OH)2 nanoflowers using a precursor solution of EtOH/H2O, nickel nitrate, and urea found that temperature (in the range of 80-120 &#176;C) was not a critical factor, provided the reaction is conducted above the urea hydrolysis temperature (60 &#176;C)27. A recent paper that studied the microwave synthesis of Ni(OH)2 using a precursor solution of nickel acetate tetrahydrate, urea, and water found that at a temperature of 150 &#176;C, the material contained both &#945;-Ni(OH)2 and &#946;-Ni(OH)2 phases, which indicates that temperature can be a critical parameter in the synthesis of Ni(OH)228.
Microwave-assisted hydrothermal synthesis can be used to produce high-surface area &#945;-Ni(OH)2 and &#945;-Co(OH)2 by using a precursor solution composed of metal nitrates and urea dissolved in an ethylene glycol/H2O solution12,29,30,31. Metal-substituted &#945;-Ni(OH)2 cathode materials for alkaline Ni-Zn batteries were synthesized using a scaled-up synthesis designed for a large-format microwave reactor12. Microwave-synthesized &#945;-Ni(OH)2 was also used as a precursor for obtaining &#946;-Ni(OH)2 nanosheets12, nickel-iridium nanoframes for oxygen evolution reaction (OER) electrocatalysts29, and bifunctional oxygen electrocatalysts for fuel cells and water electrolyzers30. This microwave reaction route has also been modified to synthesize Co(OH)2 as a precursor for cobalt-iridium nanoframes for acidic OER electrocatalysts31 and bifunctional electrocatalysts30. Microwave-assisted synthesis was also used to produce Fe-substituted &#945;-Ni(OH)2 nanosheets, and the Fe substitution ratio alters the structure and magnetization32. However, a step-by-step procedure for microwave synthesis of &#945;-Ni(OH)2 and the evaluation of how varying reaction time and temperature within a water-ethylene glycol solution affects the crystalline structure, surface area, and porosity, and local environment of interlayer anions within the material&#160;has not been previously reported.
This protocol establishes procedures for high-throughput microwave synthesis of &#945;-Ni(OH)2 nanosheets using a rapid and scalable technique. The effect of reaction temperature and time were varied and evaluated using in situ reaction monitoring, scanning electron microscopy, energy dispersive X-ray spectroscopy, nitrogen porosimetry, powder X-ray diffraction (XRD), and Fourier transform infrared spectroscopy to understand the effects of synthetic variables on reaction yield, morphology, crystal structure, pore size, and local coordination environment of &#945;-Ni(OH)2 nanosheets.

作者聚焦：氢氧化镍纳米片的快速微波辅助水热合成 

微波合成条件对氢氧化镍纳米片结构的影响

反应温度和时间对α-Ni（OH）合成的影响2 反应前，前驱体溶液[Ni（NO3）2·6H2O，尿素，乙二醇和水]为透明绿色，pH值为4.41±0.10（图2A和表1）。微波反应的温度（120°C或180°C）会影响溶液的原位反应压力和颜色（图2B-G和图3）。对于120°C反?...

Watch this Scientific Journal Video about A Rapid, Microwave-Assisted Hydrothermal Synthesis Of Nickel Hydroxide Nanosheets at JoVE.com

氢氧化镍纳米片是通过微波辅助水热反应合成的。该协议表明，用于微波合成的反应温度和时间会影响反应产率、晶体结构和局部配位环境。

A protocol for rapid, microwave-assisted hydrothermal synthesis of nickel hydroxide nanosheets under mildly acidic conditions is presented, and the effect ...

我们开发了一种用于快速微波辅助水热合成氢氧化镍纳米片的方案。我们的工作研究了微波反应温度和时间如何影响结构和产物收率。纳米级材料的纳米结构或表达对材料的性能有显著影响。我们和其他人已经证明，当我们在纳米水平上工作时，氢氧化镍的结构对用于合成材料的反应条件非常敏感。我们的工作为α氢氧化镍的微波合成提供了一个分步程序。我们评估了反应温度和时间的变化如何影响内层阴离子的晶体结构、表面积孔隙率和局部环境，这在以前没有报道过。该反应方案快速且高度适应生产不同的金属氢氧化物和氧化物材料，包括氧化镍和氢氧化钴，并且还允许将铝或铁等金属取代基掺入结构中。氢氧化镍在储能、催化、传感器和其他应用方面有许多用途。我们的研究促进了对如何使用不同合成条件来控制结构的理解，这为开发改进的材料提供了途径。

effect-microwave-synthesis-conditions-on-structure-nickel-hydroxide

Research

JoVE Journal

Chemistry

Effect of Microwave Synthesis Conditions on the Structure of Nickel Hydroxide Nanosheets

1.0K 次观看.  Texas State University. 我们开发了一种用于快速微波辅助水热合成氢氧化镍纳米片的方案。我们的工作研究了微波反应温度和时间如何影响结构和产物收率。纳米级材料的纳米结构或表达对材料的性能有显著影响。我们和其他人已经证明，当我们在纳米水平上工作时，氢氧化镍的结构对用于合成材料的反应条件非常敏感。我们的工作为α氢氧化镍的微波合成提供了一个分步程序。我们评估了?...

视频: 作者聚焦：氢氧化镍纳米片的快速微波辅助水热合成 

A protocol for rapid, microwave-assisted hydrothermal synthesis of nickel hydroxide nanosheets under mildly acidic conditions is presented, and the effect of reaction temperature and time on the material&#39;s structure is examined. All reaction conditions studied result in aggregates of layered &#945;-Ni(OH)2 nanosheets. The reaction temperature and time strongly influence the structure of the material and product yield. Synthesizing &#945;-Ni(OH)2 at higher temperatures increases the reaction yield, lowers the interlayer spacing, increases crystalline domain size, shifts the frequencies of interlayer anion vibrational modes, and lowers the pore diameter. Longer reaction times increase reaction yields and result in similar crystalline domain sizes. Monitoring the reaction pressure in situ shows that higher pressures are obtained at higher reaction temperatures. This microwave-assisted synthesis route provides a rapid, high-throughput, scalable process that can be applied to the synthesis and production of a variety of transition metal hydroxides used for numerous energy storage, catalysis, sensor, and other applications.

Nickel hydroxide nanosheets are synthesized by a microwave-assisted hydrothermal reaction. This protocol demonstrates that the reaction temperature and time used for microwave synthesis affects the reaction yield, crystal structure, and local coordination environment.

科研

化学

Microwave-Assisted Synthesis of &#945;-Ni(OH)2 Nanosheets

Microwave-Assisted Synthesis of &amp;#945;-Ni(OH)2 Nanosheets  

Begin preparing the precursor solution by mixing 105 milliliters of ethylene glycol and 15 milliliters of ultrapure water. Then add 4.1 grams of uria and add 5.0 grams of nickel nitrate hexahydrate, and cover the solution. Sonicate the precursor solution for 30 minutes in a bath sonicator filled with ice and water at 40 kilohertz frequency and full power without pulse.Transfer 20 milliliters of the sonic precursor solution into a microwave reaction vial fitted with a PTFE stir bar. Seal the reaction vessel using a locking lid with a PTFE liner. Place the vial inside the microwave reactor and set the reactor program to as fast as possible, which applies maximum power until the desired temperature is achieved.Thereafter, apply variable power to maintain the reaction temperature for 13 to 30 minutes. Upon completion of the reaction, vent the reaction chamber with compressed air until the solution temperature reaches 55 degrees Celsius. Transfer the post reaction solution to 50 milliliter centrifuge tubes.Centrifuge the tubes at room temperature for four minutes, and decant the supernatant. Resuspend the resulting nickel hydroxide nano sheets in 25 milliliters of ultrapure water and centrifuge once more as demonstrated previously. After decanting the supernatant, cover the centrifuge tubes with a tissue or paper towel serving as a porous cover to minimize potential contamination.Finally, dry the nano sheets under an ambient atmosphere in a sample oven at 70 degrees Celsius for 21 hours. At 120 degrees Celsius, the maximum reaction pressure generated was nine to 11.5 pounds per square inch or PSI. Whereas at 180 degrees Celsius, it increased to 138 PSI.Increasing the reaction temperature from 120 to 180 degrees Celsius also changed the post-reaction supernatant color from green to blue. In C2 photographs of the reaction at 180 degrees Celsius showed a murky green color when the reaction terminated, but it changed to murky blue as the reaction cooled. After centrifugation, washing, and drying, all the reactions, irrespective of time and temperature, produced a green powder.The pH of the supernatant of the 180 degree Celsius reaction was much higher relative to the 120 degree Celsius reaction supernatants. The 180 degree Celsius reaction also recorded a much higher yield than the reactions at 120 degrees Celsius.

微波辅助合成α-Ni（OH）2 纳米片

Characterization and Analysis of &#945;-Ni(OH)2 Nanosheets

Characterization and Analysis of &amp;#945;-Ni(OH)2 Nanosheets  

To characterize the morphology and composition of the microwave synthesized nickel hydroxide nanosheets by SEM and EDS, prepare the sample by suspending a small amount of nickel hydroxide powder in one milliliter of ethanol using a water bath sonicator. Then drop cast the nickel hydroxide and ethanol mixture on an SEM stub and evaporate the ethanol by heating the stub in a sample oven at 70 degrees Celsius before collecting the SEM micrographs and EDS spectra. In order to determine the surface area and porosity of the nanosheets, add 25 milligrams of nickel hydroxide nanosheets into the sample tube.Carry out a pre-analysis degassing and drying procedure under vacuum at 120 degrees Celsius for 16 hours. Lastly, transfer the sample tube from the degassing port to the analysis port to collect nitrogen isotherms. For structural analysis using X-ray diffraction or XRD, fill the sample well of a zero-background powder XRD holder with nickel hydroxide.Collect powder X-ray diffractograms using a copper K-alpha radiation source between a 2-theta of 2 to 80 degrees with a 0.01 step increment. Equip the attenuated total reflectance or ATR attachment to the Fourier Transform Infrared or FTIR spectrometer. Press a small amount of nickel hydroxide powder between two glass slides to create a pellet.Then place the nickel hydroxide pellet on the silicon ATR crystal and obtain an FTIR spectrum between 404, 000 reciprocal centimeters as an average of 16 individual scans with a resolution of four reciprocal centimeters. SEM revealed that the microwave synthesized nickel hydroxide was composed of randomly interwoven ultra thin nanosheet aggregates. However, increasing the reaction temperature from 120 to 180 degrees Celsius increased the lateral sheet dimensions of individual nanosheets in the aggregates.Also, increasing the reaction time from 13 to 30 minutes at 120 degrees Celsius increased the nucleated aggregate sizes from about three to five microns. EDS showed a uniform distribution of nickel, oxygen, carbon, and nitrogen within all the synthesized nanosheets. The nanosheets had BET surface areas ranging from 61 to 85 square meters per gram, average pore diameter of 21 to 35 angstroms, and cumulative poor volumes of 0.4 to 0.6 cubic centimeters per gram.The XRD patterns of all three microwave synthesized samples showed characteristic peaks of alpha nickel hydroxide. However, reaction time and temperature affected the peaks as demonstrated by the shifting of the 001 plane. The ATR-FTIR spectra of the microwave synthesized nanosheets showed characteristic nickel oxide lattice mode.Modes from the ligands and structural molecules, cyanate bands and alpha hydroxide lattice modes. Increasing the reaction temperature from 120 to 180 degrees Celsius altered the frequencies and relative intensities of the cyanate, nitrate, hydroxyl, and water vibrational modes.