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2020 | OriginalPaper | Chapter

4. Perovskite Materials in Biomedical Applications

Authors : Jue Gong, Tao Xu

Published in: Revolution of Perovskite

Publisher: Springer Singapore

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Abstract

Due to exceptional light absorption and superior carrier transport properties, solution-processable hybrid perovskites have realized outstanding performance on solar cells and photodetectors in recent years. As hybrid perovskites contain high atomic number lead and halide elements, they are greatly suitable for X-ray detection and imaging purposes. Here, we present ongoing research in perovskite-based X-ray detectors and low-dose images, which are highly valuable for medical applications. In addition, magnetic oxide perovskite La_0.7Sr_0.3Mn_0.98Ti_0.02O₃ nanoparticles with magneto-temperature response, as well as double-perovskite L₂NiMnO₆ for adsorption of bovine serum albumin will be introduced. Moreover, in vitro cell proliferation studies reveal low cytotoxicity and promising biocompatibility of perovskite CaTiO₃ in cellular environments, thus justifying its benign functions in osseointegration and osteoblast adhesion. This chapter could advance the roles of perovskite materials in biomedical applications.

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Liu Z, Cai Y, Wang Y, Nie Y, Zhang C, Xu Y (2018) Cloning of macaque monkeys by somatic cell nuclear transfer. Cell 172:881–887

Rodriguez GA, Hu S, Weiss SM (2015) Porous silicon ring resonator for compact, high sensitivity biosensing applications. Opt Express 23:7111–7119

Gershlak JR, Hernandez S, Fontana G, Perreault LR, Hansen KJ, Larson SA (2017) Crossing kingdoms: using decellularized plants as perfusable tissue engineering scaffolds. Biomaterials 125:13–22

Munarin F, Guerreiro SG, Grellier MA, Tanzi MC, Barbosa MA, Petrini P, Granja PL (2011) Pectin-based injectable biomaterials for bone tissue engineering. Biomacromolecules 12:568–577

O’Brien FJ (2011) Biomaterials & scaffolds for tissue engineering. Mater Today 14:88–95

Amini AR, Laurencin CT, Nukavarapu SP (2012) Bone Tissue Engineering: Recent Advances and Challenges. Crit Rev Biomed Eng 40:363–408

Cohrs NH, Petrou A, Loepfe M, Yliruka M, Schumacher CM, Kohll AX (2017) A soft total artificial heart-first concept evaluation on a hybrid mock circulation. Artif Organs 41:948–958

Ott HC, Matthiesen TS, Goh SK, Black LD, Kren SM, Netoff TI et al (2008) Perfusion-decellularized matrix: using nature’s platform to engineer a bioartificial heart. Nat Med 14:213–221

Brown TE, Anseth KS (2017) Spatiotemporal hydrogel biomaterials for regenerative medicine. Chem Soc Rev 46:6532–6552

10.

Zhao Y, Feric NT, Thavandiran N, Nunes SS, Radisic M (2014) The role of tissue engineering and biomaterials in cardiac regenerative medicine. Can J Cardiol 30:1307–1322

11.

Martinez JO, Chiappini C, Ziemys A, Faust AM, Kojic M, Liu X, Ferrari M, Tasciotti E (2013) Engineering multi-stage nanovectors for controlled degradation and tunable release kinetics. Biomaterials 34:8469–8477

12.

Lalwani G, D’agati M, Gopalan A, Rao M, Schneller J, Sitharaman B (2017) Three-dimensional microporous graphene scaffolds for tissue engineering. J Biomed Mater Res A 105:73–83

13.

Tasciotti E, Cabrera FJ, Evangelopoulos M, Martinez JO, Thekkedath UR, Kloc M et al (2016) The emerging role of nanotechnology in cell and organ transplantation. Transplantation 100:1629–1638

14.

Martinez JO, Brown BS, Quattrocchi N, Evangelopoulos M, Ferrari M, Tasciotti E (2012) Multifunctional to multistage delivery systems: the evolution of nanoparticles for biomedical applications. Chin Sci Bull 57:3961–3971

15.

Tasciotti E, Liu X, Bhavane R, Plant K, Leonard AD, Price BK (2008) Mesoporous silicon particles as a multistage delivery system for imaging and therapeutic applications. Nat. Nanotech. 3:151–157

16.

Lee Kenry, Loh WC, Lim CT (2018) When stem cells meet graphene: opportunities and challenges in regenerative medicine. Biomaterials 155:236–250

17.

Shahbazi MA, Hamidi M, Makila EM, Zhang H, Almeida PV, Kaasalainen M (2013) The mechanisms of surface chemistry effects of mesoporous silicon nanoparticles on immunotoxicity and biocompatibility. Biomaterials 34:7776–7789

18.

Li C, Yang D, Ma P, Chen Y, Wu Y, Hou Z (2013) Multifunctional upconversion mesoporous silica nanostructures for dual modal imaging and in vivo drug delivery. Small 9:4150–4159

19.

Allen HS (1931) X-Rays and their Applications. Nature 127:356–358

20.

Dierolf M, Menzel A, Thibault P, Schneider P, Kewish CM, Wepf R (2010) Ptychographic X-ray computed tomography at the nanoscale. Nature 467:436–439

21.

Guillard F, Marks B, Einav I (2017) Dynamic X-ray radiography reveals particle size and shape orientation fields during granular flow. Sci Rep 7:8155

22.

Tamura M, Ito H, Matsui H (2017) Radiotherapy for cancer using X-ray fluorescence emitted from iodine. Sci Rep 7:43667

23.

Shrestha S, Fischer R, Matt GJ, Feldner P, Michel T, Osvet A, Levchuk I, Merle B, Golkar S, Chen H, Tedde SF, Schmidt O, Hock R, Ruhrig M, Goken M, Heiss W, Anton G, Brabec CJ (2017) High-performance direct conversion X-ray detectors based on sintered hybrid lead triiodide perovskite wafers. Nat Photon 11:436–440

24.

Wei H, Fang Y, Mulligan P, Chuirazzi W, Fang HH, Wang C (2016) Sensitive X-ray detectors made of methylammonium lead tribromide perovskite single crystals. Nat Photon 10:333–339

25.

Yakunin S, Sytnyk M, Kriegner D, Shrestha S, Richter M, Matt GJ, Azimi H, Brabec CJ, Stangl J, Kovalenko MV, Heiss W (2015) Detection of X-ray photons by solution-processed lead halide perovskites. Nat Photon 9:444–449

26.

Wei W, Zhang Y, Xu Q, Wei H, Fang Y, Wang Q (2017) Monolithic integration of hybrid perovskite single crystals with heterogeneous substrate for highly sensitive X-ray imaging. Nat Photon 11:315–321

27.

Chen Y, Yi HT, Wu X, Haroldson R, Gartstein YN, Rodionov YI, Tikhonov KS, Zakhidov A, Zhu XY, Podzorov V (2016) Extended carrier lifetimes and diffusion in hybrid perovskites revealed by Hall effect and photoconductivity measurements. Nat Commun 7:12253

28.

Stranks SD, Eperon GE, Grancini G, Menelaou C, Alcocer MJP, Leijtens T (2013) Electron–hole diffusion lengths exceeding 1 micrometer in an organometal trihalide perovskite absorber. Science 342:341–344

29.

Xing G, Mathews N, Sun S, Lim SS, Lam YM, Gratzel M (2013) Long-range balanced electron- and hole-transport lengths in organic–inorganic CH₃NH₃PbI₃. Science 342:344–347

30.

You J, Meng L, Song TB, Guo TF, Yang YM, Chang WH (2016) Improved air stability of perovskite solar cells via solution-processed metal oxide transport layers. Nat Nanotech 11:75–81

31.

Yang WS, Noh JH, Jeon NJ, Kim YC, Ryu S, Seo J, Seok SI (2015) High-performance photovoltaic perovskite layers fabricated through intramolecular exchange. Science 348:1234–1237

32.

Gong J, Guo P, Benjamin SE, Van Patten PG, Schaller RD, Xu T (2018) Cation engineering on lead iodide perovskites for stable and high-performance photovoltaic applications. J Energy Chem 27:1017–1039

33.

Huang D, Goh T, Kong J, Zheng Y, Zhao S, Xu Z, Taylor AD (2017) Perovskite solar cells with a DMSO-treated PEDOT:PSS hole transport layer exhibit higher photovoltaic performance and enhanced durability. Nanoscale 9:4236–4243

34.

Hu L, Sun K, Wang M, Chen W, Yang B, Fu J (2017) Inverted planar perovskite solar cells with a high fill factor and negligible hysteresis by the dual effect of NaCl-doped PEDOT:PSS. ACS Appl Mater Interfaces 9:43902–43909

35.

Yu JC, Hong JA, Jung ED, Kim DB, Baek SM, Lee S, Cho S, Park SS, Choi KJ, Song MH (2018) Highly efficient and stable inverted perovskite solar cell employing PEDOT:GO composite layer as a hole transport layer. Sci Rep 8:1070

36.

Jiang Q, Rebollar D, Gong J, Piacentino EL, Zheng C, Xu T (2015) Pseudohalide-induced moisture tolerance in perovskite CH₃NH₃Pb(SCN)₂I thin films. Angew Chem Int Edition 54:7617–7620

37.

Kazim S, Nazeeruddin MK, Gratzel M, Ahmad S (2014) Perovskite as light harvester: a game changer in photovoltaics. Angew Chem Int Ed 53:2812–2824

38.

Jin Z, Wang J (2014) Flexible high-performance ultraviolet photoconductor with zinc oxide nanorods and 8-hydroxyquinoline. J Mater Chem C 2:1966–1970

39.

Sze SM, Ng KK (2006) Physics of semiconductor devices, 2nd edn. Wiley, New York, pp 667–671

40.

Kim YC, Kim KH, Son DY, Jeong DN, Seo JY, Choi YS et al (2017) Printatble organometallic perovskite enables large-area, low-dose X-ray imaging. Nature 550:87–91

41.

Nof E, Lane C, Cazalas M, Cuchet-Soubelet E, Michaud GF, John RM (2015) Reducing radiation exposure in the electrophysiology laboratory: it is more than just fluoroscopy times! Pacing Clin Electrophysiol 38:136–145

42.

Davies AG, Cowen AR, Kengyelics SM, Moore J, Sivananthan MU (2007) Do flat detector cardiac X-ray systems convey advantages over image-intensifier-based systems? Study comparing X-ray dose and image quality. Eur Radiol 17:1787–1794

43.

Viggiano A, De Potter TJR, Celentano E, Stefan L, Peytchev P, Geelen P (2013) Exposure reduction by optimization of the imaging toolchain in pulmonary vein isolation. Eur Heart J 34:P2344

44.

Kasap S, Frey JB, Belev G, Tousignant O, Mani H, Greenspan J et al (2011) Amorphous and polycrystalline photoconductors for direct conversion flat panel X-ray image sensors. Sensors 11:5112–5157

45.

Zhao W, Rowlands JA (1995) X-ray imaging using amorphous selenium: feasibility of a flat panel self-scanned detector for digital radiology. Med Phys 22:1595–1604

46.

Kasap SO (2002) Rowlands JA (2002) Direct-conversion flat-panel X-ray image sensors for digital radiography. Proc IEEE 90:591–604

47.

Moy JP (2000) Recent developments in X-ray imaging detectors. Nucl Instrum Methods Phys Res 442:26–37

48.

Huang J, Shao Y, Dong Q (2015) Organometal trihalide perovskite single crystals: a next wave of materials for 25% efficiency photovoltaics and applications beyond? J Phys Chem Lett 6:3218–3227

49.

Nie W, Tsai H, Asadpour R, Blancon JC, Neukirch AJ, Gupta G (2015) High-efficiency solution-processed perovskite solar cells with millimeter-scale grains. Science 347:522–525

50.

Saidaminov MI, Abdelhady AL, Murali B, Alarousu E, Burlakov VM, Peng W (2015) High-quality bulk hybrid perovskite single crystals within minutes by inverse temperature crystallization. Nat Commun 6:7586

51.

Amat A, Mosconi E, Ronca E, Quarti C, Umari P, Nazeeruddin MK, Gratzel M, De Angelis F (2014) Cation-induced band-gap tuning in organohalide perovskites: interplay of spin–orbit coupling and octahedra tilting. Nano Lett 14:3608–3616

52.

Saidaminov MI, Abdelhady AL, Maculan G, Bakr OM (2015) Retrograde solubility of formamidinium and methylammonium lead halide perovskites enabling rapid single crystal growth. Chem Commun 51:17658–17661

53.

Han Q, Bae SH, Sun P, Hsieh YT, Yang Y, Rim YS (2016) Single crystal formamidinium lead iodide (FAPbI₃): insight into the structural, optical, and electrical properties. Adv Mater 28:2253–2258

54.

Weller MT, Weber OJ, Frost JM, Walsh A (2015) Cubic perovskite structure of black formamidinium lead iodide, α-[HC(NH₂)₂]PbI₃, at 298 K. J Phys Chem Lett 6:3209–3212

55.

Pang S, Zhou Y, Wang Z, Yang M, Krause AR, Zhou Z et al (2016) Transformative evolution of organolead triiodide perovskite thin films from strong room-temperature solid–gas interaction between HPbI₃–CH₃NH₂ precursor pair. J Am Chem Soc 138:750–753

56.

Mokhtar MZ, Chen M, Whittaker E, Hamilton B, Aristidou N, Ramadan S et al (2017) CH₃NH₃PbI₃ films prepared by combining 1- and 2-step deposition: how crystal growth conditions affect properties. Phys Chem Chem Phys 19:7204–7214

57.

Chen P, Zhang Y, Du J, Wang Y, Zhang X, Liu Y (2018) Global control of CH₃NH₃PbI₃ formation with multifunctional ionic liquid for perovskite hybrid photovoltaics. J Phys Chem C 122:10699–10705

58.

Zhang T, Long M, Yan K, Zeng X, Zhou F et al (2016) Facet-dependent property of sequentially deposited perovskite thin films: chemical origin and self-annihilation. ACS Appl Mater Interfaces 8:32366–32375

59.

Yaffe MJ, Rowlands JA (1997) X-ray detectors for digital radiography. Phys Med Biol 42:1

60.

Szeles C (2004) CdZnTe and CdTe materials for X-ray and gamma ray radiation detector applications. Phys Status Solidi B 241:783–790

61.

Kasap SO (2000) X-ray sensitivity of photoconductors: application to stabilized a-Se. J Phys D 33:2853

62.

Yoo YZ, Chmaissem O, Kolesnik S, Ullah A, Lurio LB, Brown DE (2006) Diverse effects of two-dimensional and step flow growth mode induced microstructures on the magnetic anisotropies of SrRuO₃ thin films. Appl Phys Lett 89:124104

63.

Sale AG, Kazan S, Gatiiatova JI, Valeev VF, Khaibullin RI, Mikailzade FA (2013) Magnetic properties of Fe implanted SrTiO₃ perovskite crystal. Mater Res Bull 48:2861–2864

64.

Shevchuk YA, Gagulin VV, Korchagina SK, Ivanova VV (2004) Dielectric and magnetic properties of SrTiO₃–BiMnO₃ solid solutions. Inorg Mater 40:292

65.

Chen H, Kolpak AM, Ismail-Beigi S (2010) Electronic and magnetic properties of SrTiO₃/LaAlO₃ interfaces from first principles. Adv Mater 22:2881–2899

66.

Zhai X, Mohapatra CS, Shah AB, Zuo JM, Eckstein JN (2013) Magnetic properties of the (LaMnO₃)_N/(SrTiO₃)_N atomic layer superlattices. J Appl Phys 113:173913

67.

Zhang H, Zhang J, Yang H, Lan Q, Hong D, Wang S et al (2016) Structural and Magnetic Properties of LaCoO₃/SrTiO₃ Multilayers. ACS Appl Mater Interfaces 8:18328–18333

68.

Mota DA, Barcelay YR, Senos AMR, Fernandes CM, Tavares PB, Gomes IT et al (2014) Unravelling the effect of SrTiO₃ antiferrodistortive phase transition on the magnetic properties of La_0.7Sr_0.3MnO₃ thin films. J Phys D Appl Phys 47:43

69.

Li B, Louca D, Niedziela J, Li Z, Zhang L, Zhou J, Goodenough JB (2016) Lattice and magnetic dynamics in perovskite Y_1−xLa_xTiO₃. Phys Rev B 94:224301

70.

Ponath P, O’Hara A, Cao HX, Posadas AB, Vasudevan R, Okatan MB (2016) Contradictory nature of Co doping in ferroelectric BaTiO₃. Phys Rev B 94:205121

71.

Li Z, Cho Y, Li X, Aimi A, Inaguma Y, Alonso JA et al (2018) New mechanism for ferroelectricity in the perovskite Ca_2−xMn_xTi₂O₆ synthesized by spark plasma sintering. J Am Chem Soc 140:2214–2220

72.

Xia H, Dai J, Xu Y, Yin Y, Wang X, Liu Z et al (2017) Magnetism and the spin state in cubic perovskite CaCoO₃ synthesized under high pressure. Phys Rev Materials 1, 024406 (2017)

73.

Tyson TA, Wu T, Ahn KH, Kim SB, Cheong SW (2010) Local spin-coupled distortions in multiferroic hexagonal HoMnO₃. Phys Rev B 81:054101

74.

Gao P, Chen Z, Tyson TA, Wu T, Ahn KH, Liu Z (2011) High-pressure structural stability of multiferroic hexagonal RMnO₃ (R = Y, Ho, Lu). Phys Rev B 83:224113

75.

Jin H, Rhim SH, Im J, Freeman AJ (2013) Topological Oxide Insulator in Cubic Perovskite Structure. Sci Rep 3:1651

76.

Soleymani M, Edrissi M (2016) Preparation of manganese-based perovskite nanoparticles using a reverse microemulsion method: biomedical applications. M Bull Mater Sci 39:487

77.

Zaraska L, Mika K, Hnida KE, Gajewska M, Lojewski T, Jaskula M, Sulka GD (2017) High aspect-ratio semiconducting ZnO nanowires formed by anodic oxidation of Zn foil and thermal treatment. Mater Sci Eng, B 226:94–98

78.

Ciocarlan RG, Seftel EM, Mertens M, Pui A, Mazaj M, Tusar NN, Cool P (2018) Novel magnetic nanocomposites containing quaternary ferrites systems Co_0.5Zn_0.25M_0.25Fe₂O₄ (M = Ni, Cu, Mn, Mg) and TiO₂-anatase phase as photocatalysts for wastewater remediation under solar light irradiation. Mater Sci Eng, B 230:1–7

79.

Patterson AL (1939) The Scherrer formula for X-ray particle size determination. Phys Rev 56:978–982

80.

Woo H, Tyson TA, Croft M, Cheong SW, Woicik JC (2001) Correlations between the magnetic and structural properties of Ca-doped BiMnO₃. Phys Rev B 63:134412

81.

Qian Q, Tyson TA, Kao CC, Croft M, Ignatov AY (2002) Local magnetic ordering in La_1−xCa_xMnO₃ determined by spin-polarized X-ray absorption spectroscopy. Appl Phys Lett 80:3141

82.

Wu Y, Ma Y, Xu G, Wei F, Ma Y, Song Q (2017) Metal-organic framework coated Fe₃O₄ magnetic nanoparticles with peroxidase-like activity for colorimetric sensing of cholesterol. Sens Actuators B Chem 249:195–202

83.

Zhao X, Liu S, Tang Z, Niu H, Cai Y, Meng W et al (2015) Synthesis of magnetic metal-organic framework (MOF) for efficient removal of organic dyes from water. Sci Rep 5:11849

84.

McBain SC, Yiu HHP, Dobson J (2008) Magnetic nanoparticles for gene and drug delivery. Int J Nanomedicine 3:169–180

85.

Ito A, Shinkai M, Honda H, Kobayashi T (2005) Medical application of functionalized magnetic nanoparticles. J Biosci Bioeng 100:1–11

86.

Peller M, Boll K, Zimpel A, Wuttke S (2018) Metal-organic framework nanoparticles for magnetic resonance imaging. Inorg Chem Front Advance Article

87.

Tang D, Yuan R, Chai Y (2006) Magnetic core–shell Fe₃O₄@Ag nanoparticles coated carbon paste interface for studies of carcinoembryonic antigen in clinical immunoassay. J Phys Chem B 110:11640–11646

88.

Bagheri A, Taghizadeh M, Behbahani M, Asgharinezhad AA, Salarian M, Dehghani A et al (2012) Synthesis and characterization of magnetic metal-organic framework (MOF) as a novel sorbent, and its optimization by experimental design methodology for determination of palladium in environmental samples. Talanta 99:132–139

89.

Chen Y, Xiong Z, Peng L, Gan Y, Zhao Y, Shen J, Qian J, Zhang L, Zhang W (2015) Facile preparation of core–shell magnetic metal-organic framework nanoparticles for the selective capture of phosphopeptides. ACS Appl Mater Interfaces 7:16338–16347

90.

Wu ZY, Ma CB, Tang XG, Li R, Liu QX, Chen BT (2013) Double-perovskite magnetic La₂NiMnO₆ nanoparticles for adsorption of bovine serum albumin applications. Nanoscale Res Lett 8:207

91.

Yang Y, Jia TW, Xu F, Li W, Tao S, Chu LQ et al (2018) Fluorescent neomannosyl bovine serum albumin as efficient probe for mannose receptor imaging and MCF-7 cancer cell targeting. ACS Appl Nano Mater 1:1058–1065

92.

Feng LJ, Zhang XH, Zhao DM, Wang SF (2011) Electrochemical studies of bovine serum albumin immobilization onto the poly-o-phenylenediamine and carbon-coated nickel composite film and its interaction with papaverine. Sens Actuators B Chem 152:88–93

93.

Coreno J, Coreno O (2005) Evaluation of calcium titanate as apatite growth promoter. J Biomed Mater Res 75A:478–484

94.

Song HJ, Kim MG, Moon WJ, Park YJ (2011) Formation of hydroxyapatite nanorods and anatase TiO₂ on CaTiO₃ powder using hydrothermal treatment. Mater Sci Eng, C 31:558–561

95.

Dubey AK, Basu B, Balani K, Guo R, Bhalla AS (2011) Multifunctionality of Perovskites BaTiO₃ and CaTiO₃ in a Composite with Hydroxyapatite as Orthopedic Implant Materials. Integr Ferroelectr 131:119–126

96.

Wei D, Zhou Y, Jia D, Wang Y (2008) Formation of CaTiO₃/TiO₂ composite coating on titanium alloy for biomedical applications. J Biomed Mater Res 84B:444–451

97.

Webster TJ, Ergun C, Doremus RH, Lanford WA (2003) Increased osteoblast adhesion on titanium-coated hydroxyapatite that forms CaTiO₃. J Biomed Mater Res 67A:975–980

98.

Dubey AK, Tripathi G, Basu B (2010) Characterization of hydroxyapatite-perovskite (CaTiO₃) composites: Phase evaluation and cellular response. J Biomed Mater Res 95B:320–329

99.

Krupa D, Baszkiewicz J, Kozubowski JA, Barcz A, Sobczak JW, Bilinski A, Lewandowska-Szumiel M, Rajchel B (2001) Effect of calcium-ion implantation on the corrosion resistance and biocompatibility of titanium. Biomaterials 22:2139–2151

100.

Biegalski MD, Qiao L, Gu Y, Mehta A, He Q, Takamura Y et al (2015) Impact of symmetry on the ferroelectric properties of CaTiO₃ thin films. Appl. Phys Lett 106:162904 (2015)

101.

Stanishevsky AV, Holliday S (2007) Mechanical properties of sol-gel calcium titanate bioceramic coatings on titanium. Surf Coat Technol 202:1236–1241

102.

Wang L, Li J, Feng M, Min L, Yang J, Yu S (2017) Perovskite-type calcium titanate nanoparticles as novel matrix for designing sensitive electrochemical biosensing. Biosens Bioelectron 96:220–226

103.

Hench LL (1998) Bioceramics. J Am Ceram Soc 81:1705–1728 (1998)

104.

Li B, Zhang Y, Fu L, Yu T, Zhou S, Zhang L, Yin L (2018) Surface passivation engineering strategy to fully-inorganic cubic CsPbI₃ perovskites for high-performance solar cells. Nat Commun 9:1076

105.

Niu G, Li W, Li J, Liang X, Wang L (2017) Enhancement of thermal stability for perovskite solar cells through cesium doping. RSC Adv 7:17473–17479

106.

Tsai H, Nie W, Blancon JC, Stoumpos CC, Asadpour R, Harutyunyan B et al (2016) High-efficiency two-dimensional Ruddlesden-Popper perovskite solar cells. Nature 536:312–316

107.

Chen AZ, Shiu M, Ma JH, Alpert MR, Zhang D, Foley BJ et al (2018) Origin of vertical orientation in two-dimensional metal halide perovskits and its effect on photovoltaic performance. Nat Commun 9:1336

Title: Perovskite Materials in Biomedical Applications
Authors: Jue Gong
Tao Xu
Publisher: Springer Singapore
Book: Revolution of Perovskite
Print ISBN: 978-981-15-1266-7

Electronic ISBN: 978-981-15-1267-4

Copyright Year: 2020
DOI: https://doi.org/10.1007/978-981-15-1267-4_4