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A ∼ D Afm Image Of Sb 1−x Bi X 2 Te 3 Grown On Mica Substrate

A ∼ D Afm Image Of Sb 1−x Bi X 2 Te 3 Grown On Mica Substrate

A ∼ D Afm Image Of Sb 1−x Bi X 2 Te 3 Grown On Mica Substrate

A ∼ D Afm Image Of Sb 1−x Bi X 2 Te 3 Grown On Mica Substrate
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Magnetotransport Study Of Sb1−xbix2te3 Thin Films On Mica Substrate

Magnetotransport Study Of Sb1−xbix2te3 Thin Films On Mica Substrate

Magnetotransport Study Of Sb1−xbix2te3 Thin Films On Mica Substrate
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Figure 2 From Role Of Defects In The Carrier Tunable Topological

Figure 2 From Role Of Defects In The Carrier Tunable Topological

Figure 2 From Role Of Defects In The Carrier Tunable Topological
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A Magnetoconductance Of Sb 1−x Bi X 2 Te 3 With X 0043 At Low

A Magnetoconductance Of Sb 1−x Bi X 2 Te 3 With X 0043 At Low

A Magnetoconductance Of Sb 1−x Bi X 2 Te 3 With X 0043 At Low
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Tem Bright Field Images Of Bi X Sb 1 X 2 Te 3 Nanoparticles

Tem Bright Field Images Of Bi X Sb 1 X 2 Te 3 Nanoparticles

Tem Bright Field Images Of Bi X Sb 1 X 2 Te 3 Nanoparticles
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Band Dispersions Of Sb 1−x Bi X 2 Te 3 X 0 029 And 043 A

Band Dispersions Of Sb 1−x Bi X 2 Te 3 X 0 029 And 043 A

Band Dispersions Of Sb 1−x Bi X 2 Te 3 X 0 029 And 043 A
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Figure 1 From Selective Area Epitaxy Of Bulk Insulating Bixsb 1 X

Figure 1 From Selective Area Epitaxy Of Bulk Insulating Bixsb 1 X

Figure 1 From Selective Area Epitaxy Of Bulk Insulating Bixsb 1 X
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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Figure 3 From Selective Area Epitaxy Of Bulk Insulating Bixsb 1 X

Figure 3 From Selective Area Epitaxy Of Bulk Insulating Bixsb 1 X

Figure 3 From Selective Area Epitaxy Of Bulk Insulating Bixsb 1 X
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Figure 3 From Two Superconducting Phases And Their Characteristics In

Figure 3 From Two Superconducting Phases And Their Characteristics In

Figure 3 From Two Superconducting Phases And Their Characteristics In
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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A The Transient Absorption Profile Of The Nh 4 3 Sb 1−x Bi X 2 I

A The Transient Absorption Profile Of The Nh 4 3 Sb 1−x Bi X 2 I

A The Transient Absorption Profile Of The Nh 4 3 Sb 1−x Bi X 2 I
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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Pdf Two Superconducting Phases And Their Characteristics In Layered

Pdf Two Superconducting Phases And Their Characteristics In Layered

Pdf Two Superconducting Phases And Their Characteristics In Layered
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Synthesis Of Bi 1−x Sb X 2 S 3 Solid Solutions Via Thermal

Synthesis Of Bi 1−x Sb X 2 S 3 Solid Solutions Via Thermal

Synthesis Of Bi 1−x Sb X 2 S 3 Solid Solutions Via Thermal
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using
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Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using
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A Xrd Phi Scan Of A 100 Ql Thick Bisb 2 Te 3 Film On Inp 111a

A Xrd Phi Scan Of A 100 Ql Thick Bisb 2 Te 3 Film On Inp 111a

A Xrd Phi Scan Of A 100 Ql Thick Bisb 2 Te 3 Film On Inp 111a
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Scanning Electron Microscopy Sem Images Of A D Ti 2 Fenisb 1 X Bi

Scanning Electron Microscopy Sem Images Of A D Ti 2 Fenisb 1 X Bi

Scanning Electron Microscopy Sem Images Of A D Ti 2 Fenisb 1 X Bi
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Scanning Electron Microscopy Sem Images Of A D Ti 2 Fenisb 1 X Bi

Scanning Electron Microscopy Sem Images Of A D Ti 2 Fenisb 1 X Bi

Scanning Electron Microscopy Sem Images Of A D Ti 2 Fenisb 1 X Bi
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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Xrd Patterns Of A Ti 2 Fenisb 1 X Bi X 2 X 0025 01 And B

Xrd Patterns Of A Ti 2 Fenisb 1 X Bi X 2 X 0025 01 And B

Xrd Patterns Of A Ti 2 Fenisb 1 X Bi X 2 X 0025 01 And B
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Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using
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Schematic Illustration Of 2d Mg 3 Sb 2−x Bi X In A 5 × 5 × 1

Schematic Illustration Of 2d Mg 3 Sb 2−x Bi X In A 5 × 5 × 1

Schematic Illustration Of 2d Mg 3 Sb 2−x Bi X In A 5 × 5 × 1
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using

Synthesis Of Bi 2 Te 3 And Bi X Sb 1−x 2 Te 3 Nanoparticles Using
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A1 ∼ A3 Schematic Illustrations On Tuning The Fermi Level And

A1 ∼ A3 Schematic Illustrations On Tuning The Fermi Level And

A1 ∼ A3 Schematic Illustrations On Tuning The Fermi Level And
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Atomic Local Ordering And Alloying Effects On The Mg3sb1xbix2

Atomic Local Ordering And Alloying Effects On The Mg3sb1xbix2

Atomic Local Ordering And Alloying Effects On The Mg3sb1xbix2
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Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically

Band Gap Tuning Through Cation And Halide Alloying In Mechanochemically
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Color Online A Lattice Constants As A Function Of Bi Content X For

Color Online A Lattice Constants As A Function Of Bi Content X For

Color Online A Lattice Constants As A Function Of Bi Content X For
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Direct Deposition Of Bixsb1x2te3 Nanosheets On Sisio2 Substrates By

Direct Deposition Of Bixsb1x2te3 Nanosheets On Sisio2 Substrates By

Direct Deposition Of Bixsb1x2te3 Nanosheets On Sisio2 Substrates By
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Fig S1 Characterization Of The Bisb 2 Te 3 Heterostructure A

Fig S1 Characterization Of The Bisb 2 Te 3 Heterostructure A

Fig S1 Characterization Of The Bisb 2 Te 3 Heterostructure A
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Compositionally Tunable Ternary Bi 2 Se 1−x Te X 3 And Bi 1−y Sb Y

Compositionally Tunable Ternary Bi 2 Se 1−x Te X 3 And Bi 1−y Sb Y

Compositionally Tunable Ternary Bi 2 Se 1−x Te X 3 And Bi 1−y Sb Y
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