Twelve-tone technique
The twelve-tone technique, also known as dodecaphony or the twelve-note method, is a system of musical composition developed by Austrian composer Arnold Schoenberg in the early 1920s, in which the twelve pitches of the chromatic scale are organized into a specific sequence called a tone row (or series), and all musical material in a work is derived from this row or its transformations—inversion, retrograde, and retrograde inversion—to ensure the equal treatment of all pitches and the avoidance of tonal hierarchy.[1][2] This method emerged as a response to the challenges of atonality, providing structural coherence without relying on traditional major-minor tonality, as Schoenberg described it as "composition with twelve tones related only with one another."[1] Schoenberg's development of the technique followed a period of free atonality in his works from around 1908 to 1921, during which he sought a new organizing principle to replace the functional harmony of the common-practice era, motivated by the need for logical unity in increasingly complex atonal music.[3] The first fully twelve-tone compositions appeared in 1921–1923, including the Five Piano Pieces, Op. 23, the Serenade, Op. 24, and the Suite for Piano, Op. 25 (1923), marking the technique's public debut; Schoenberg announced the method to his students around 1923 to distinguish his approach from similar ideas by Josef Matthias Hauer.[3] Influenced by his earlier expressionist and atonal experiments, such as Pierrot lunaire (1912), the technique represented Schoenberg's evolution toward a more systematic form of composition, balancing freedom with rigorous order.[4] At its core, the technique requires that no pitch in the tone row repeats until all twelve have been stated, with the row serving as the source for melodies, harmonies, and textures through its four basic forms, each of which can be transposed in 12 ways (one for each starting pitch), yielding 48 possible row forms.[2] Exceptions allow for immediate repetitions in certain contexts like trills, but the principle of permutation maintains the row's integrity, often visualized in a twelve-tone matrix to track interval relationships.[5] This combinatorial approach emphasizes intervallic structure over pitch content, fostering a sense of unity and inevitability in the music.[2] The technique quickly gained traction among Schoenberg's pupils, notably Alban Berg and Anton Webern, who adapted it in works like Berg's Lyric Suite (1926, partially twelve-tone) and Webern's Symphony, Op. 21 (1928), though Berg used it more flexibly while Webern embraced its strictness.[6][1] Post-World War II, it profoundly influenced the avant-garde, inspiring integral serialism by composers such as Pierre Boulez and Karlheinz Stockhausen, who extended serialization to rhythm, dynamics, and timbre, thus shaping modern music's departure from tonality.[1]Origins and Historical Development
Invention and Early Concepts
Arnold Schoenberg, having pioneered free atonality in works from around 1908 to the early 1920s, grew dissatisfied with its improvisatory nature and lack of systematic unity, prompting him to seek a compositional method that would ensure the equal treatment of all twelve chromatic pitches without favoring any tonal center.[7] This motivation stemmed from his desire to extend the emancipation of dissonance while restoring structural coherence akin to traditional tonality, but grounded in pitch-class equality rather than key-based hierarchy.[8] Early explorations of these ideas appear in Schoenberg's private sketches dating from 1915 to 1917, including a twelve-tone theme in the Scherzo of his unfinished symphony from that period, marking initial steps toward serial organization.[8] These sketches reflect tentative efforts to array pitches in sequences that avoided repetition and tonal bias, though they remained unpublished and undeveloped at the time.[3] The technique's core development occurred between 1920 and 1923, during which Schoenberg was influenced by Josef Matthias Hauer's concurrent work on twelve-tone composition, particularly Hauer's Von der Melodie (1919) and his tropoi—unordered sets of six pitches forming the basis of atonal structures—but Schoenberg differentiated his approach by emphasizing strictly ordered rows to govern melodic and harmonic content.[9] This period culminated in the formalization of the method in Schoenberg's Five Piano Pieces, Op. 23 (1923), where the third piece, "Walzer," employs a single twelve-tone row as its foundational unit to serialize pitch classes and eliminate tonal implications.[8] The core principle of this serialization ensures that all twelve pitches relate solely to one another within the row, preventing any subset from suggesting traditional harmony or key.[7]Evolution in Schoenberg's Works
Schoenberg's compositional approach evolved from the free atonality of his earlier works, such as Pierrot Lunaire (1912), which eschewed traditional tonal centers without a systematic organizing principle, toward a more structured serialism by the early 1920s. This transition culminated in the Suite for Piano, Op. 25 (1921–1923), recognized as his first fully twelve-tone composition, where he introduced systematic row transpositions and emphasized the equality of all twelve pitches while integrating neoclassical forms like prelude, minuet, and gigue. In this suite, Schoenberg balanced the method's rigor with expressive elements, such as rhythmic and registral variations that projected row forms, marking a shift from the improvisatory atonality of pieces like the Five Pieces for Orchestra, Op. 16 (1909) to a disciplined framework that ensured motivic coherence across movements.[8][10] Key milestones in this evolution include the Wind Quintet, Op. 26 (1924), Schoenberg's first multi-instrumental twelve-tone work for chamber ensemble, which fully realized the method by employing the row and its inversion to generate thematic material and contrapuntal textures. Composed for flute, oboe, clarinet, bassoon, and horn, it revived classical forms such as sonata and rondo, demonstrating the technique's adaptability to larger-scale structures and instrumental interplay, while avoiding orchestral forces. Later, in the opera Moses und Aron (begun 1930), Schoenberg applied varied row partitions and hexachordal combinations to dramatize thematic conflicts, such as the tension between divine idea and human representation, further refining the method's capacity for narrative depth. These works illustrate Schoenberg's progressive integration of serial procedures into diverse genres, from solo piano to vocal-orchestral forms.[8][11][12] Throughout this period, Schoenberg grappled with balancing the method's strict serial organization against musical expressivity, occasionally incorporating tonal allusions—such as triadic formations or cadential gestures—to evoke emotional resonance without undermining the row's primacy. He articulated this tension in reflections emphasizing that "everything of supreme value in art must show heart as well as brain," underscoring the need for subconscious inspiration to guide technical control. His appointment as professor of composition at the Prussian Academy of Arts (1925–1933) played a pivotal role in formalizing the technique, as he taught advanced composition to students like Winfried Zillig and Hanns Eisler, refining its principles through pedagogical exposition and application in classroom analyses. This institutional context helped solidify the method as a teachable system, influencing its dissemination before his dismissal in 1933 amid political upheaval.[8]Adoption by Other Composers
Alban Berg, one of Schoenberg's closest pupils, was among the first to adapt the twelve-tone technique in a more lyrical and expressive manner, as seen in his Lyric Suite for string quartet (1926), where serial procedures coexist with tonal allusions and emotional depth to evoke personal narrative.[13] In this work, Berg selectively applied twelve-tone rows to certain movements while allowing freer, tonally inflected passages elsewhere, creating a hybrid that bridged atonal innovation with Romantic sensibility.[14] Berg extended this approach in his Violin Concerto (1936), his final completed composition, which integrates a twelve-tone row derived from folk tunes and Bach chorales with overt tonal structures, resulting in a memorial work that balances serial rigor and melodic warmth.[15] Anton Webern, another key figure in Schoenberg's circle, embraced the twelve-tone method with an emphasis on structural economy and timbral innovation, particularly in his Symphony, Op. 21 (1928), the first fully serial orchestral piece by any of Schoenberg's students.[16] Here, Webern employed a palindromic tone row to achieve maximal symmetry and concision, using brief motifs and Klangfarbenmelodie—melody defined by shifting timbres rather than pitch alone—to distribute notes across instruments in sparse, pointillistic textures that heightened the work's austerity and precision.[17] Hanns Eisler incorporated the technique into politically charged compositions during the 1930s, adapting it to convey socialist ideals amid rising fascism.[18] In pieces like the Deutsche Sinfonie (begun 1935), Eisler combined serial rows with agitprop elements, such as Brechtian texts and march-like rhythms, to critique capitalism and war while maintaining accessibility for mass audiences.[19] This fusion reflected Eisler's belief that twelve-tone could serve revolutionary purposes without sacrificing ideological clarity. The Nazi regime's classification of twelve-tone music as "degenerate art" led to severe suppression from 1933 onward, with performances banned, scores confiscated, and composers like Schoenberg, Berg, Webern, and Eisler forced into exile or silence, compelling the technique's dissemination through clandestine networks and émigré communities in the United States and elsewhere.[20] After World War II, René Leibowitz emerged as a leading advocate in France, promoting the method through his 1947 treatise Introduction à la musique de douze sons and conducting premieres of Second Viennese School works, which helped establish serialism as a cornerstone of postwar European composition.[21] Leibowitz's efforts, including teaching figures like Boulez, countered lingering resistance and fostered a rigorous theoretical framework for the technique's broader adoption.[22]Fundamentals of the Tone Row
Definition and Basic Construction
The twelve-tone technique is a method of musical composition in which the twelve pitch classes of the chromatic scale are arranged into a specific ordered sequence known as a tone row, serving as the foundational source for all pitches in the work. This approach, developed by Arnold Schoenberg in the early 1920s, ensures that each pitch class appears exactly once in the row before any repetition occurs, thereby generating the entire pitch content systematically.[23][24] The construction of a tone row involves the composer selecting an arbitrary ordering of the twelve distinct pitch classes, typically designed to eschew immediate patterns reminiscent of traditional tonality, such as triads or scalar progressions, in order to preserve an atonal framework. No pitch class is repeated until all others have been stated, though exceptions like immediate repetitions for emphasis or in ornamental figures such as trills are permitted. Pitch classes are commonly notated using integers from 0 to 11 in modulo 12 arithmetic, with 0 representing C, 1 for C♯/D♭, and so forth; a representative prime row starting on 0, for instance, might be expressed as 0, 1, 4, 6, 8, 10, 7, 9, 5, 11, 3, 2.[2][23][25] By mandating the equal utilization of all pitch classes without privileging any as a tonic, the tone row promotes the equality of tones and facilitates the emancipation of dissonance, wherein dissonance is no longer subordinated to consonance but integrated as a structural equal within the composition. This contrasts with tonal music's hierarchical organization and aligns with broader atonal principles by emphasizing intervallic relationships over chordal or scalar functions.[24][26] Notationally, a tone row is an ordered sequence, distinct from an unordered pitch-class set, which collects pitch classes without regard to sequence, and from scales, which cyclically repeat and imply a tonal center for resolution. This ordered structure underscores the row's role in providing motivic and structural unity across the piece.[2][25]Standard Example of a Tone Row
A canonical illustration of a tone row appears in Arnold Schoenberg's Suite for Piano, Op. 25 (1921–1923), one of the composer's earliest fully twelve-tone works. The prime form of the row, designated P₄ in standard integer notation (with C as 0), consists of the pitch classes 4, 5, 7, 1, 6, 3, 8, 2, 11, 0, 9, 10, corresponding to the pitches E–F–G–D♭–G♭–E♭–A♭–D–B–C–A–B♭.[27] This sequence encompasses all twelve chromatic pitches without repetition, structured as three tetrachords: [E–F–G–D♭], [G♭–E♭–A♭–D], and [B–C–A–B♭].[28] In integer form for analytical purposes: $4, 5, 7, 1, 6, 3, 8, 2, 11, 0, 9, 10 In the Präludium (first movement), the row is stated linearly in the right hand within a three-voice polyphonic texture, with the opening measures 1–3 unfolding the row across the upper voice in three tetrachords: the first (E–F–G–D♭) in measures 1–2, the second (G♭–E♭–A♭–D) continuing in measures 2–3, and the third (B–C–A–B♭) completing in measure 3. This full prime row extends through measures 1–19, interwoven with complementary voices to form complete chromatic aggregates, demonstrating the row's role as a unifying melodic motif.[28][10] To highlight the row's intervallic structure, the directed semitone intervals between adjacent pitches (positive for ascending, negative for descending) provide insight into its rhythmic and motivic potential:| Transition | From Pitch Class | To Pitch Class | Interval (semitones) |
|---|---|---|---|
| 1–2 | 4 (E) | 5 (F) | +1 |
| 2–3 | 5 (F) | 7 (G) | +2 |
| 3–4 | 7 (G) | 1 (D♭) | -6 |
| 4–5 | 1 (D♭) | 6 (G♭) | +5 |
| 5–6 | 6 (G♭) | 3 (E♭) | -3 |
| 6–7 | 3 (E♭) | 8 (A♭) | +5 |
| 7–8 | 8 (A♭) | 2 (D) | -6 |
| 8–9 | 2 (D) | 11 (B) | +9 |
| 9–10 | 11 (B) | 0 (C) | -11 |
| 10–11 | 0 (C) | 9 (A) | +9 |
| 11–12 | 9 (A) | 10 (B♭) | +1 |
Row Forms and Their Notation
In twelve-tone technique, a single tone row serves as the basis for generating a complete family of related forms through specific operations, ensuring comprehensive utilization of the chromatic pitch classes. These operations produce four primary row forms: the prime form (P), which is the original sequence of twelve pitch classes; the inversion (I), created by inverting the intervals of the prime form around its initial pitch class (such that ascending intervals become descending and vice versa, preserving interval sizes); the retrograde (R), obtained by reversing the order of the prime form; and the retrograde-inversion (RI), which applies inversion to the retrograde or, equivalently, retrograde to the inversion. Each of these four forms can be transposed to any of the twelve possible starting pitch classes within the chromatic scale, yielding a total of 48 distinct row forms for a given tone row (12 transpositions multiplied by 4 operations). Transpositions are typically indexed by a subscript numeral from 0 to 11, corresponding to semitone displacement from a reference pitch (often C=0); for instance, P_5 denotes the prime form transposed upward by five semitones, so that if the original P_0 begins on pitch class 0, P_5 begins on pitch class 5. This indexing applies analogously to the other forms, such as I_5 or R_3. However, if the tone row exhibits inherent symmetries—such as invariance under certain transpositions, inversions, or retrogrades—the number of unique forms may be reduced, as some operations yield equivalents of existing forms.[29][30] Standard notation for these forms, including the subscript indexing (e.g., I_n for the nth transposition of the inversion and RI_n for the retrograde-inversion), was systematized by composer-theorists like Milton Babbitt in his analyses of serial structures. Babbitt's approach emphasizes the relational properties among forms, using this notation to track invariant intervals and pitch-class sets across operations. Complementing this, George Perle developed the twelve-tone matrix (or row array), a tabular grid that visually organizes all 48 forms for analytical purposes: the left column lists the 12 transpositions of the prime form (P_0 to P_11), the top row lists the 12 transpositions of the inversion (I_0 to I_11), and each cell at the intersection of P_m and I_n contains the pitch sequence of the row form starting with the pitch class at that position, facilitating quick derivation of retrogrades and retrograde-inversions by reading rows backward or columns downward. This matrix, introduced in Perle's foundational text on serialism, enables composers and analysts to navigate the full array of forms efficiently without recalculating each one manually.[31][29]Serial Transformations and Operations
Prime Form and Its Properties
The prime form, denoted as P or P_n where n indicates the starting pitch class (0 to 11), represents the original, untransformed sequence of all twelve pitch classes arranged in a specific order, serving as the foundational generator for the entire serial structure in twelve-tone composition. This form establishes the basic linear ordering that ensures each pitch class appears exactly once, avoiding tonal hierarchy while providing a fixed succession for melodic and harmonic derivation.[2] The interval content of the prime form consists of the eleven directed intervals between consecutive pitch classes, calculated as the difference modulo 12 (ranging from 1 to 11), which defines the row's rhythmic and melodic profile. These intervals determine the row's character, such as its motivic gestures or potential for combinatorial properties when segmented. A special case is the all-interval series, where the eleven adjacent directed intervals comprise each value from 1 to 11 exactly once, maximizing intervallic variety and often resulting in a tritone (interval 6) between the first and last pitch classes due to the sum of 1 through 11 equaling 66, or 6 modulo 12.[32][33] Such rows, first systematically analyzed in the 1970s, appear in works like Alban Berg's Lyric Suite (1926), enhancing structural density.[32] Analytical examination of the prime form often involves segmentation into tetrachords (groups of four consecutive notes) or hexachords (groups of six), revealing invariant subsets or recurring interval patterns that contribute to coherence. For instance, tetrachordal division can highlight balanced interval distributions within segments, while hexachordal analysis uncovers potential for row overlap in multi-voice textures. The prime form fosters thematic unity by supplying the core intervallic and pitch successions that permeate the composition, allowing derived segments to echo its essential motives across sections. To illustrate interval content, consider the prime form P_3: [3, 5, 0, 7, 9, 1, 4, 6, 10, 8, 11, 2] (pitch classes modulo 12). The adjacent directed intervals are calculated as follows:| Position | From | To | Directed Interval (mod 12) |
|---|---|---|---|
| 1-2 | 3 | 5 | 2 |
| 2-3 | 5 | 0 | 7 |
| 3-4 | 0 | 7 | 7 |
| 4-5 | 7 | 9 | 2 |
| 5-6 | 9 | 1 | 4 |
| 6-7 | 1 | 4 | 3 |
| 7-8 | 4 | 6 | 2 |
| 8-9 | 6 | 10 | 4 |
| 9-10 | 10 | 8 | 10 |
| 10-11 | 8 | 11 | 3 |
| 11-12 | 11 | 2 | 3 |
Inversion and Retrograde Operations
In the twelve-tone technique, inversion transforms the prime row by reflecting its intervals around an axis defined by the starting pitch, effectively reversing the direction of each successive interval while preserving their magnitudes modulo 12. This operation, one of the four basic row forms derived from the prime, ensures that the inverted row contains the same twelve pitch classes in a reordered sequence that mirrors the original's intervallic structure in the opposite direction. As Arnold Schoenberg described, the inversion is automatically derived from the basic set as a "mirror form" where ascending intervals become descending and vice versa.[7] The mathematical formulation for the inversion I_n of a prime row P_n = (p_1, p_2, \dots, p_{12}), where n is the starting pitch class (0 to 11), is given by I_n(i) = (2n - p_i) \mod 12 for i = 1 to $12. This formula inverts each position p_i relative to the axis at n, maintaining the row's integrity within the chromatic scale. A key property of inversion is the preservation of interval succession in magnitude but not direction; for instance, a +3 semitone interval becomes -3 (or +9 modulo 12), allowing the form to be transposed equivalently to the prime while altering melodic contours. This equivalence under transposition underscores inversion's role in generating variety without introducing tonal hierarchy. Retrograde, the second basic transformation, simply reverses the order of the prime row's pitches, starting from the original ending note and proceeding backward to the starting note. Denoted as R_n, where n designates the ending pitch class for consistency in notation (unlike the prime and inversion, which use the starting pitch), it is computed as R_n(i) = P_n(13 - i). Schoenberg identified the retrograde as the basic set played in reverse, providing a straightforward way to derive motivic material that echoes but inverts the temporal flow of the original. Unlike inversion, retrograde reverses the sequence entirely, disrupting interval succession while retaining the pitch classes; it too maintains equivalence under transposition, enabling seamless integration across row forms.[7] These operations are exemplified in Schoenberg's Suite for Piano, Op. 25 (1921–23), his first fully twelve-tone work, which employs a prime row beginning on E (pitch class 4): E–F–G–D♭–G♭–E♭–A♭–D–B–C–A–B♭, or in integers [4, 5, 7, 1, 6, 3, 8, 2, 11, 0, 9, 10]. The corresponding inversion I_4 yields [4, 3, 1, 7, 2, 5, 0, 6, 9, 8, 11, 10], or E–E♭–D♭–G–D–F–C–F♯–A–A♭–B–B♭, transforming upward leaps (e.g., the initial +1 and +2 semitones) into downward motions (-1 and -2) and altering the melodic contour from ascending to predominantly descending in the opening gestures. The retrograde R_4, ending on 4, is the reverse: [10, 9, 0, 11, 2, 8, 3, 6, 1, 7, 5, 4], or B♭–A–C–B–D–A♭–E♭–G♭–D♭–G–F–E, which in the suite's Prelude (mm. 20–21) pairs with the prime to create palindromic dyads, emphasizing symmetry in texture. These transformations highlight how inversion and retrograde facilitate contour variation and structural balance without repeating pitches prematurely.[10]Retrograde-Inversion and Composite Forms
The retrograde-inversion (RI) represents a composite transformation in the twelve-tone technique, achieved by applying inversion to the prime row form followed by retrograde, or alternatively, by retrograding the prime and then inverting it. This operation preserves the intervallic content of the original row while reversing both the directional and sequential aspects, resulting in a form that mirrors the prime in a dual manner. In integer notation, where pitches are assigned numbers from 0 to 11, the pitch at position i (with i ranging from 1 to 12) in the retrograde-inversion transposed by n is given by \mathrm{RI}_n(i) = \mathrm{I}_n(13 - i), ensuring modular arithmetic aligns the structure modulo 12.[5] This duality inherent in the retrograde-inversion—wherein RI is equivalently the inversion of the retrograde or the retrograde of the inversion—underpins the symmetrical architecture of the serial system, fostering balance between forward and backward motions as well as upward and downward interval trajectories. Such symmetry extends to the broader composite framework, where the four basic row forms (prime, retrograde, inversion, and retrograde-inversion), each subjected to 12 transpositions, generate a total of 48 distinct forms. These 48 forms constitute a closed group under the serial operations of transposition, inversion, and retrograde, forming a set of up to 48 distinct forms (the four basic forms each transposed to 12 pitch levels), which constitute a closed system under the serial operations of transposition, inversion, and retrograde, generating a group of order 48 for rows without symmetries.[34] In analytical terms, the composite properties of these forms enable sophisticated row overlaps in polyphonic contexts, where segments from different transformations (such as a prime in one voice overlapping with a retrograde-inversion in another) can interweave without pitch-class repetition, thereby supporting contrapuntal density while adhering to the non-replicative principle of twelve-tone organization. This capability is particularly evident in array-based progressions, where retrograde-inversions facilitate invariant interval cycles across voices, enhancing textural cohesion without compromising serial integrity.[35]Advanced Derivational Techniques
Combinatoriality in Hexachords
Combinatoriality in hexachords refers to a property of twelve-tone rows where specific transpositions of the prime form (P) and its inversion (I), or the retrograde (R) and retrograde-inversion (RI), share identical hexachordal content, allowing their simultaneous presentation to form aggregates that collectively span the entire chromatic scale without repetition.[31] This technique, which facilitates polyphonic textures by ensuring complementary pitch-class sets in the first and second hexachords (the initial and final six pitches of the row), was formalized by Milton Babbitt as a means to extend serial control beyond linear statements to vertical and contrapuntal combinations.[31] Rows exhibiting combinatoriality are classified by the transformations under which the hexachords align: semi-combinatorial rows satisfy the property for one pair of forms (such as P-I or R-RI), while all-combinatorial rows (AC) satisfy it for all four pairs (P-I, R-RI, P-RI, and R-I).[31] Only six distinct all-combinatorial row classes exist, each derived from one of the six all-combinatorial hexachords, which possess the necessary invariance under transposition, inversion, and retrograde to enable these alignments. Cyclic permutations of the hexachords within such rows can further enhance rotational symmetries, allowing flexible segmentation for contrapuntal deployment.[31] The condition for combinatoriality between the prime and a transposed inversion, such as P and I₅, requires set equality between the first hexachord of P and the transposed second hexachord of I:\{p_1, p_2, \dots, p_6\} = \{i_1 + 5, i_2 + 5, \dots, i_6 + 5\} \pmod{12}
where p_i and i_j denote pitch classes modulo 12.[31] Similar equalities hold for the second hexachords under the complementary transposition, ensuring the combined forms produce two full aggregates. This hexachordal matching extends to other pairs, with the transposition interval (e.g., 5 for P-I in certain classes) determined by the row's interval structure. A prominent example is the all-combinatorial row from Anton Webern's Symphonie, Op. 21 (1928), given as P₀: A, F♯, G, A♭, E, F, B, B♭, D, C♯, C, E♭ (pitch classes: 9, 6, 7, 8, 4, 5, 11, 10, 2, 1, 0, 3). The row's hexachords are both instances of set class 6-1 (the chromatic hexachord of six consecutive pitch classes), enabling combinations like P₀ with I₅, where the first hexachord of P₀ matches the second hexachord of I₅, and vice versa, to form vertical aggregates in the work's canonic textures. This property allows Webern to overlap row forms in polyphony, such as the double canon in the second movement, creating dense yet controlled harmonic fields.[31]