Taking silicon photonics modulators to a higher performance level: state-of-the-art and a review of new technologies

Table 1. Prominent approaches for high-speed modulation in SiPh. The modulator implementations in SiPh use a variety of physical phenomenons, materials, optical architectures, and driver architectures.


The landscape of high-speed modulators in silicon photonics
Modulation	Operating principle	Platform	Reported optical implementation	Reported driver implementation
Phase	Plasma dispersion effect by carrier	Silicon	MZI, michelson, resonators (ring, disk, ph. crystal, Fabry–Perot), slow-light structure, Bragg reflectors	Lumped, traveling wave (TW), segmented
(a) Injection
(b) Accumulation
(c) Depletion
Pockels effect	${LiNbO}_{3}$ on silicon	MZI	Lumped, TW
Organics on silicon	MZI, ring resonator	Lumped, TW
BTO on silicon	MZI, ring resonator	Lumped, TW
PZT on silicon	MZI, ring resonator	Lumped
Interband transitions	2D materials on silicon	MZI, ring resonator	Lumped, TW
Carrier accumulations/carrier depletion+Franz-Keldysh effect	III-V on silicon	MZI, ring resonator	Lumped, TW
Amplitude	Franz-Keldysh effect	Silicon-germanium	Waveguide, MZI	Lumped
Quantum confined Stark effect	Ge-Si-Ge quantum wells	Waveguide, Fabry–Perot cavity	Lumped
Electrical gating	2D materials on silicon	Waveguide	Lumped
Quantum confined Stark effect	III-V on silicon	Waveguide	Lumped

The electrical driving of the modulator comprises an electrode configuration and the driving scheme (such as single-ended drive with dual-arm push-pull, differential drive with dual-arm push-pull, differential drive with dual-arm push-pull with shared drive, or dual-differential drive with dual-arm push-pull) to feed the electrodes.²⁵ Generally, the length of the phase shifter determines the electrode configuration.²⁰⁹ Modulators with a short phase shifter length (phase shifter length $< λ_{RF} / 10$ )²^,²⁵ use lumped electrodes.²⁰⁹^,²¹⁰ Lumped driving is applicable to modulators comprising interferometric structures,⁶⁵^,²¹⁰^,²¹¹ as well as cavity-based structures⁹^,¹²^,⁶²^,⁷⁰^,¹¹⁵ and slow-light structures.¹¹²^,¹¹³ With lumped electrodes, the applied voltage is approximately identical across the entire length of the phase shifter. Lumped driving does not necessarily require a matched termination of the driving electrodes. With unterminated lumped driving, the phase shifter’s capacitive load determines the energy consumption per bit ( $E_{bit}$ ) for a modulator. Typically, the bandwidth of lumped electrode phase shifter driving is limited by its impedance (intrinsic, parasitic, and the one contributed by the driving circuitry) and the time taken by the photons to transit through the phase shifter. The latter effect is more pronounced for the slow-light modulators.¹¹³^,¹¹⁴

The traveling wave (TW) is the most common driving scheme for carrier depletion plasma dispersion MZMs.²^,⁴^,²⁵^,²¹⁰^,²¹² In this scheme, a single driver drives the entire electrode of the phase shifter.²⁵^,²¹² The TW electrode typically comprises a coplanar waveguide transmission line. It terminates with a resistive impedance matched to the wave impedance of the electrode. The RF power applied to the TW electrode is consumed by the RF losses in the TW, capacitive loading by the phase shifter, and the matched termination. The matched resistance prevents electrical reflections and consequent interference with the electrical signal stream. But, it also increases the power consumption of the TW electrode as a fraction of the total input RF power is always consumed by the matched termination. Generally, TW driving schemes are six to eight times more energy-hungry than the lumped driving.²^,⁴ The detrimental factors impacting the bandwidth of the modulators with TW driving are: (a) RC time constant of the phase shifter; (b) walk-off (phase mismatch due to mismatch between the propagation speed of the electrical signal in the transmission line and the optical signal in the waveguide) between the electrical and optical signals; and (c) RF-losses in the TW electrode.

The segmented topology with distributed driving comprises a series of short phase shifters, which are individually driven by lumped electrodes.⁶^,²²^,⁶⁶ Segmentation of the phase shifter with distributed driving avoids the RF attenuation due to a long transmission line while enabling the same voltage swing across the whole length of the phase shifter.²¹² As compared to the TW architecture, the segmented electrodes require smaller-size voltage drivers.²⁵ The precise delivery of the electrical signal to a phase shifter segment requires time synchronization with the transit time of light in that segment, which requires timing control circuitry for precise delivery of the electrical signal to each segment. This additional overhead undermines the energy efficiency of the segmented drivers and adds to the driver complexity. The number of phase shifter segments and their length determine the modulator bandwidth and its power efficiency. Typically, segmented electrodes with distributed drivers require tighter connectivity between the electronic drivers and the phase shifter segments to preserve the signal integrity and prevent parasitic effects. Therefore, this driving scheme demands either monolithic integration of electronics and photonics or flip-chip bonding photonic and electronic chips through an array of microbumps. Electrical driving plays a crucial role in defining the performance (primarily the power consumption and bandwidth) of high-speed phase modulators.²^,¹²²^,²¹⁰ In the early years, most of the high-speed modulator demonstrations focused on the optimization of modulator performance in isolation from the driver design.¹²² Recent demonstrations of high-speed modulators have established that concurrent co-design and co-optimization of electrical driving and photonic phase shifter design²⁵^,⁵²^,¹²² are a key to extracting the best performance for all modulator performance attributes.⁵²^,²¹³ This holds for modulators involving monolithic or hybrid integration with electronics.²⁵^,¹²²^,²¹³

This paper aims to provide a comprehensive review of the new technologies that provide additional, viable routes to enhance the performance of SiPh modulators. These new technologies involve the integration of materials with high electro-optic coefficients with SiPh platforms. As a result, they promise to deliver modulator performance that is required to meet the blistering surge in transmission rates for the optical links. This paper also compares these new technologies against the current mainstream SiPh modulator implementations. A comprehensive coverage in full detail is very challenging and difficult to be performed in a paper with a limited page number. Therefore, we will limit the discussion in this paper to some of the most important and relevant implementations of high-speed modulators in SiPh. It is important to note that the SiPh modulators have been used to modulate signals by means of advanced modulation schemes such as QPSK,⁵⁵^,⁵⁶^,¹²⁴ QAM,¹²⁵^,¹²⁶ PAM-4,²⁹^,⁵²^,¹²⁷ and PAM-8.¹¹⁵ However, in this paper, the operating speed is quoted only for OOK. Furthermore, the discussion in this paper is limited to C-band and O-band implementations of SiPh modulators for telecommunication and data communication applications; though SiPh modulators are also reported for mid-infrared (mid-IR) wavelengths²¹⁴^,²¹⁵ and for non-telecom/datacom applications.²¹⁵

2 State-of-the-Art of Contemporary Silicon Photonic High-Speed Modulators

Research to develop SiPh modulators dates back to the era when it was still a niche choice for photonic integration.⁶¹^,⁶⁴^,⁸⁸^–⁹⁰^,²¹⁶ Unstrained silicon has a fundamentally zero linear electro-optic effect (the Pockels effect, used in traditional ${LiNbO}_{3}$ modulators) due to its crystallographic structure (i.e., centrosymmetric crystal lattice), albeit strained silicon is investigated for high-speed all-silicon modulation.²¹⁷^–²¹⁹ This intrinsic property of Si directed the researchers to investigate other optical phenomenons, such as the plasma dispersion effect to realize high-performance modulators in SiPh. This section provides a summary of the plasma dispersion modulators to implement SiPh high-speed modulators.

2.1 High-Speed Modulators Using the Plasma Dispersion Effect

The refractive index change by the plasma dispersion effect in silicon is larger than the change by the Kerr⁶¹^,²²⁰ and FK effects.³¹^,⁶³^,¹⁴¹ The plasma dispersion effect is broadband going all the way from telecom to mid-IR wavelengths²²¹ and is relatively temperature independent.²²²^–²²⁵ Furthermore, its implementation is inherently simple, using standard CMOS processing technology.⁸¹ All of these factors made the plasma dispersion effect one of the current mainstream mechanisms to implement efficient high-speed modulators in SiPh.²^,²¹^,³⁵^,⁴⁹ Years of development, led by both industry and academic players, have resulted in the demonstration of plasma dispersion effect-based phase modulators providing losses of $< 10 dB / cm$ ,⁷¹^,⁸⁰^,¹¹⁶^,¹¹⁸^,¹²¹ phase modulation efficiencies $V_{π} \cdot L < 0.3 V \cdot cm$ ,⁵^,⁶⁹^,¹⁰⁴ energy consumption as low as tens of fJ/bit,¹⁸^,⁹⁹^,¹¹⁰^,¹¹¹^,¹¹⁵ and data rates reaching $100 Gb / s$ ¹⁴^,⁸⁷^,¹²²^,¹²³ for OOK modulation with minimal influence of temperature on the performance of the plasma dispersion modulators (III–V modulators rely on the QCS effect and are influenced by temperature). It is important to note that all of these specs are not provided simultaneously by a single plasma dispersion modulation implementation.²¹

Plasma dispersion is an electro-refractive effect. The change of free carrier concentration by the movement of charge carriers into or out of a waveguide results in phase modulation of the optical signal.²¹^,⁴⁹^,⁶¹ Phase modulation is translated into intensity modulation by embedding the phase modulator into MZIs,¹⁵^–¹⁷^,⁷⁷^,⁷⁹^,¹⁰⁸^,¹⁰⁹ RRs,¹⁸^,³²^,³³^,⁶²^,¹¹⁰^,¹¹¹^,¹¹⁹ Bragg reflectors,⁸⁸ Michelson interferometers,⁸^,¹²¹ photonic crystal cavities,⁹⁸^,¹¹²^–¹¹⁴ and Fabry–Perot cavities.¹⁰⁰ The three prominent schemes to introduce change in the free carrier concentration are (a) the injection of minority carriers⁷^,³⁷^,⁶¹^–⁶⁷ by forward biasing a PIN junction; (b) the accumulation of majority carriers¹²^,⁶⁸^,⁶⁹^,⁶⁹^,⁷⁰ of opposing polarity across an insulating section in a waveguide; (c) the depletion of majority carriers⁹^,¹³^,¹⁴^,¹⁶^,²²^,³²^,³³^,⁷¹^,⁷¹^–⁸⁷ from a PN junction by reversely biasing it.

Carrier injection is the most efficient plasma dispersion-based modulation scheme.⁷^,⁸^,³⁷^,⁹⁸ Most of the early demonstrations of high-speed modulators relied on carrier injection of minority carriers by forward biasing a PIN junction built along a waveguide.⁶³^,⁸⁹^,⁹⁰^,⁹³^,²¹⁶^,²²⁶ The carrier injection-based modulators provide a high modulation efficiency due to their large diffusion capacitance (typically $\sim 10 pF$ ) when implemented on a waveguide with a small cross section with stronger confinement.⁷^,³⁷^,⁶⁵^–⁶⁷^,⁹¹^–⁹⁴ Carrier injection-based modulators are reported using lateral PIN⁶³^,⁶⁵^,⁶⁷^,⁹² and vertical PIN configurations (see Fig. 1).⁶³^,⁸⁹^,⁹³^,²¹⁶^,²²⁶ Owing to the feasibility for a short phase shifter ( $\sim$ a few hundreds of $μ m$ ), carrier injection modulators typically use lumped driving schemes.⁷^,⁶⁵^,⁶⁷ The use of pre-emphasized electrical signaling schemes, in which a fraction of the electrical driver signal has a voltage $≫ V_{π}$ of the modulator, boosts the limited speeds of carrier injection-based modulators⁶⁷^,⁹⁵^–⁹⁷ with the obvious ramification of increased power consumption. Recent years have seen the development of passive equalization techniques to boost the high-speed operation of the carrier injection modulators.⁶⁵^,⁶⁷ The studies have shown that the factors that limit the speed of the carrier injection-based modulation are (a) recombination time of the injected electron–hole pairs and (b) the sum of the electrical driver output resistance and the bulk resistance of the p- and n-doped regions.⁷^,⁶⁵^,⁶⁷ The slower of these two effects determines the speed limit of the carrier injection modulators.⁶⁷ Practically, it is possible to improve the bandwidth of carrier injection modulators by embedding an $R_{E} C_{E}$ passive equalizer such that $R_{E} C_{E} = R_{F} C_{F}$ and $C_{F} ≫ C_{E}$ , where $R_{E, F}$ and $C_{E, F}$ are the equalizer and the forward resistance and the capacitance, respectively.⁷^,⁶⁵^,⁹¹ Current state-of-the-art carrier injection modulators use this passive equalization to demonstrate $> 20 Gb / s$ operation.⁷^,⁶⁵ Recently, 70 Gbaud operation of a carrier injection MZM was enabled by passive RC equalization.⁷ The modulator has a 37-GHz 3-dB bandwidth using a 0.25-mm long-phase shifter having $\sim 28 dB / cm$ loss and a $V_{π} \cdot L$ of $2 V \cdot cm$ .⁷ One of the best modulation efficiencies of $0.274 V \cdot cm$ has been reported in Ref. 67, where a side-wall corrugated MZM with a bandwidth of 12.5 GHz is operated at $25 Gb / s$ using a finite impulse response filter for frequency compensation necessary for the broadband operation.⁶⁷ The demonstrated modulator had a $250 - μ m$ -long phase shifter that exhibited a propagation loss of $5.3 dB / mm$ .

Figure 1.(a) Baseline architecture of carrier injection, carrier depletion, and carrier accumulation plasma dispersion phase shifters. (b) Various configurations of plasma dispersion phase shifters.

The carrier accumulation plasma dispersion phase shifter requires forward biasing of a metal-oxide-semiconductor (MOS) capacitor.²^,⁶⁸^,¹⁰¹^,¹⁰² A typical implementation of an MOS (also known as silicon–insulator–silicon capacitor—SISCAP) modulator comprises a vertical slot waveguide with an overlapping stack of a $sub - μ m$ -sized thick p-type poly-silicon layer on top of a $sub - μ m$ -sized thick n-type c-silicon layer with a few nm (typically $< 20 nm$ ) thick insulating gate oxide layer in the middle (i.e., p-Si/insulator/c-Si vertical slot waveguide)—see Fig. 1(a).⁶⁹^,¹⁰¹^,¹⁰² Under accumulation conditions, in which a positive bias is applied to the p-type layer, the vertically confined optical mode overlaps strongly with the highly capacitive gate section.¹⁰¹^,¹⁰² This enables $< 1 V \cdot cm$ modulation efficiency for SISCAP modulators³⁷ with state-of-the-art values as low as 0.2 and $0.16 V \cdot cm$ .⁵^,⁶⁸^,⁶⁹ Owing to this higher modulation efficiency, typically $\leq 0.5 - mm$ -long phase shifters with lumped electrical driving are implemented in SISCAP modulators.⁶⁵^,⁶⁷^,⁶⁹^,⁶⁹^,¹⁰³ The higher capacitance, which leads to higher modulation efficiency, caps the modulation speed of SISCAP modulators.²^,¹⁰⁴ The modulation efficiency and speed can be traded-off in SISCAP modulators by adopting the capacitance to a value that can provide either an efficient modulator (i.e., high capacitance) with low $V_{π} \cdot L$ or high-speed modulator (i.e., low capacitance) without any degradation of the loss parameter for the modulator (the increase or decrease in capacitance is independent of the doping level and is controlled by the thickness of gate oxide and the relative permitivity of the material used as the gate oxide).²^,⁷⁰^,¹⁰¹^,¹⁰²^,¹⁰⁴ Typically, a vertical capacitor configuration is used in SISCAP modulators due to the ease of fabrication.⁵^,⁶⁸^,⁶⁹^,⁶⁹^,⁷⁰^,¹⁰⁴ It is straightforward to fabricate by the deposition of poly-Si.²^,¹⁰¹ Techniques such as epitaxial lateral growth¹⁰¹^,¹⁰² and laser-induced epitaxial growth crystallize the poly-silicon layer to overcome the higher scattering loss due to defects in the lattice.²^,²²⁷ Recently, SISCAP modulators using a c-Si/insulator/c-Si in a vertical slot configuration⁷⁰ and in a horizontal slot configuration¹⁰³ without requiring any additional processing steps have been reported [see Fig. 1(b)]. One of the first $40 Gb / s$ Mach–Zehnder SISCAP modulators relied on a vertical capacitor configuration, and it delivered an ER of 9 dB.⁶⁸ The design consisted of a $400 - μ m$ -long MOS capacitor with a $6.5 - dB / mm$ loss delivering a $V_{π} \cdot L$ of 0.2 cm for the O-band. The same MZM is driven by a CMOS driver to demonstrate its low-power operation for NRZ-OOK and for advanced modulation formats such as PAM-4 using a segmented driver.⁵ A recent demonstration reports high modulation efficiency of $0.16 V \cdot cm$ for $25 Gb / s$ operation using a $60 - μ m$ -long phase shifter with a loss of $3.5 dB / mm$ .⁶⁹ The MZM provided one of the best FoMs ( $α \cdot V_{π} \cdot L$ ) of $< 7 dB \cdot V$ . A microdisk-based SISCAP modulator demonstrated $15 Gb / s$ operation on a small footprint of $\sim 30 μ m^{2}$ consuming only $55 fJ / bit$ .⁷⁰ In order to deliver $> 50 Gb / s$ operation using SISCAP modulators, a parametric study has been performed validating the trade-off between high-speed operation, modulation efficiency, and loss.¹⁰⁴

Depletion of electrons and holes by reversely biasing a PN junction built in or around it is the most widely adopted scheme to implement the plasma dispersion-based phase modulator.⁸^–¹¹^,¹³^–¹⁹^,²²^,³²^,³³^,⁷¹^,⁷¹^–⁸⁷^,¹⁰⁶^–¹²¹ Depletion-based modulators were the first all-silicon modulator to reach speeds of 40¹⁰⁶ and $50 Gb / s$ .¹⁶ The current highest reported data rates of $100 Gb / s$ using OOK modulation were also demonstrated in carrier depletion modulators.¹²²^,¹²³ Carrier depletion phase shifters exhibit a relatively limited capacitance of 0.2 to $0.8 pF / mm$ ²¹^,⁹¹ and, hence, a limited modulation efficiency. In order to improve the modulation efficiency, the capacitance can be increased by either shrinking the mode size (determined by the waveguide geometry) or by reducing the width of the depletion region (higher transition capacitance).²¹ The latter requires higher doping concentrations, which leads to higher loss due to free carrier absorption. Over the years, a wide variety of PN junction designs are reported to solve this challenge of optimizing modulator speed, efficiency, and loss at the same time.¹³^,¹⁵^,¹⁷^,¹⁸^,²²^,⁷¹^–⁷⁶^,⁷⁸^,¹⁰⁷^–¹⁰⁹^,¹¹⁶^,¹¹⁷^,¹¹⁹ Distinct categories of PN junction implementation are as follows:

One of the first $40 Gb / s$ modulators relied on a vertical PIN junction and delivered a modulation efficiency of $4 V \cdot cm$ and phase shifter loss of $18 dB / cm$ .¹⁰⁶ Using a vertical P(I)N junction design, an athermal microdisk modulator with a high modulation efficiency of $250 pm / V$ consuming $0.9 fJ / bit$ while operating at $25 Gb / s$ using NRZ-OOK signaling has been reported.¹⁸ At $25 Gb / s$ , the modulator had an IL of $\sim 1 dB$ and an ER of 6 dB. One of the highest operating speeds of $60 Gb / s$ with 3.8 dB ER comprised a symmetric PN junction.¹⁷ In this case, the modulator operated in a series of push–pull modes by connecting back-to-back the phase shifter PN junction embedded on both arms of the MZI. The series connection of the two phase shifters halves the net capacitance, and the push–pull scheme limits the chirp of the modulator. The modulator shows 50 GHz bandwidth at 4 V reverse bias and an average modulation efficiency of $3.2 V \cdot cm$ for a 4-mm-long PN junction.¹⁷ In another implementation, a symmetric carrier depletion MZM with sub-1 V drive signal operated at $20 Gb / s$ and delivered a power consumption as low as $200 fJ / bit$ .¹¹⁸ Yet another variant of the symmetric lateral PN junction used the doping compensating technique¹²⁰ to demonstrate a $50 - Gb / s$ MZM comprising a 3-mm-long phase shifter with a modulation efficiency of $1.85 V \cdot cm$ and a loss of 3.9 dB. An RM relying on a symmetric phase shifter configuration delivered a modulation efficiency of $25 pm / V$ at 0 V¹¹⁹ to demonstrate $36 fJ / bit$ energy consumption for $40 Gb / s$ operation on a compact footprint of $0.5 {mm}^{2}$ . A recent implementation demonstrates a $64 - Gb / s$ MZM, in which the carrier depletion-based phase shifter is implemented through a $200 - μ m$ -long photonic crystal slow light structure.¹¹⁴ The modulator used a meandered RF electrode terminated with a $20 Ω$ resistor to provide a bandwidth of 38 GHz by preventing the velocity mismatch of the electrical and optical signals. The modulator required a voltage swing of 5.5 V to provide an energy consumption of $21 pJ / bit$ and provided 4.8 dB ER. The literature also reports various other demonstrations of asymmetric (where there is an offset of the PN junction from the waveguide center) carrier depletion-based phase shifters.⁸^,¹⁶^,⁷²^,⁷⁴^,⁷⁶ For example, a Michelson interferometer with a partially shifted PN-junction provided one of the highest modulation efficiencies of $0.72 V \cdot cm$ at 1 V reverse bias and 4.7 dB loss for a $500 - μ m$ -long PN junction with a lumped driving scheme to operate at $40 Gb / s$ through a bandwidth extension scheme involving a resistor parallel to the PN junction.⁸ The asymmetric PN diodes are also exploited by RRs⁷²^,⁷⁶ to demonstrate low-power (sub- $100 fJ / bit$ ) and compact depletion modulators. The literature also reports fully shifted PN junctions, where a self-aligning process allows for the alignment of the n-doped region to the edge of the waveguide.¹⁶^,⁷⁴ In one implementation of a fully shifted PN junction, a $50 - Gb / s$ MZM modulator provided a modulation efficiency of $2.8 V \cdot cm$ and an IL of 4 dB for a 1-mm-long phase shifter.¹⁶ By further optimizing the implementation of self-aligned PN junctions,⁷⁴ a demonstration provided an $\sim 1 dB / mm$ loss without compromising the speed of the modulator. The self-aligning process is further exploited to implement a PIPIN phase shifter with a modulation efficiency of $3.5 V \cdot cm$ for a 0.95-mm-long phase shifter introducing 4.5 dB optical loss when operated at $40 Gb / s$ .⁷⁹ Depletion-based modulators relying on an interleaved phase shifter design have also delivered high-speed operation. A modulator comprising a 3-mm-long interleaved phase shifter reported a high modulation efficiency of $0.62 V \cdot cm$ with a static IL of 2.8 dB while delivering $40 Gb / s$ modulation speed.⁸¹ An RM comprising a ring resonator with a $100 - μ m$ radius, and an MZM with a 0.95-mm phase shifter length operated at $40 Gb / s$ speed using an interleaved phase shifter delivering a modulation efficiency and loss of $2.4 V \cdot cm$ and $2.1 dB / mm$ , respectively.³² Apart from standalone implementations of high-speed phase shifters through these three baseline junction configurations and their adaptations, there are reports on junction implementations that rely on combining these three schemes in a single PN junction design.⁹^,³³^,⁷⁹^,⁸⁵^,⁸⁶ An example is the substrate-removed “zig-zag” phase shifter for an MZM delivering $1.6 V \cdot cm$ modulation efficiency for a 2-mm-long phase shifter with 4.4 dB loss.¹⁴ The modulator provided 55 GHz bandwidth and modulation speed of $90 Gb / s$ .¹⁴^,⁸⁷ Another example includes a phase shifter for $40 Gb / s$ operation of a racetrack RM by combining horizontal, vertical, and interleaved approaches. This implementation delivered a modulation efficiency of $0.76 V \cdot cm$ at $- 1 V$ reverse bias and a loss of $3.5 dB / mm$ .³³ A recent result demonstrated an RM with a record low modulation efficiency of $0.52 V \cdot cm$ by employing a phase shifter comprising a combination of horizontal and vertical junctions by wrapping the n-doped region over the intrinsic and the p-doped region.⁹ The modulator showed 50 GHz bandwidth and delivered $70 fJ / bit$ energy consumption for $64 Gb / s$ operation.

In the discussion presented above, we have provided a summary of the latest developments made for the improvement of plasma dispersion effect-based modulators. Figure 1(a) represents the three baseline plasma dispersion phase shifter architectures and their respective biasing configuration. Figure 1(b) gives an overview of a variety of other phase shifter configurations for carrier injection, carrier depletion, and carrier accumulation phase shifters.

Table 2 summarizes the typical performance for the injection, accumulation, and depletion-type plasma dispersion modulators. Table 2 also presents the best-reported results for the modulation efficiencies, losses, data rates, and energy consumption. There is an interplay of a vast pool of variables, such as junction type and its actuation mechanism, doping concentrations (typically ranging from $\sim 10^{17}$ to $\sim 10^{18} {cm}^{- 3}$ ) and their positions, the thickness of the slab waveguide (typically ranging from 1/3 to 1/4 of the guiding silicon thickness), the thickness of the guiding silicon layer (typically $< 1 μ m$ ), choice of the passive structure for the translation of phase modulation to amplitude modulation, and the design of the driving electrode (lumped, TW, and segmented), which can influence the performance of plasma dispersion modulators. In many cases, one performance parameter has to be delicately traded-off for another specification. This makes the design of a plasma dispersion modulator, which can meet all of the performance requirements concurrently, far from trivial. Operation of plasma dispersion modulators at speeds $> 70 Gb / s$ ⁷^,¹⁴^,¹²² consuming tens of fJ/bit with high modulation efficiency enabling micrometer-sized footprints has been accomplished. Recent developments have resulted in a co-designed SiPh modulator-driver offering $100 Gb / s$ while preserving a good modulation efficiency¹²² and without any customized fabrication process development. The plasma dispersion modulators deliver sufficient linearity and ER to handle advanced coherent modulation schemes,³^,⁵⁵^,⁵⁶^,¹²⁴^–¹²⁶ such as QAM, and amplitude modulation schemes,⁹^,¹⁷^,²⁹^,⁵²^,⁶⁶^,¹¹⁵^,¹²³ such as PAM. Furthermore, the plasma dispersion modulators have shown modest chirp-induced penalty for short- and long-haul links.³^,²⁶^,³⁰ The co-design and co-optimization of the driver–modulator design is the key to taking the performance of plasma dispersion modulators to a new level.¹²²

Table 2. Typical and state-of-the-art performance matrix for the plasma dispersion high-speed phase modulators. The parentheses contain the best-reported result for a performance attribute. The matrix includes the results reported for O-band and C-band demonstrations.

Table 2. Typical and state-of-the-art performance matrix for the plasma dispersion high-speed phase modulators. The parentheses contain the best-reported result for a performance attribute. The matrix includes the results reported for O-band and C-band demonstrations.


Principle	Modulation efficiency $V_{π} \cdot L$ ( $V \cdot cm$ )	Loss (dB/cm)	Lengtha of phase shifter (mm)	Data rateb(Gb/s)	Energy/bit (fJ/bit)
Carrier injectionc	< $0.5$ (0.058⁸)	$\sim 70$ (28⁷)	$\geq 0.1$ to < $0.3$	< $40$ (70⁷)	$\sim 1000$ for MZMs and RMs (0.1f^,⁹⁸)
Carrier accumulationd	< $0.3$ (0.16⁶⁹)	50 to 80 ( $\sim 35$ ⁶⁹)	$\leq 0.5$	$\sim 40$ (40⁵)	> $200$ for MZMs, < $200$ (3¹⁰⁵) for SLMsg
Carrier depletione	$\sim 2$ (0.52⁹)	10 to 30 (2.6¹⁰)	> $1$	> $40$ (100¹²²^,¹²³)	$\sim 200$ for MZMs (32.4¹⁹), < $40$ for RMs (0.9¹⁸)

3 New Materials on Silicon for High-Speed Modulators

Recent years have seen growing efforts to integrate materials with strong electro-optic effects on SiPh platforms.¹⁵³^–¹⁹²^,¹⁹²^–²⁰⁸^,²²⁸ The integration of new materials provides routes for optically broadband and energy-efficient high-speed modulation with little or no current flow.¹⁷⁶^,¹⁸¹^,¹⁸⁴^,¹⁸⁸^,²⁰² Furthermore, in some cases, these new materials provide an excellent decoupling between amplitude and phase modulation, which is difficult to achieve with contemporary all-silicon plasma dispersion modulation schemes.¹⁷⁴^,¹⁷⁸^,¹⁸⁴

Through the wafer-scale integration of these new material systems with SiPh platforms, one can achieve impressive modulator performance, while at the same time preserving the benefits provided by the mature SiPh technology.¹⁸¹ These new materials can be broadly categorized into the following:

Early results of high-speed modulators by integrating electro-optic materials with the SiPh platforms have shown a lot of promise. Many research teams are attempting to take their maturity and performance beyond the performance of plasma dispersion modulators. The sections below discuss the key modulator implementations by integrating these materials into SiPh platforms.

3.1 (Silicon-)Germanium

The FK effect and the QCS effect provide possible routes to implement compact, low-power, and high-speed electro-absorption modulators (EAMs) in SiPh.³¹^,¹⁴³^,¹⁴⁴^,¹⁴⁶^,¹⁴⁹ Under the influence of an applied electric field, the band edge tilts to enhance the absorption coefficient for GeSi bulk material (FK effect) or Ge/SiGe quantum well (QW) structures (QCS effect).³¹^,³⁸^,¹⁴⁵^,¹⁴⁶ These effects are intrinsically fast through their sub-ps response time.³⁴^,²²⁹ The QCS effect is stronger than the FK effect¹³⁴^,²³⁰ due to the strong excitonic effect and discretized density of states. The integration of bulk GeSi or Ge/SiGe QW requires epitaxial growth on SiPh platforms. The FK effect is considered more attractive than the QCS effect in the context of integration feasibility. The latter requires a more complex epitaxial growth process for band alignment and strain balancing.¹⁵²^,²³⁰ A large change in the absorption coefficient (typically ranging from 100 to $1000 {cm}^{- 1}$ in the C-band¹⁴⁶) enables the implementation of a compact and energy-efficient EAM using the FK effect and QCS effect.³¹^,²³⁰ Both effects rely on band engineering. Therefore, they have limited optical bandwidth ( $\sim 30 nm$ for the FK effect and $\sim 20 nm$ for the QCS effect).¹³⁴^,¹⁴⁹ In one of the first SiPh EAMs, the L-band absorption spectrum is shifted to the C-band by a tensiled 0.8% GeSi alloy.³¹ On a small footprint of only $30 μ m$ , the EAM actuated by a vertical PIN diode provided an energy consumption of only $50 fJ / bit$ . This EAM could operate over a 14-nm bandwidth from 1539 to 1553 nm and delivered an efficiency (defined as $Δ α / α_{on}$ , where $Δ α$ is the absorption difference between ON-state and OFF-state, and $α_{on}$ is the absorption for the ON-sate, in which no electric field is applied) of 2. Despite the limited bandwidth of 1 GHz, this promising demonstration triggered other demonstrations of EAMs.²⁰^,³⁸^,¹²⁸^,¹³³^–¹³⁹^,²³¹^,²³² An evanescently coupled $55 μ m^{2}$ GeSi EAM has been reported on a thick SOI platform (silicon guiding layer thickness of $3 μ m$ ), actuated by a horizontal PIN junction.¹³⁵ This EAM is butt-coupled to the thick SOI waveguide through an appropriately designed taper.¹³⁵ The modulator has an efficiency of $\sim 1$ . This EAM operated in the C-band and provided $28 Gb / s$ operation with $60 fJ / bit$ energy consumption.¹³⁵ Literature also reports an L-band Ge EAM and a GeSi C-band EAM with an electrical 3-dB bandwidth of $\sim 50 GHz$ for an optical bandwidth of 30 nm.¹³⁶ In this case, the EAM is butt-coupled to a silicon waveguide through a tapered waveguide section. The Ge or GeSi alloy, which is grown on a silicon recess, has a lateral PIN diode. A highly doped contact on the silicon layer biases the EAM. The modulator consumed $12.8 fJ / bit$ energy at modulation speeds of $56 Gb / s$ and provided an FoM of $< 1$ . Using this GeSi EAM, a digital to analog converter-less and digital signal processing (DSP)-free $100 Gb / s$ transmission over a 500-m-long single-mode fiber using NRZ-OOK signaling has been reported.²⁰^,¹³⁷

There are various reports on the implementation of the Ge/SiGe QCS effect-based modulators.¹⁴¹^–¹⁵² In one case, a Ge/SiGe QW modulator is butt-coupled to a thin SOI rib waveguide in such a way that the QWs and the rib waveguide are vertically aligned with each other to have maximum overlap.¹⁴⁷ The active section of the modulator, which comprised 15 pairs of $Ge / {Si}_{0.15} {Ge}_{0.85}$ QWs, is driven by a vertical PIN diode. The $8 - μ m^{2}$ modulator showed 3.5 GHz bandwidth by using a 1-V voltage swing (5.5 to 6.5 V) to provide $\sim 3 dB$ of ER. In another implementation, Ge QWs are epitaxially grown at temperatures below 450°C on the silicon-rich ${Si}_{1 - x} {Ge}_{x}$ low-loss waveguide platform.¹⁴¹ The $x$ concentration is selected such that it simultaneously ensures low indirect bandgap absorption and a sufficiently small lattice mismatch with the QWs. The $400 - μ m^{2}$ modulator with 6.3 GHz bandwidth and 0 to 3 V swing provided $\sim 4 dB$ ER and 3 dB IL.

The FK effect or QCS effect electro-absorption amplitude modulators allow for the implementation of coherent $I / Q$ ²³¹^,²³² and advanced amplitude modulation schemes such as PAM-4.²³³ These modulation schemes are a promising solution for short- and long-reach links because they are spectrally efficient while being tolerant of optical fiber transmission impairments.⁵⁴^,⁵⁵^,²³¹ The implementation of an EAM-based $I / Q$ or PAM-4 modulators relies on balanced MZIs with an EAM and a fixed phase-shift in the arms of the MZI.²³¹^–²³³ Typically, an unequal splitting of the optical carrier is required by the splitter of the MZI to achieve the appropriate eye-opening for PAM-4 or constellation for the $I / Q$ signal.²³³ Literature reports an EAM-based PAM-4 modulator by integrating an EAM in each arm of a two-port balanced MZI.²³¹^–²³³ In this modulator, a fixed phase shift is provided by embedding a thermal phase shifter in one of the two arms of the MZI. The device modulated a $128 - Gb / s$ PAM-4 signal without requiring any DSP. Furthermore, there are reports on the demonstrations of modulating QPSK and 16-QAM signals using EAM-based coherent modulators.²³¹^,²³² The energy consumption of these modulators takes a hit due to the power-hungry thermo-optic effect required to provide a fixed phase shift in the arms of the MZIs.

Figure 2 represents the typical cross sections of FK EAMs and QCS effect-based EAMs in SiPh. This figure also summarizes the integration routes of these materials with SiPh. Table 3 summarizes the typical and the best-reported performance for the (silicon-)germanium modulators. This table covers the performance of the FK effect-based EAMs as well as QCS effect-based EAMs. The FoM for both FK and QCS effect-based EAMs is typically $< 2$ , although QCS effect-based modulators can potentially deliver better FoM due to their stronger excitonic absorption peaks.¹⁴⁴^,¹⁴⁹^,¹⁵² In most cases, FK-effect-based EAMs operate either in the L-band or C-band.¹⁵⁰^,¹⁵² It is possible to tune the operating wavelength of the QCS effect modulators by a bias voltage.¹⁵⁰^,¹⁵² Therefore, the QCS effect modulators can operate in the O-band as well. In terms of high-speed operation, FK effect-based EAMs have reached line rates of up to $100 Gb / s$ for OOK modulation schemes,¹³⁷ whereas the QCS effect-based modulators have not yet demonstrated such a high speed of operation.

Figure 2.Representative cross sections of (a) FK-based EAMs and (b) QCS effect-based EAMs in SiPh. This figure also highlights the integration route for the respective EAMs. The term monolithic refers to the integration of a material with an SOI substrate using wafer-scale epitaxial growth resulting in PICs made out of one substrate technology in mass on a wafer level.

Table 3. Typical and state-of-the-art performance matrix for amplitude modulation by the FK effect and QCS effect. The best-reported performance attributes are mentioned in parentheses.

Table 3. Typical and state-of-the-art performance matrix for amplitude modulation by the FK effect and QCS effect. The best-reported performance attributes are mentioned in parentheses.


Principle	FoM ER/IL	Loss (dB)	Modulator length (mm)	Data ratea (Gb/s)	Energy/bit (fJ/bit)
FK effectb	< $2$ (2³¹)	< $6$ (4.8¹³³)	$\sim 0.050$	> $40$ (100¹³⁷)	< $50$ (13²⁰)
Quantum-confined Stark effectc	< $2$ (7.9¹⁴⁹)	< $6$ (1.3¹⁴⁹)	< $0.25$	< $10$ (7¹⁴⁷)	< $100$ (16¹⁴⁸)

3.2 Ferroelectrics

Ferroelectrics are materials possessing spontaneous polarization that can be altered by the application of a sufficiently strong electric field.²³⁴ As ferroelectric materials are non-centrosymmetric, they exhibit a Pockels effect.²³⁴ Many ferroelectrics have large Pockels coefficients compared to non-ferroelectric inorganic materials. The dominant contribution to the Pockels coefficients in these ferroelectrics tends to come from lattice vibrations rather than electron movements.²³⁴^,²³⁵ Because of their strong Pockels effect, the integration of ferroelectric materials such as ${LiNbO}_{3}$ ,¹⁶⁷^–¹⁷⁴ barium titanate ( ${BaTiO}_{3}$ ),¹⁷⁵^–¹⁸² and lead zirconate titanate (PZT)¹⁸³^–¹⁸⁵ with SiPh provides a promising route for the implementation of efficient, high-speed modulators.²^,¹⁷⁵^,²²⁸ A variety of integration techniques have been explored, such as molecular beam epitaxy (MBE),¹⁷⁶^,¹⁷⁸ pulsed laser deposition,²³⁶^,²³⁷ chemical solution deposition (CSD),²³⁸ RF magnetron sputtering,²³⁹ metal organic chemical vapor deposition,²⁴⁰ and atomic layer deposition.²⁴¹ The two key requirements for integrating ferroelectric materials with SiPh are to ensure a high electro-optic coefficient and low propagation loss.¹⁸² The following sections will review the latest developments to implement high-speed modulators by integrating ferroelectric materials with SiPh.

3.2.1 LiNbO₃ on silicon (nitride) high-speed modulators

${LiNbO}_{3}$ is a widely used material for modulators and provides high-speed devices with a bandwidth of $> 35 GHz$ .²⁷^,²⁴²^,²⁴³ ${LiNbO}_{3}$ modulators have been used for a long time in fiber-optic networks.²⁴²^,²⁴⁴ These devices are based on low-index-contrast waveguides in bulk ${LiNbO}_{3}$ ,²⁴² in which the index contrast between the core and cladding of a ${LiNbO}_{3}$ waveguide is provided by the diffusion of Ti or Li ions.²⁴² The weak optical guiding resulting from the low-index-contrast requires the electrical contacts to be placed far away from the waveguides, resulting in typical $V_{π} \cdot L$ of 10 to $20 V \cdot cm$ .²⁴² Recent demonstrations of high-index-contrast ${LiNbO}_{3}$ -on-insulator (LNOI) modulators have shown energy-efficient operation (a few tens of fJ/bit energy consumption) with 100-GHz bandwidth, $\sim 2 V \cdot cm$ modulation efficiency, and $< 0.5 dB$ loss for a device that is a few millimeters long (typically 2 to 20 mm long).²⁴³^,²⁴⁵^–²⁴⁷ These thin-film LNOI modulators rely on ${LiNbO}_{3}$ layers of a few hundred nanometers thickness, which are bonded on top of ${SiO}_{2}$ .²⁴³ Several approaches have been reported in the last two decades to integrate ${LiNbO}_{3}$ with silicon at room temperature²⁴⁵^,²⁴⁸^,²⁴⁹ and to demonstrate high-speed modulation by bonding ${LiNbO}_{3}$ with silicon¹⁶⁷^–¹⁶⁹^,²⁵⁰ or silicon nitride.¹⁷⁰^–¹⁷² The Pockels coefficient of integrated ${LiNbO}_{3}$ is comparable to that of bulk ${LiNbO}_{3}$ ,²⁴⁹ but most of these integration attempts have resulted in modulator bandwidths that are smaller than the all-silicon modulator implementations.¹⁷³ Recently, a tremendous boost in the speeds (not yet the overall performance) of such modulators has been reported.¹⁷³^,¹⁷⁴ For example, for a 5-mm long TW-MZM that was realized by direct oxide bonding of thin-film ${LiNbO}_{3}$ on top of a silicon waveguide, a bandwidth of 100 GHz and a loss of 7.6 dB have been reported.¹⁷³ The modulator had a limited efficiency of $6.7 V \cdot cm$ due to $< 100 %$ vertical coupling of light into the unpatterned ${LiNbO}_{3}$ membrane on top of the silicon waveguide. In another implementation, the complete coupling of light from a silicon waveguide to a patterned ${LiNbO}_{3}$ rib waveguide through a vertical adiabatic coupler resulted in a modulation efficiency of $\sim 2.5 V \cdot cm$ .¹⁷⁴ With a 2.5-dB loss, the 5-mm-long ${LiNbO}_{3}$ phase shifter embedded in an MZI and driven by a TW electrode in the push–pull configuration provided 70 GHz bandwidth and enabled single-lane $100 Gb / s$ NRZ-OOK transmission. Unlike the other reported implementation,¹⁷³ the integration of ${LiNbO}_{3}$ with the SiPh PIC was carried out using BCB-bonding. Monolithic integration of ${LiNbO}_{3}$ with SiPh PICs has yet to be reported.

3.2.2 BaTiO₃ on silicon high-speed modulators

In recent years, there has been a lot of interest in the integration of ${BaTiO}_{3}$ with SiPh.¹⁷⁵^–¹⁸² ${BaTiO}_{3}$ is a promising material for integration with SiPh because of (a) its high Pockels coefficient [in bulk form, ${LiNbO}_{3}$ has a Pockels coefficient of $\sim 30 pm / V$ ,²⁷^,¹⁷⁵^,²⁴⁹ whereas BTO offers one of the highest Pockels coefficients ( $> 1000 pm / V$ ) in bulk form¹⁷⁶^,²⁵¹]; (b) feasibility of integration with a silicon substrate;²⁵² (c) capability to offer high-speed modulation;²⁵³ (d) high chemical and thermal stability of BTO; and (e) feasibility of low-loss hybrid BTO-Si passive circuitry.¹⁷⁸^,¹⁷⁹ The integration of BTO with SiPh relies on epitaxial growth enabling integration compatible with 200 and 300 mm silicon wafers.¹⁸¹ The large lattice mismatch ( $\sim 27 %$ ) between BTO and Si makes the integration of the two materials far from trivial.²⁵⁴ A ${SrTiO}_{3}$ (STO) buffer layer of a couple of nanometers thickness reduces this lattice mismatch to $< 2 %$ .²²⁸ Among the various possible routes to grow BTO on SiPh platforms, MBE is known to provide the highest ( $> 900 pm / V$ ) Pockels coefficient in BTO thin films.¹⁷⁶ In one approach, the BTO growth is done directly on an SOI wafer.¹⁷⁷ Afterward, an amorphous silicon layer with a thickness equal to the thickness of the c-Si layer of the SOI wafer is grown. The resulting heterostructure is patterned lithographically to form a horizontal slot waveguide. Stronger guiding of the optical signal in the low-index BTO layer ( $n_{BTO} \sim 2.38$ ) enhances the overlap of the optical and electrical field in the BTO layer. This approach provided a Pockels coefficient of $213 \pm 49 pm / V$ .¹⁷⁷ A ring-based modulator with a modulation efficiency of $1.5 V \cdot cm$ and a bandwidth of 4.9 GHz has been reported, where the limited bandwidth is associated with the parasitic electrical effects.¹⁷⁷ A key challenge faced by the integration approach mentioned in Ref. 177 and other integration approaches¹⁷⁶^,¹⁷⁸ is the high propagation loss ( $> 40 dB / cm$ ).¹⁷⁶^–¹⁷⁸^,²⁵⁵ The origin of this high loss is attributed to the absorption of hydrogen by the STO seed layer during the fabrication of the slot waveguide.¹⁷⁸ Furthermore, it has been shown that a loss of $6 dB / cm$ in a strip-loaded horizontal slot waveguide can be achieved by low-temperature annealing.¹⁷⁸ Apart from the aforementioned approach, where BTO is grown directly on an SOI wafer,¹⁷⁷ another possible approach entails the formation of a BTO/Si heterostructure by bonding an SOI wafer with a BTO layer grown on a host SOI wafer.¹⁷⁶^,¹⁷⁹ For such a bonded BTO/Si heterostructure, a Pockels coefficient of $923 pm / V$ has been reported (30 times larger than that of a ${LiNbO}_{3}$ structure).¹⁷⁹ In one implementation, a plasmonic MZM with a $10 - μ m$ -long BTO/Si phase shifter with 25 dB loss delivered $72 Gb / s$ and required a $V_{π}$ of 14.5 V (modulation efficiency of $0.0145 V \cdot cm$ ).¹⁸⁰ The modulator operated successfully for temperatures up to 130°C. Furthermore, a wafer-level bonding of Si/BTO heterostructures on the back-end-of-line (BEOL) dielectric layer of an advanced SiPh platform has been reported.¹⁸¹ This integration led to the demonstration of an MZM with a limited bandwidth of 2 GHz (mostly limited by the electrical bandwidth of the electrodes).¹⁸¹ The modulator had a modulation efficiency of $0.2 V \cdot cm$ and loss of $< 6 dB$ for a 1-mm-long phase shifter.¹⁸¹^,¹⁸²

3.2.3 PZT on silicon nitride high-speed modulators

PZT is an orthorhombic lead-containing ceramic ferroelectric material.²⁵⁶^,²⁵⁷ Though BTO has a large Pockels coefficient, its use in SiPh requires complex and expensive integration technology.¹⁷⁸^,¹⁸¹^,¹⁸²^,²⁵⁵ As compared to BTO, PZT has a smaller Pockels coefficient, but it can be deposited by a low-cost and simple CSD method.¹⁸⁵^,²⁵⁷ Ultra-thin lanthanide-based intermediate seed layers enable the deposition of high-quality thin (up to 200 nm) PZT layers on silicon,²⁵⁷ with Pockels coefficients up to $150 pm / V$ .²²⁸ PZT thin films have been integrated with silicon nitride photonic circuits. An RM with a bandwidth of 33 GHz and an MZM with a bandwidth of 27 GHz have been demonstrated,¹⁸⁴ with a modulation efficiency of $3.2 V \cdot cm$ and a loss of $1 dB / cm$ . The PZT layer was deposited on a planarized silicon nitride PIC (i.e., the PIC consisted of silicon nitride strip waveguides with oxide bottom and side cladding, while the top cladding was air). The PZT thin film was poled by applying a voltage of 60 to 80 V for 1 h.¹⁸⁵

Figure 3 represents the typical cross sections of ferroelectric modulators in SiPh. This figure also summarizes the integration routes of the respective materials with SiPh. Table 4 presents a summary of the typical and the best-reported modulation efficiencies, losses, data rates, and energy consumption for the ferroelectric-based modulators in SiPh. For all three types (i.e., ${LiNbO}_{3}$ , BTO, and PZT), modulation speeds $\geq 40 Gb / s$ have been demonstrated. ${LiNbO}_{3}$ -based modulators are outstanding in terms of low-loss operation and have delivered speeds of $\sim 100 Gb / s$ . In terms of modulation efficiency, BTO-based modulators have shown a lot of promise with typical reported values of $< 0.5 V \cdot cm$ .

Figure 3.Representative cross sections of (a) ${LiNbO}_{3}$ , (b) BTO, (c) PZT, and (d) organics modulators in SiPh. This figure also highlights the integration route for each material. The term monolithic refers to the integration of a material with a SiPh substrate using wafer-scale epitaxial growth resulting in PICs made out of one substrate technology in mass on a wafer level.

Table 4. Typical and state-of-the-art performance matrix for the ferroelectric and organic high-speed phase modulators in SiPh.a The parentheses contain the best-reported result for a performance attribute.

Table 4. Typical and state-of-the-art performance matrix for the ferroelectric and organic high-speed phase modulators in SiPh.a The parentheses contain the best-reported result for a performance attribute.


Scheme	Modulation efficiency $V_{π} \cdot L$ ( $V \cdot cm$ )	Loss (dB/cm)	Length of phase shifter (mm)	Data rateb(Gb/s)	Energy/bit (fJ/bit)
${LiNbO}_{3}$ integrated with SiPhc	< $3$ (2.2¹⁷⁴)	$\sim 1$ (0.98¹⁷⁴)	> $1$	> $70$ (100¹⁷⁴)	> $100$ (170¹⁷⁴)
${BaTiO}_{3}$ integrated with SiPhd	< $0.5$ (0.2¹⁸²)	> $40$ (6¹⁸²)	> $1$	> $40$ (72¹⁸⁰)	< $100$ ¹⁷⁹
PZT integrated with SiPhe	1 (1¹⁸³)	1 (1¹⁸³)	> $2$	40 (40¹⁸⁴)	-
Organics integrated with SiPhf	< $0.05$ (0.032¹⁹⁰)	< $45$ (20²²⁸)	< $1.5$	> $50$ (100¹⁹⁶)	< $100$ (0.7¹⁹²)

3.3 Organic Electro-Optic Materials

Organic electro-optic materials are typically based on $π$ -conjugated molecules with strong electron donor and acceptor groups at the ends of the $π$ -conjugated structure.¹⁸⁸^,²⁵⁸ The delocalized electrons associated with this $π$ -conjugated structure are confined by a strongly asymmetric potential well, giving rise to large Pockels coefficients.¹⁸⁸^,²⁵⁸ In contrast to the ferroelectrics discussed above, the Pockels effect in these organic electro-optic materials is mostly electronic in nature and can thus provide an ultra-fast response.¹⁸⁸^,¹⁹⁰^,²²⁸^,²⁵⁸ Organic electro-optic materials can be processed at room temperature using inexpensive solution-based techniques, whereas the growth of inorganic Pockels materials typically requires high temperatures and/or the use of vacuum equipment.¹⁷⁷^,¹⁸²^,¹⁸⁸^,²⁵⁵^,²⁵⁸

A combination of organic materials with SiPh devices has resulted in the so-called silicon-organic hybrid (SOH) class of modulators.¹⁸⁶^–¹⁸⁸^,¹⁹⁷ The underlying organic materials in SOH modulators are designed to provide high electro-optic activity with experimentally demonstrated values of $n^{3} r > 2000 pm / V$ .¹⁹⁰ This results in modulators with a low-loss,¹⁹⁴ a low-chirp parameter of $α = - 0.02$ ,¹⁹³ and a high modulation efficiency ( $V_{π} \cdot L \approx 0.03 V \cdot cm$ ),¹⁹⁰ along with a high modulation bandwidth ( $> 100 GHz$ )¹⁹¹^,²⁵⁹ and low-energy consumption of a few fJ/bit.¹⁹²^,²²⁸ With $π$ -voltages below 1 V, SOH modulators may be directly driven by standard CMOS circuits without the need for any additional drive amplifiers,²⁶⁰ thereby opening a path toward greatly reduced power dissipation in highly integrated transceivers. For the fabrication of SOH devices, the organic electro-optic material is deposited onto fully processed SiPh chips in a postprocessing step, which requires removal of the BEOL layer stack of a standard SiPh process flow.²²⁸ SOH modulators rely on slot waveguides,¹⁸⁸^,¹⁹¹ which guarantees enhanced interaction between the highly confined optical mode in the slot waveguide and the organic electro-optic material filling the slot. To pole the electro-optic material after deposition, the devices are heated, and a DC voltage is applied across the slot waveguides. This non-volatile poling transforms the random orientation of the electro-optic chromophores in the slot into an acentric orientation, thereby leading to a non-zero Pockels coefficient. After cooling down the device to ambient temperature, the voltage can be removed, and the poled electro-optic material preserves its orientation. SOH modulators have shown exemplary performance over the years. Some key results are reported in Refs. 189–191, 193, 196, and 261. The main skepticism faced by the SOH modulators comes from their long-term photochemical and photothermal stability. Recent research results reported in Refs. 195 and 262 have shown long-term stability of SOH devices following Telecordia standards. These early experiments have shown that in storing the SOH modulators at elevated temperatures of 85°C, the degradation of the electro-optic activity converges to a stable level where the $V_{π} \cdot L$ -product increases by $< 15 %$ after 2400 h.

The limitations of poled organic materials can be overcome by substituting them with crystalline organic materials, which are inherently resilient to higher temperatures with good photochemical stability and do not require any poling.¹⁹⁹ The electro-optic coefficients of the organic crystals are smaller (typically $n^{3} r < 500 pm / V$ )²⁶³ than those of the poled organic polymers.¹⁹⁰ The integration of organic crystals requires growth to functionalize the silicon waveguides.¹⁹⁸^,¹⁹⁹ An N-benzyl-2-methyl-4-nitroaniline crystal has been deposited on an SOI waveguide to demonstrate an MZM that could operate at $12.5 Gb / s$ with a modulation efficiency of $1.2 V \cdot cm$ and a loss of 16 dB in the phase modulator with a 1.5 mm length.¹⁹⁹

Typically, the analogue bandwidth of current SOH modulators is limited to $\sim 25 GHz$ by the finite conductivity of the doped silicon slabs that provide an electrical contact with the rails of the slot waveguide.¹⁹⁰ These bandwidths may be improved to more than 100 GHz by exploiting optimized waveguide designs that rely on multi-step doping profiles.²⁵⁹ To that end, doped silicon slabs have also been replaced by BTO to feed the modulating RF signal to the EO material in the slot waveguide.²⁰⁰ This so-called capacitively coupled SOH MZM delivered a bandwidth of 65 GHz, which was sufficient to produce a $100 - Gb / s$ OOK signal.²⁰⁰ The modulator had a modulation efficiency of $0.13 V \cdot cm$ ; the loss from the phase shifter section is not reported. Yet another variant of the SOH modulator is the plasmonic-organic hybrid (POH) modulator,²⁵⁸^,²⁶⁴^–²⁶⁹ where the silicon slot waveguide is replaced by a metal plasmonic slot waveguide to provide even higher optical confinement.²⁵⁸^,²⁶⁵ The deposition of an organic electro-optic material on the metal slot waveguide leads to compact high-speed devices with bandwidths of hundreds of gigahertz.²⁶⁶^,²⁷⁰ POH modulators are compact with typical lengths of a few microns and offer a low-energy consumption of a few tens of fJ/bit along with ultra-low voltage-length products of typically $\sim 0.005 V \cdot cm$ ²⁵⁸—nearly an order of magnitude lower than those of classical SOH modulators. The obvious limitation of the POH modulators is the high propagation loss in the plasmonic slot-waveguide section with typical values of $200 dB / mm$ .²⁰⁰^,²⁵⁸ Despite the high efficiencies, this leads to substantial $π$ -voltage-loss-products of the order of $10 V \cdot dB$ .¹⁸⁸

Table 4 provides a summary of typical modulation efficiencies, losses, speeds, and energy consumption for organic electro-optic modulators in SiPh. When compared with the other Pockels modulators, the organic electro-optic modulators provide the best modulation efficiency with a reported value of $0.032 V \cdot cm$ .¹⁹⁰ Organic electro-optic modulators have shown up to $100 Gb / s$ ¹⁹⁶ operation and sub-fJ/bit energy consumption.¹⁹²Figure 3(d) represents the typical cross section of organics modulators in SiPh.

3.4 III–V Semiconductors

The integration of III–V semiconductors with SiPh platforms is a well-established research field, as it provides a viable route for the integration of laser sources with SiPh PICs.²⁷¹^–²⁷⁵ Direct bonding,²⁷² BCB-aided adhesive bonding,²⁷¹ III–V/Si flip-chip bonding,²⁷⁵ and transfer printing²⁷⁴ are some of the most established bonding mechanisms for III–V/Si integration. Demonstrations of III–V integration with advanced SiPh platforms have been reported.²⁷⁶^,²⁷⁷ Demonstrations of epitaxial growth of III–V on Si have also been reported despite the large lattice mismatch between Si and III–V (for example, InP has 8% lattice mismatch with Si).²⁷⁸^,²⁷⁹ The integration of III–V on silicon also provides a route for the implementation of efficient high-speed modulators because they provide (a) a large electron-induced refractive-index change, (b) a high electron mobility, and (c) a low carrier-plasma absorption.¹⁶⁶

The reported implementations of III–V/Si modulators typically use a MOS (SISCAP) modulator architecture.¹⁶¹^–¹⁶³ In these modulators, n-doped III–V material, for example, InGaAsP, is bonded to a p-doped Si layer with an insulating layer separating the two.¹⁶¹^–¹⁶³ This results in a SISCAP architecture, where the insulating layer acts as a capacitor. A change in the refractive index takes place due to the charge accumulation due to the biasing of the doped silicon and III–V layer. According to Drude’s model, the plasma dispersion induced refractive index change $- Δ n$ is inversely proportional to the effective masses of the electrons and holes.⁶¹^,⁸⁹ As compared to the electron mass of Si, the lighter electron mass of n-doped III–V results in a 17 times stronger electron-induced refractive index change.¹⁶¹ Furthermore, an n-doped III–V provides a larger ratio of $- Δ n$ to $Δ k$ , where $Δ k$ is the change in the absorption coefficient,¹⁶¹ resulting in a phase modulator with reduced spurious intensity modulation (“pure-phase” modulation). Similarly, p-doped silicon provides larger $- Δ n / Δ k$ than p-doped III–Vs for carrier concentrations below $10^{19} {cm}^{- 3}$ .¹⁶¹^–¹⁶³ Therefore, a hybrid III–V/Si MOS modulator brings the best of III–V and Si together. Consequently, this approach offers modulators with a 3 to 5 times better modulation efficiency compared to all-silicon MOS modulators and a phase shifter loss that is significantly lower than in all-silicon MOS modulators.¹⁶¹^,¹⁶³

In one report, an $InGaAsP / {Al}_{2} O_{3} / Si$ MOS structure provided a modulation efficiency of $0.047 V \cdot cm$ and a phase shifter loss of $\sim 19.4 dB / cm$ .¹⁶¹ In another report, an $InGaAsP / {SiO}_{2} / Si$ MOS structure provided¹⁶³ a modulation efficiency of $0.09 V \cdot cm$ with an absorption loss of $26 dB / cm$ in the phase shifter. Both demonstrations show an impressive modulation efficiency. But, the electro-optic cut-off frequency is rather limited due to the large oxide capacitance in the carrier accumulation mode of operation.¹⁶¹^,¹⁶³

One possible approach to break the trade-off between the high-speed operation and high modulation efficiency banks on operating the III–V on Si MOS phase shifter in reverse bias.¹⁶⁵^,²⁸⁰ The III–V on Si MOS modulator that is operated in reverse bias is architecturally similar to the forward biased III–V on Si modulator.¹⁶¹^,¹⁶³^,¹⁶⁵^,²⁸⁰ For a given thickness of the oxide layer, the reverse biased III–V on Si phase shifter has a reduced depletion capacitance as compared to the accumulation capacitance.¹⁶⁵^,²⁸⁰ The combined plasma dispersion effect and FK effect in the reverse biased III–V on Si MOS phase shifter ensure a modulation efficiency that is comparable to that in the accumulation mode while ensuring a low-loss operation due to the limited hole density in the n-doped InGaAsP layer of the modulator.¹⁶⁵^,²⁸⁰ A III–V on Si MOS modulator with a $250 - μ m$ -long phase shifter and a 9-nm-thick oxide layer has been reported with a modulation efficiency of $0.11 V \cdot cm$ .¹⁶⁵ As compared to the carrier accumulation MOS, the reverse biased MOS provides a $3.3 \times$ lower depletion capacitance, hence paving the way for a $3.3 \times$ improvement in modulation bandwidth and energy consumption per bit. The implementation of III–V on Si MOS modulators is not limited to MZIs only.¹⁶⁴ By implementing a III–V on Si MOS modulator in a racetrack configuration (implementing III–V on Si MOS modulators in a ring is challenging due to the long taper length needed for the III–V on Si hybrid waveguide), the energy consumption of a 40-GHz (3-dB bandwidth) modulator has been improved by a factor of 3.7 as compared to the III–V on Si MZMs, while delivering a modulation efficiency of $0.064 V \cdot cm$ .¹⁶⁴ The $100 - μ m$ -long phase shifter section of the modulators comprised a thin aluminum oxide gate layer separating the n-type III–V and the p-doped Si layer. Recently, a proof-of-concept, taper-less integration of a few tens of nanometers thick III–V layer with Si has been demonstrated to reduce the footprint and loss of the device²⁸¹ without compromising the modulation efficiency of the III–V on Si MOS capacitor.

Apart from phase modulators, EAMs have been reported by the bonding of III–V QWs with silicon.¹⁴⁰^,²⁸² These EAMs use a PIN architecture, where the application of a bias voltage changes the optical absorption of the intrinsic multiple QWs due to the QCS effect.²⁸² A segmented electrode, comprising a low-impedance active modulation section cascaded by a high-impedance passive section, provides high-bandwidth operation while ensuring low reflection and good modulation efficiency.¹⁴⁰ A $> 67 GHz$ bandwidth hybrid III–V on silicon EAM has been demonstrated using this scheme.¹⁴⁰ In the O-band, this modulator has an IL of 4.9 dB, and it shows $> 9 dB$ of dynamic ER for $50 Gb / s$ operation over a 16-km-long optical fiber link.

Figure 4 represents the typical cross sections of III–V on Si phase modulators and EAMs. This figure also summarizes the routes to integrate III–V on Si. Table 5 presents a summary of the typical and best-reported values for the modulation efficiencies, losses, data rates, and energy consumption for forward and reverse biased III–V on Si phase modulators as well as for III–V on Si EAMs. III–V on Si modulators have shown an impressive modulation efficiency and low-loss operation, but so far experimental demonstrations of high-speed operation ( $\sim 100 Gb / s$ ) remain elusive.

Figure 4.Representative cross sections of (a) III–V on Si phase modulator and (b) III–V on Si EAM.

Table 5. Typical and state-of-the-art performance matrix for the III–V on Si high-speed modulators in SiPh. The parentheses contain the best-reported result for a performance attribute.

Table 5. Typical and state-of-the-art performance matrix for the III–V on Si high-speed modulators in SiPh. The parentheses contain the best-reported result for a performance attribute.


Operation	Modulation efficiency $V_{π} \cdot L$ ( $V \cdot cm$ )	Loss (dB/cm)	Length of phase shifter (mm)	Data ratea(Gb/s)	Energy/bit (fJ/bit)
Forward biased III–V on Si as a phase modulatord	< $0.1$ (0.047¹⁶¹)	< $30$ (19.4¹⁶¹)	< $0.5$	> $30$ (32¹⁶³^,b)	$\geq 100$
Reverse biased III–V on Si as a phase modulatord	< $0.2$ (0.11¹⁶⁴)	(28²⁸⁰)	< $0.5$	200c^,²⁸⁰	$\leq 100$ ²⁸⁰
Operation	FoM ER/IL	Loss (dB)	Modulator length (mm)	Data ratea (Gb/s)	Energy/bit (fJ/bit)
III–V on Si as an amplitude modulatord	$\sim 2$ (2¹⁴⁰)	(4.9¹⁴⁰)	$\leq 0.1$	$\sim 50$ (50)¹⁴⁰	-

3.5 2D Materials

Atomically thick 2D materials, the most prominent graphene, have received considerable interest in the last decade to implement efficient modulators by integration with Si/SiN PICs.¹^,¹⁵³^–¹⁶⁰^,²⁰¹^–²⁰⁸ The implementation of graphene-based modulators in SiPh involves the transfer of the graphene layer on a Si or SiN waveguide.¹ Mature and wafer-scale chemical vapor deposition is the widely adopted scheme to deposit graphene on a variety of metallic and dielectric substrates.²⁸³^–²⁸⁵ The transfer of the graphene layer on a Si or SiN waveguide is performed after delaminating graphene from the substrate while adding a polymer carrier to handle the graphene film.¹⁵⁴^,¹⁵⁹ Recently, microtransfer printing technology has shown promising results to transfer graphene to the target substrate in an automatic fashion.¹⁵⁹ A single graphene layer, which is only a fraction of a nanometer thick, can absorb 2.3% of light²⁸⁶ with a wavelength ranging from the visible to THz wavelengths (graphene is a gapless material). Furthermore, graphene has a very high electron mobility of $> 100,000 {cm}^{2} \cdot V^{- 1} \cdot s^{- 1}$ (silicon has a carrier mobility of $1400 {cm}^{2} \cdot V^{- 1} \cdot s^{- 1}$ ).²²⁸^,²⁸⁷^,²⁸⁸ These two properties enable the implementation of high-speed electro-absorptive¹⁵³ or electro-refractive²⁰¹ modulators through the integration of graphene with SiPh ICs.

The two prominent types of graphene modulators in SiPh comprise a SiPh rib waveguide, which is either loaded with a single layer or a double layer of graphene¹⁵³^,¹⁵⁶ (see Fig. 5). The operating principle of these modulators relies on the charging and discharging of a capacitor. A single-layer graphene modulator comprises a graphene loaded Si rib waveguide with a doped slab region.¹⁵³ A few nm thick dielectric spacer, such as ${SiO}_{2}$ , ${Al}_{2} O_{3}$ , or hBN, separates the waveguide and the graphene layer to form a capacitor.¹ The first reported graphene modulator¹⁵³ had a 4-dB ER and relied on a single-layer approach. The $25 - μ m^{2}$ EAM provided 1 GHz operation, limited by the RC time constant, and an electroabsorption modulation of $0.1 dB / μ m$ .¹⁵³ The absorption in graphene is dependent on the bias voltage.¹ This voltage tunes the Fermi level of graphene to enable or inhibit the interband transitions by excitation of electrons through the incident photons.²⁰¹^,²⁸⁹ This change in absorption due to carrier accumulation in the graphene sheet results in modulation of light propagating in the waveguide. The doped Si waveguide in the single-layer graphene modulator is a source of loss, and it requires an implantation step.¹⁵³^,¹⁵⁶ Double-layer graphene modulators remedy these limitations.¹⁵⁶ They are separated by a dielectric layer that resides on top of a completely passive waveguide. (This architecture does not require any doping of the waveguide slab.)¹⁵⁶ The first double-layer graphene modulator reported 1 GHz bandwidth and an electroabsorption modulation of $0.16 dB / μ m$ .¹⁵⁶ The $40 - μ m$ -long modulator provided a 6-dB ER and required a 5-V driving voltage. One of the first multi-Gb/s graphene-silicon modulators¹⁵⁷ relied on a single-layer graphene architecture that provided a 5.2-dB ER for a $50 - μ m$ -long EAM operating at $\sim 2.5 V$ . At $10 Gb / s$ , the modulator provided a modulation efficiency of $1.5 dB / V$ . The ON state loss is 3.8 dB with a power consumption of about $350 fJ / bit$ . Another result reports a double-layer graphene RM¹⁵⁸ using a critical coupling effect in a $40 - μ m$ SiN ring. In this implementation, a 50-nm thick ${Al}_{2} O_{3}$ layer separates the two graphene layers. By biasing, the change in the transparency of the graphene capacitor led to the modulation of the optical signal. The reduced capacitance resulting from the thick spacer between the graphene layers led to a modulator showing 30 GHz bandwidth with a modulation efficiency of $1.5 dB / V$ but required a $- 30 - V$ DC bias and $7.5 V_{p - p}$ .¹⁵⁸ The modulator could transmit $22 Gb / s$ while consuming $800 fJ / bit$ . A positive chirp of a graphene EAM is an interesting property.¹⁶⁰ This feature is useful in compensating for the chromatic dispersion in an optical transmission link for the transmission of $10 - Gb / s$ without any optical signal to noise ratio penalty.¹⁶⁰

Figure 5.Representative cross sections of (a) single-layer graphene phase/amplitude modulator and (b) double-layer graphene amplitude/phase modulator in SiPh.

Apart from amplitude modulation, it is also feasible to use graphene for phase modulation.²⁰¹^–²⁰⁸ Phase modulation is more exciting for the encoding of complex modulation formats such as QPSK. A single-layer graphene architecture, in which the graphene layer is separated from the silicon waveguide by a thin dielectric spacer layer, acts as a phase modulator by shifting the Fermi level of graphene.²⁰¹^,²⁰⁵^,²⁰⁷^,²⁹⁰^,²⁹¹ A single-layer graphene phase modulator of $300 μ m$ length is integrated on a Si MZI and showed a modulation efficiency of $0.28 V \cdot cm$ . The modulator delivered an ER of 35 dB, an EO bandwidth of 5 GHz, and a loss of $236 dB / cm$ .²⁰¹ With a $2 - V_{p - p}$ drive, the transmission of $10 Gb / s$ over a 50-km fiber span is demonstrated. The higher loss in the modulator is associated with the suboptimal transfer of graphene.²⁰¹ The quality of graphene, which is typically determined by the scattering time and is related to the carrier mobility, plays a detrimental role in the performance of graphene modulators.¹ Typically, scattering time of $> 100 fs$ is required to implement energy-efficient graphene modulators with a high ER.¹ Achieving $10,000 {cm}^{2} \cdot V^{- 1} \cdot s^{- 1}$ graphene carrier mobility, which roughly corresponds to 300 fs scattering time, upon the complete modulator integration process would be ideal. Accomplishing this would lead to extremely low IL.²⁸⁹ In perspective, the combination of low IL in a dual-layer graphene structure, the high graphene electro-absorption, or electro-refractive efficiency would lead to a modulator with a good FoM.¹ It is important to mention that graphene can be used for detection,¹ and this makes graphene suitable for a telecommunication platform on a passive integrated circuit operating in several telecommunications bands.

Inspired by the promising results shown by graphene, other 2D materials such as tungsten disulfide ( ${WS}_{2}$ ) and molybdenum disulfide ( ${MoS}_{2}$ ) have also been integrated with SiPh. Results show phase change relative to the change in absorption for these materials at telecom wavelengths when integrated with SiN.²⁰⁴

Figure 5 represents typical cross sections of a single layer graphene modulator (a) and a double layer graphene modulator (b) in SiPh. Table 6 provides the current state of high-speed phase and amplitude modulators in SiPh by integrating 2D materials. The currently reported performances of 2D modulators, in particular graphene modulators, are mostly limited by technological immaturity and not by conceptual limits. Graphene requires more development to reach the best performances. More specifically, graphene needs to preserve the high carrier mobility after the integration in the photonic circuit. This preservation is not the case yet. By achieving a high level of technological maturity, graphene has the potential to provide devices that can work over a wide range of wavelengths due to its gapless band structure, miniaturized devices due to its large EO efficiency, feasibility for BEOL integration with the SiPh fabrication process, and a possibility to offer a complete platform for communication applications, as graphene possesses properties for efficient modulation and detection.

Table 6. Typical and state-of-the-art performance matrix for graphene on Si high-speed modulators in SiPh. The parentheses contain the best-reported result for a performance attribute.