PIN diode
A PIN diode is a semiconductor diode with a p-i-n structure, consisting of a p-type region, a high-resistivity intrinsic (i) region, and an n-type region, designed to operate as a current-controlled resistor at radio frequency (RF) and microwave frequencies.[1][2] The intrinsic region, typically several micrometers wide, provides low capacitance in reverse bias and enables conductivity modulation in forward bias, distinguishing it from standard p-n junction diodes.[1] In operation, under forward bias, minority carriers are injected into the intrinsic region, creating a stored charge that reduces the diode's series resistance (R_S) proportionally to the forward current (I_F) and carrier lifetime (τ), following the relation R_S ≈ W² / [(μ_n + μ_p) I_F τ], where W is the intrinsic region width and μ_n, μ_p are electron and hole mobilities.[1][2] In reverse or zero bias, the diode behaves as a parallel combination of a low-capacitance junction (C_T ≈ ε A / W, with ε as permittivity and A as junction area) and high parallel resistance (R_P), supporting high breakdown voltages due to the wide depletion layer in the intrinsic region.[1] This dual-mode behavior allows fast switching speeds, often in the microsecond range, limited by the carrier lifetime τ (typically 1–10 μs in silicon devices).[2][1] PIN diodes are essential in high-frequency circuits, serving as RF switches in series or shunt configurations for single-pole single-throw (SPST) or single-pole double-throw (SPDT) designs, with low insertion loss (e.g., IL = 20 log(1 + R_S / (2 Z_0)) in 50 Ω systems) and high isolation.[1][2] They also function in attenuators for automatic gain control (AGC) and signal leveling, phase shifters for beam steering in phased-array antennas, and limiters to protect sensitive components from high-power signals, handling peak powers up to kilowatts in pulsed applications.[1][2] Additionally, their photodetection properties make them suitable for optical-to-electrical conversion in light-absorbing roles.[3]Physical Structure
Layer Composition
The PIN diode features a layered structure comprising a p-type semiconductor region, an intrinsic (undoped) region, and an n-type semiconductor region, forming the acronym PIN. The p-type layer is heavily doped with acceptor impurities, such as boron in silicon, to achieve high conductivity and facilitate ohmic contacts, with typical doping concentrations ranging from $10^{18} to $10^{20} cm^{-3}. Similarly, the n-type layer is heavily doped with donor impurities, like phosphorus or arsenic in silicon, at comparable concentrations of $10^{18} to $10^{20} cm^{-3}, ensuring low resistance for current flow.[4][4] The intrinsic region, positioned between the p- and n-type layers, is intentionally undoped or lightly doped to minimize free carrier density, with concentrations typically below $10^{14} cm^{-3}, which separates the heavily doped regions and defines the device's key electrical properties.[4] Common materials for PIN diodes include silicon (Si) for cost-effective, general-purpose applications due to its mature fabrication processes and adequate performance up to microwave frequencies. For high-frequency RF and microwave uses, wider-bandgap materials like gallium arsenide (GaAs) are preferred because of their higher electron mobility (approximately 8500 cm^2/V·s compared to 1400 cm^2/V·s in Si), enabling faster carrier transport and reduced losses at frequencies above 10 GHz. Indium phosphide (InP) is also utilized, particularly in optoelectronic and high-speed RF contexts, owing to its electron mobility (5400 cm^2/V·s) and suitable bandgap (1.34 eV) for low-noise, high-frequency operation up to millimeter waves.[5][6] Layer thicknesses are optimized for specific performance trade-offs; the intrinsic region typically measures 10–100 μm in RF applications, where thinner layers reduce forward-bias resistance but thinner profiles can increase capacitance, while the p- and n-type layers are much shallower, often 1–5 μm, to maintain high doping uniformity without compromising breakdown strength.[7][8] These dimensions directly influence device metrics such as breakdown voltage and parasitic capacitance, with the intrinsic layer's width playing a pivotal role in achieving low capacitance for high-frequency isolation. A cross-sectional diagram of the PIN structure would depict the vertical stacking of these layers, with the intrinsic region as the dominant central band flanked by the thinner, highly conductive p- and n-regions, often topped with metal contacts for electrical interfacing.[7]Fabrication Techniques
The fabrication of PIN diodes begins with the selection of a high-resistivity n-type silicon substrate, typically float-zone material with resistivity exceeding 8 kΩ·cm, to serve as the base for the intrinsic region and minimize parasitic capacitance.[9] In the 1960s and early 1970s, early PIN diodes were produced using planar diffusion techniques, where dopants were introduced through predeposition and drive-in steps to form the p+ and n+ regions on a lightly doped substrate, enabling reliable junction formation while leveraging silicon dioxide masking for precise control.[10] This method, rooted in the broader planar process developed in the late 1950s, allowed for the creation of stable, isolated junctions suitable for initial applications in photodetection and switching.[11] Modern fabrication has shifted toward epitaxial growth techniques to achieve superior purity and thickness control in the intrinsic (i) region, particularly for high-performance RF and optoelectronic devices.[12] The p+ and n+ regions are commonly formed via boron or phosphorus diffusion doping or ion implantation, followed by high-temperature annealing (typically 900–1100°C) to activate dopants and anneal out implantation-induced lattice damage.[13] For the i-layer, methods such as metalorganic chemical vapor deposition (MOCVD) or molecular beam epitaxy (MBE) are employed to deposit undoped or low-doped epitaxial layers (often 1–50 μm thick) on the substrate, ensuring abrupt interfaces and low defect densities essential for carrier lifetime. In some silicon-based processes, epi-ready wafers are used to grow a thin intrinsic epitaxial layer directly, avoiding the need for deep diffusion into the bulk.[9] Following doping and growth, surface passivation is applied using thermal oxidation or plasma-enhanced chemical vapor deposition (PECVD) of silicon dioxide or nitride layers to suppress surface recombination and leakage currents.[14] Metallization contacts (e.g., aluminum or nickel) are then patterned via photolithography and etching to connect the p+ and n+ regions, completing the device structure.[15] Key challenges in PIN diode fabrication include maintaining uniformity in the i-region thickness across wafers and minimizing defects that could degrade carrier transport.[12] During epitaxial growth, autodoping—where substrate dopants diffuse into the growing i-layer at high temperatures (above 1000°C)—poses a significant issue, potentially narrowing the effective intrinsic width and increasing unwanted conductivity; this is mitigated by using low-pressure growth conditions or dopant segregation techniques.[16] Scaling these processes for high-volume production requires optimizing throughput in MOCVD or MBE systems while preserving epitaxial quality, often achieved through automated wafer handling and in-situ monitoring.[17]Operation Principles
Bias Conditions
In forward bias, a PIN diode operates by injecting minority carriers (holes from the p-region and electrons from the n-region) into the intrinsic (I) region, which fills with a high concentration of free carriers forming a conductive plasma that significantly reduces the I-region's resistivity.[8] This plasma enables the diode to function as a low-resistance path, with the forward voltage drop typically around 0.7 V for silicon devices at moderate currents.[18] The forward current I under low-level injection follows the Shockley diode equation: I = I_s \left( e^{V / V_T} - 1 \right) where I_s is the saturation current, V is the applied voltage, and V_T is the thermal voltage (\approx 25 mV at room temperature).[7] As the forward bias increases, the diode transitions from low-level injection (where injected carrier density is much less than the majority carrier density) to high-level injection, where the plasma density becomes comparable to or exceeds the background doping, leading to conductivity modulation that further lowers the I-region resistance.[8] At high forward currents exceeding 10 mA, the series resistance drops markedly due to the enhanced plasma formation and increased carrier mobility effects, enabling efficient current flow with minimal voltage overhead.[18] Doping levels in the p- and n-regions influence the onset of these injection thresholds by affecting carrier injection efficiency.[7] Under reverse bias, the PIN diode's I-region becomes depleted of free carriers, swept by the electric field to create a high-resistivity barrier that blocks current flow, resulting in a low-conductivity off-state.[8] The depletion width d expands with increasing reverse voltage, and the breakdown voltage is primarily determined by the I-layer width, as silicon's dielectric strength limits the field before avalanche occurs (approximately 400 V per mil of I-region thickness).[7] The reverse-bias capacitance C behaves like that of a parallel-plate capacitor: C = \frac{\varepsilon A}{d} where \varepsilon is the permittivity of the semiconductor, A is the junction area, and d is the depletion width, which remains relatively constant beyond punch-through for wider I-regions.[18]Carrier Dynamics
In the intrinsic (I) region of a PIN diode, charge carriers exhibit dynamic behavior governed by diffusion and recombination processes, particularly during transient or high-frequency operation. The carrier lifetime, denoted as τ, represents the average time a minority carrier exists before recombining and typically ranges from 1 to 100 μs in silicon PIN diodes, depending on material quality and doping control.[19][18] This lifetime directly influences the recovery time after forward bias, as longer τ values enable higher stored charge but prolong the return to low-conductivity states. Diffusion of injected carriers across the I-region, with a diffusion length L = √(D τ) where D is the ambipolar diffusion coefficient (approximately 10-20 cm²/s in silicon), determines the spatial distribution and transit time, typically on the order of nanoseconds to microseconds for I-region widths of 10-300 μm.[7][20] Under forward bias, the conductivity of the I-region is modulated by the injection of minority carriers from the p+ and n+ regions, creating a high-density plasma that significantly reduces resistance. The average carrier density n in the I-region can be approximated as n ≈ I_f τ / (q A W), where I_f is the forward current, q is the elementary charge, A is the junction area, and W is the I-region width; this relation arises from the stored charge Q = I_f τ balanced across the volume A W.[1][7] For typical values (e.g., I_f = 10 mA, τ = 4 μs, W = 250 μm, A = 10^{-4} cm²), n reaches ~10^{15}-10^{16} cm^{-3}, yielding conductivities up to 10-100 S/cm and series resistances as low as 0.1-1 Ω. This modulation enables the PIN diode's variable resistance characteristic, which is more pronounced than in PN diodes due to the wide, low-doped I-region allowing uniform carrier filling without significant junction field effects.[2][1] Switching transients in PIN diodes are dominated by carrier dynamics: turn-on is limited by the diffusion time for carriers to fill the I-region, roughly t_on ≈ W² / (2 D), while turn-off relies on recombination to clear the stored charge. The reverse recovery time t_r, critical for pulsed or high-speed applications, is approximated by t_r ≈ τ ln(1 + I_f / I_r), where I_r is the reverse current; this logarithmic dependence highlights how higher forward currents extend recovery due to increased stored charge.[7] For example, with τ = 1 μs and I_f / I_r = 100, t_r ≈ 5 τ, emphasizing the need for tailored τ in fast-switching designs.[18] At high frequencies, such as in microwave regimes, carrier dynamics exhibit specific behaviors: the skin effect is negligible below X-band (around 10 GHz) because RF signals penetrate deeply into the semiconductor due to the modulated low resistance and high carrier mobility, unlike in metals.[18] However, the plasma frequency of the injected carriers, ω_p = √(n e² / (ε m^)) where ε is permittivity and m^ is effective mass (typically 10^{13}-10^{14} rad/s or 1-10 THz for n ~10^{16} cm^{-3}), influences microwave propagation by creating a dispersive medium; below ω_p, the I-region acts as a lossy conductor, while proximity to resonance can enhance attenuation or phase shifts in RF applications.[8]Electrical Characteristics
I-V Behavior
The current-voltage (I-V) characteristic of a PIN diode in forward bias follows an exponential relationship at low currents, akin to the Shockley diode equation I = I_s \left( \exp\left( \frac{qV}{n k T} \right) - 1 \right), where I_s is the saturation current, q is the elementary charge, V is the applied voltage, n is the ideality factor (typically 1 to 2), k is Boltzmann's constant, and T is the absolute temperature.[7] This results in a rapidly increasing current with voltage, leading to high forward conductance once sufficient bias is applied, as the injected carriers fill the intrinsic (I) region and reduce its resistivity.[18] In reverse bias, the current remains near zero (typically less than 10 μA at rated reverse voltage) until the breakdown voltage is reached, providing effective blocking.[1] At high forward currents, corresponding to the high-injection regime, the I-V curve transitions from exponential to nearly linear behavior due to the dominance of the series resistance R_s in the I-region. This resistance arises from the finite conductivity of the plasma formed by injected carriers and is approximated as R_s \approx \frac{W}{q \mu n}, where W is the I-region width, \mu is the average carrier mobility, and n is the carrier density (proportional to forward current and lifetime).[18] For example, typical values show R_s dropping to around 0.1 Ω at 1 A forward bias, enabling low-loss conduction.[18] Compared to a conventional PN junction diode, the PIN diode's wider I-region increases forward resistance at low currents because carriers must diffuse across the undoped layer before significant conduction occurs, though the overall I-V shape remains similar at DC.[1] The forward voltage exhibits a negative temperature coefficient of approximately -2 mV/°C, consistent with silicon diode behavior, while the ideality factor remains in the range of 1-2 across typical operating temperatures.[21] PIN diodes display a softer knee in the forward I-V curve owing to the gradual buildup of carrier plasma in the I-region, contrasting with the sharper turn-on of PN junctions.[22]Capacitance and Switching
The junction capacitance of a PIN diode, C_j, is given by C_j = \epsilon A / W_d, where \epsilon is the permittivity of the semiconductor, A is the junction area, and W_d is the depletion region width.[8] This capacitance arises primarily from the intrinsic (I) region under reverse bias, where the depletion layer extends across the lightly doped I-layer, resulting in lower capacitance compared to PN diodes due to the wider effective spacing between charge layers.[18] Under reverse bias, the depletion region extends across the intrinsic I-region, with width W_d approximately equal to the I-region width W for V_r greater than a few volts, resulting in nearly voltage-independent capacitance.[1] In forward bias, the capacitance remains low due to the high-density carrier plasma in the I-region, which screens the electric field and effectively shorts the junction, minimizing capacitive effects and allowing the device to behave primarily as a low-resistance path.[7] Key switching performance metrics for PIN diodes include an on-state resistance R_{on} typically below 1 Ω at forward currents of 10–100 mA, an off-state capacitance C_{off} under 1 pF at reverse biases of 5–10 V, and transition times less than 1 ns for high-speed variants optimized with thin I-layers (e.g., 5–10 μm).[23] These parameters enable rapid state changes between low-loss conduction and high-isolation blocking, with the off-state isolation limited by C_{off} and parasitic series resistance. A common figure of merit for switching suitability is the cutoff frequency f_c = 1 / (2\pi R_s C_{off}), where R_s is the series resistance, often exceeding 10 GHz for RF-grade devices, indicating effective operation up to microwave frequencies before parasitic effects degrade performance.[8] Compared to conventional PN diodes, PIN diodes achieve faster switching speeds owing to the I-region, which allows independent control of stored charge lifetime and depletion dynamics without the minority carrier storage time limitations of PN junctions; however, this comes at the cost of a higher forward voltage drop (typically 0.8–1.5 V) due to the ohmic drop across the undoped I-layer.[24] The depletion width modulation under reverse bias, as detailed in bias conditions, further supports this enhanced switching by enabling complete I-region depletion at modest voltages, typically 5–20 V depending on I-layer thickness.[18]RF and Microwave Applications
Switches
PIN diodes serve as high-speed switches in RF and microwave systems by leveraging their bias-dependent impedance characteristics to control signal paths with minimal distortion. In the forward-biased "on" state, the diode presents a low series resistance, typically around 0.5 Ω, enabling a low-loss RF transmission path.[1] This resistance results from carrier injection into the intrinsic region, which effectively reduces the I-layer width for RF signals.[1] Conversely, in the reverse-biased "off" state, the diode behaves as a low-capacitance element, usually less than 0.5 pF, providing effective isolation by presenting high impedance to RF currents.[1] Common configurations exploit these properties for versatile switching. Series-shunt topologies, often used in transmit/receive (T/R) switches, combine a forward-biased series diode for signal passage with a reverse-biased shunt diode to ground for enhanced isolation in the off path.[2] Single-pole double-throw (SPDT) designs typically incorporate similar compound arrangements, such as ELL or TEE configurations, to achieve broadband operation across frequency bands.[2] Performance metrics highlight the suitability of PIN diode switches for demanding applications. They commonly deliver isolation exceeding 40 dB and insertion loss below 0.5 dB up to 10 GHz, while handling over 1 W of continuous wave (CW) power.[1] These attributes support reliable operation in high-frequency environments with fast switching times on the order of microseconds.[1] In practical use, PIN diode switches enable antenna selection in mobile radios and T/R switching in radar systems, where rapid transitions between modes are critical for system efficiency.[1] The adoption of gallium arsenide (GaAs) PIN diodes has advanced their application to millimeter-wave regimes up to 100 GHz, offering improved speed and power handling for emerging high-frequency needs.[25] Post-2020 developments have integrated these diodes into 5G beamforming arrays, enabling low-latency switching to support dynamic beam steering in sub-6 GHz and mm-wave massive MIMO setups.[26]Attenuators and Limiters
PIN diodes serve as key components in variable attenuators for RF and microwave systems, where their bias-dependent resistance enables precise control of signal amplitude. By applying forward bias, the PIN diode's series resistance R_{\text{pin}} can be modulated from high values (tens of kΩ in reverse bias, providing minimal attenuation) to low values (fractions of an Ω), achieving attenuation ranges of 0 to 60 dB or more.[7] This variable resistance arises from the injection and recombination of carriers in the intrinsic layer under bias, as detailed in the device's I-V characteristics. Common circuit configurations include π-networks, which use two series PIN diodes and one shunt diode for balanced attenuation, and T-networks, featuring one series and two shunt diodes to minimize reflections across a broad frequency range.[27] These setups are favored for their ability to maintain low insertion loss (<1 dB) at zero attenuation while supporting continuous or stepped control via DC bias current.[28] The attenuation in a typical shunt-configured PIN diode attenuator is given by the formula: A = 20 \log_{10} \left(1 + \frac{Z_0}{2 R_{\text{pin}}}\right) where Z_0 is the characteristic impedance (typically 50 Ω) and R_{\text{pin}} varies with forward bias current.[7] For example, at low bias where R_{\text{pin}} \approx 5 \, \Omega, attenuation approaches 15.6 dB, scaling higher as resistance increases under reduced or reverse bias. This equation highlights the logarithmic dependence on resistance, allowing fine-tuned signal leveling in applications like radar systems and wireless transmitters.[29] In RF limiters, PIN diodes provide passive protection against high-power incidents by self-biasing into forward conduction when input signals exceed approximately 10 dBm, effectively clamping the output voltage to around 0.7 V—the forward voltage drop of the diode.[30] This mechanism reflects excess power back to the source via the diode's low-resistance state in the intrinsic layer, preventing damage to downstream components. Recovery time, determined by the minority carrier lifetime, is typically less than 1 μs (often in the nanosecond range with gold doping), enabling rapid return to high-impedance mode for subsequent low-level signals.[31] PIN diode limiters exhibit strong performance metrics, including VSWR below 1.5:1 and operational bandwidths spanning 1 to 18 GHz, making them suitable for broadband receiver front-ends.[32] They are commonly deployed to safeguard low-noise amplifiers (LNAs) in radar and communication receivers by limiting peak input powers while maintaining low insertion loss (<0.5 dB) under normal conditions. Compared to Schottky diode limiters, PIN variants offer superior power tolerance due to the wider intrinsic layer, which dissipates heat more effectively; PIN devices can handle CW powers up to 100 W without degradation, far exceeding typical Schottky ratings of a few watts.[30] Recent developments have incorporated PIN limiters for dynamic range control in reconfigurable receivers for 5G cellular infrastructure and military applications, enhancing protection against variable interference in high-frequency bands.[33]Optoelectronic Applications
Photodetectors
PIN photodiodes function as light-sensitive detectors by converting incident photons into electrical signals through the photovoltaic effect. Under reverse bias, the applied voltage widens the depletion region across the intrinsic (I) layer, enabling rapid separation and collection of photogenerated electron-hole pairs with minimal recombination, which supports high-speed operation.[34] The quantum efficiency (η), defined as the ratio of photogenerated carriers to incident photons, typically reaches 0.8-0.9 in the visible spectrum for silicon-based PIN structures, reflecting efficient absorption and collection in the I-layer.[3] This wide I-region facilitates complete carrier collection, enhancing overall detector performance.[35] The responsivity (R) of a PIN photodiode, which measures the output photocurrent per unit optical input power, is given by the formula R = \eta \frac{q \lambda}{h c}, where q is the elementary charge, \lambda is the wavelength, h is Planck's constant, and c is the speed of light.[36] For near-infrared applications, such as at 850 nm, typical responsivity values are around 0.5 A/W, balancing high quantum efficiency with material absorption properties in GaAs or silicon devices.[37] The bandwidth, often transit-time limited by the time for carriers to traverse the I-layer, is expressed as f_{3\text{dB}} = \frac{v_{\text{sat}}}{2\pi W}, where v_{\text{sat}} is the saturation velocity and W is the I-layer thickness; advanced InGaAs PIN photodiodes achieve up to 50 GHz, enabling high-data-rate signal detection.[38] Recent developments have extended this to support data rates beyond 100 Gbps in silicon photonics for data centers and telecommunications.[39] Noise in PIN photodiodes is predominantly shot noise arising from the statistical fluctuation in photogenerated and dark carriers, with the noise equivalent power (NEP)—the minimum detectable power for a signal-to-noise ratio of 1—typically around $10^{-12} W/√Hz under low-light conditions.[40] Compared to PN photodiodes, PIN structures exhibit lower dark current, often below 1 nA, due to the intrinsic layer suppressing diffusion currents and thermal generation, which enhances sensitivity for weak signals.[41] These attributes make PIN photodiodes essential in fiber optic communications for high-speed data links and in LIDAR systems for precise distance measurement.[42] Recent advances in silicon photonics have integrated PIN photodiodes into compact transceivers supporting 100G Ethernet and higher, leveraging CMOS-compatible processes for scalable, low-cost optical interconnects in data centers.[43]Photovoltaic Devices
In photovoltaic devices, PIN diodes are adapted for solar cell applications by incorporating a thin intrinsic (I) layer, typically 0.1-1 μm thick, to optimize light absorption while minimizing recombination losses and enabling efficient carrier collection across the device.[44] This structure contrasts with traditional PN junctions by providing a wider depletion region in the I-layer, which enhances the separation of photogenerated electron-hole pairs under illumination. The power conversion efficiency (η) of such PIN solar cells is given by η = (FF × V_oc × J_sc) / P_in, where FF is the fill factor, V_oc is the open-circuit voltage, J_sc is the short-circuit current density, and P_in is the incident power density; for silicon-based PIN devices, efficiencies up to 27% have been achieved as of 2025 through optimized I-layer design and heterojunction integration.[45][46] PIN photovoltaic devices operate at zero bias, relying on the built-in electric field across the I-region to separate photogenerated carriers without external voltage, which simplifies integration and reduces power consumption in energy harvesting systems. This self-driven mechanism yields a high fill factor (FF > 0.8), reflecting efficient power extraction close to the ideal diode behavior under standard illumination conditions.[45] The spectral response of PIN solar cells is broader than that of conventional PN junctions due to the I-region's role in extending carrier collection to longer wavelengths, where diffusion limitations in PN structures reduce efficiency; this makes PIN designs suitable for concentrator photovoltaics and tandem cell architectures that capture a wider portion of the solar spectrum.[47] Specific applications include GaAs-based PIN solar cells in satellite power systems, where their high radiation tolerance and efficiency under concentrated sunlight enable reliable operation in space environments.[48] Additionally, amorphous silicon (a-Si) PIN structures excel in low-light sensors, offering high responsivity (e.g., 350 mA/W at 510 nm) for applications like biochemical detection in integrated lab-on-chip devices.[49] Recent advancements in perovskite/Si PIN tandem solar cells have pushed efficiencies beyond 30%, with the certified record reaching 34.85% as of April 2025 by LONGi for a two-terminal crystalline silicon-perovskite tandem solar cell, addressing stability and scalability challenges for emerging photovoltaic technologies.[50] These developments leverage the I-layer in both subcells to broaden spectral coverage and enhance overall energy yield in hybrid structures.[51]Device Examples
Commercial PIN Diodes
Commercial PIN diodes are widely available from leading manufacturers, with silicon-based devices dominating the market due to their cost-effectiveness and versatility in both RF and optoelectronic applications. Key players in the RF segment include Skyworks and Qorvo, which offer high-performance diodes for switches and attenuators, while Vishay and ams OSRAM lead in optical photodiodes for sensing and detection.[52][53] Low-cost silicon PIN diodes prevail in consumer electronics such as wireless devices and optical sensors, owing to their affordability and sufficient performance for high-volume production, whereas gallium arsenide (GaAs) variants have been preferred for high-end microwave applications since the early 2000s due to superior electron mobility and faster switching at frequencies above 10 GHz.[54][5][55] Representative examples include the MACOM MA4P series, silicon RF diodes designed for switching up to 1 GHz with a typical on-state resistance of 0.5 Ω, and the Hamamatsu S5973, a silicon photodetector offering 0.51 A/W responsivity at 760 nm.[56][57] For GaAs options, flip-chip PIN diodes from Microchip (formerly Microsemi) provide low zero-bias capacitance around 0.05 pF and carrier lifetimes of 0.2 ns, suited for microwave circuits.[58] The following table compares selected commercial PIN diodes, highlighting key specifications for RF and optical uses:| Manufacturer | Model | Material | Application | Frequency/Wavelength Range | Key Specs | Packaging | Power Rating |
|---|---|---|---|---|---|---|---|
| MACOM | MA4P7101F-1072T | Si | RF Switch | 10 MHz to 1 GHz | R_on = 0.5 Ω (typ.) | MELF | 11.5 W |
| Skyworks | SMP1324-087LF | Si | RF Attenuator | 1 to 900 MHz | R_on = 0.4 Ω @ 50 mA | Axial | 40 Ω·°C/W thermal resistance |
| Hamamatsu | S5973 | Si | Photodetector | 320 to 1000 nm | 0.51 A/W @ 760 nm, 1 GHz bandwidth | TO-18 | N/A |
| Vishay | VEMD2704 | Si | Optical Sensor | 400 to 1100 nm | Sensitive area = 1.51 mm² | SMD | N/A |